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Im Rahmen dieser Arbeit wurden zum Vergleich die Strukturen der ATP-Synthasen von Arabidopsis thaliana, Asparagus officinalis, Allium cepa, Helianthus annus, Solanum tuberosum, Bos taurus und Saccharomyces cerevisiae gelöst. Die ATP-Synthase von S. cerevisiae konnte mit einer Auflösung von 19 Å gelöst werden. Der Winkel zwischen den zwei ATP-Synthase-Monomeren in dem ATP-Synthase-Dimer hatte für jede Spezies einen bestimmten Wert. Dieser Winkel änderte sich innerhalb einer Spezies nur wenig im Gegensatz zu Untersuchungen mit Einzelpartikelanalyse.
Die ATP-Synthase-Dimere aus den untersuchten Spezies besitzen unterschiedliche Winkel zwischen 78˚ und 122˚. Der Winkel des ATP-Synthase-Dimers aus S. tuberosum (122˚) viel größer als der in anderen Pflanzen (~98˚), B. taurus (105˚) und S. cerevisiae (78˚). Die Proben von S. tuberosum und B. taurus waren jedoch dünner, was den Winkel eventuell beeinflussen könnte. Um dies auszuschließen müssen in Zukunft weitere Untersuchungen durchgeführt werden.
Des Weiteren wurde im peripheren Stiel der ATP-Synthasen von allen Pflanzenspezies eine Dichte entdeckt, die in B. taurus und S. cerevisiae nicht vorhanden ist. Die Dichte könnte durch eine zusätzliche Untereinheit oder veränderte Untereinheit im Vergleich zu B. taurus und S. cerevisiae kommen.
Weiterhin wurde die Bildung von Reihen aus ATP-Synthase-Dimeren untersucht. Es wurden ATP-Synthase-Dimere von Polytomella sp. gereinigt und in Lipid rekonstituiert. Es wurde das ATP-Synthase-Dimer von Polytomella sp. verwendet, da dieses besonders stabil ist und während der Reinigung nicht zum ATP-Synthase-Monomer zerfällt. Zur Rekonstitution wurde die milde GRecon-Methode verwendet. Hierbei werden Membranproteine in einem Zuckergradienten gleichzeitig in Lipid rekonstituiert und nach ihrer Dichte getrennt. Abhängig von der Dichte der Proteoliposomen ist die Konzentration an Membranproteinen unterschiedlich. In Proteoliposomen mit einer hohen Konzentration bilden sich dünne Schichten in denen die ATP-Synthase-Dimeren Zickzack-Muster formen. Dies deutet darauf hin, dass das ATP-Synthase-Dimer die Membran verformt. In Proteoliposomen mit einer niedrigeren Konzentration an ATP-Synthase-Dimeren wurden runde Vesikel detektiert, in denen die ATP-Synthase-Dimere lange Reihen bilden und die Membran innerhalb jedes ATP-Synthase-Dimer ebenfalls verformt ist. Molekulare Simulationen bestätigen dieses Ergebnis.
Zudem wurde das ATP-Synthase-Dimer in zwei verschiedene Lipide ohne Cardiolipin rekonstituiert, da Cardiolipin ein Lipid ist welches in der bakteriellen und mitochondrialen Membran gefunden wurde und in hohen Konzentrationen in Membrankrümmungen lokalisiert ist (Huang et al., 2006), wie auch die ATP-Synthase-Dimere. Ohne Cardiolipin ist die Rekonstitution nicht geglückt beziehungsweise sind die ATP-Synthase-Dimere weniger gut zueinander angeordnet. Das deutet auf die Wichtigkeit von Cardiolipin in der Stabilisierung der Reihen von ATP-Synthase-Dimeren hin. Weitere Experimente mit verschiedenen ATP-Synthase-Dimeren in verschiedenen Lipiden sind nötig um dies zu untermauern.
Ein weiteres Ziel dieser Arbeit war es ein klonierbares Label zu etablieren, um ein bestimmtes Protein in Kryo-Elektronentomogramme zu identifizieren. Das Label sollte klein sein, um das zu identifizierbare Protein nicht zu beeinflussen und groß genug um in Kryo-Elektronentomogramme identifizierbar zu sein. In Einzelbildern wurde das 6 kDa große Metallothionein gebunden mit Gold identifiziert, wenn zwei Metallothioneine an dem gewünschten Protein kloniert wurden. Metallothionein besteht zu 33 % aus Cysteinen, welche Schwermetalle binden.
In meinen Studien habe ich bewiesen, dass drei Metallothioneine, gebunden mit Gold, in Kryo-Elektronentomogramme detektiert werden können. Jedoch tritt bei der Verwendung von Metallothionein durch die hohe Anzahl an Cysteinen vermehrt Aggregation auf. Bei meinen Untersuchungen fand ich heraus, dass auch das Maltose-Binde-Protein (MBP) ein Signal gleicher Intensität erzeugt. Durch Verwendung von MBP tritt aber keine Aggregation auf und man kann MBP auch zum Reinigen des Proteins verwenden.
A simple and sustainable one-step strategy for the preparation of electron-deficient aryl trifluoromethyl ethers (ArOCF3) from the corresponding phenols by electrochemical synthesis is presented. Anodic oxidation of trifluoromethane sulfinate (Langlois reagent) leads to direct O-trifluoromethylation of phenol-derivatives bearing fluorine, chlorine, bromine and nitrile substituents under mild conditions in yields up to 75% and in gram-scale. This electrochemical protocol provides an economic and green synthesis for an otherwise inaccessible class of molecules without the need for expensive or toxic reagents, oxidants or metal catalysts.
Nuclear magnetic resonance measurements were carried out on neutron activated 20F(T1/2=11s) nuclei in a single crystal of KZnF3. The quadrupolar splitted NMR spectrum, detected via the 20F β-radiation asymmetry, could be observed using a radio frequency modulation technique. The quadrupole coupling constant was determined to e2 q Q/h= + (12.0 ± 1.5) MHz at room temperature. The sign of e2 q Q was obtained from a simultaneous γ-ray anisotropy measurement on the succeeding 20Ne transition. Utilising a calculated field gradient of the fluorine atom, an fQ = 4.6% is determined. This value is compared with literature data of similar compounds.
The development of single-photon-counting detectors, such as the PILATUS, has been a major recent breakthrough in macromolecular crystallography, enabling noise-free detection and novel data-acquisition modes. The new EIGER detector features a pixel size of 75 × 75 µm, frame rates of up to 3000 Hz and a dead time as low as 3.8 µs. An EIGER 1M and EIGER 16M were tested on Swiss Light Source beamlines X10SA and X06SA for their application in macromolecular crystallography. The combination of fast frame rates and a very short dead time allows high-quality data acquisition in a shorter time. The ultrafine φ-slicing data-collection method is introduced and validated and its application in finding the optimal rotation angle, a suitable rotation speed and a sufficient X-ray dose are presented. An improvement of the data quality up to slicing at one tenth of the mosaicity has been observed, which is much finer than expected based on previous findings. The influence of key data-collection parameters on data quality is discussed.
The influence of temperatur and pressure on the fluorescence quantum yield of N-methylacridone (9,10-dihydro-9-oxo-10-methyl-acridine) in toluene in the range of 283-313 K and 1 bar to 2.5 kbar, respectively, has been investigated. Treatment of the data in terms of the Eyring transition-state theory leads to a consistent interpretation of the observed effect. The unusually large increase of the quantum yield with increasing pressure is attributed to a positive volume of activation, ⊿V≠, for the thermally activated S1-T2 intersystem crossing which is known to be the only deactivation process (of the Si-state) competing with fluorescence. Comparison of the values for ⊿H≠, the activation enthalpy of this process, determined at various pressures, indicates a decrease in ⊿H≠ at elevated pressures. Since ⊿H≠ can be associated with the S1-T2 energy gap involved in intersystem crossing, this result further confirms the conclusion that the change in Franck-Condon factors alone cannot account for the decrease in the intersystem crossing rate with increasing pressure.
Adequate digital resolution and signal sensitivity are two critical factors for protein structure determinations by solution NMR spectroscopy. The prime objective for obtaining high digital resolution is to resolve peak overlap, especially in NOESY spectra with thousands of signals where the signal analysis needs to be performed on a large scale. Achieving maximum digital resolution is usually limited by the practically available measurement time. We developed a method utilizing non-uniform sampling for balancing digital resolution and signal sensitivity, and performed a large-scale analysis of the effect of the digital resolution on the accuracy of the resulting protein structures. Structure calculations were performed as a function of digital resolution for about 400 proteins with molecular sizes ranging between 5 and 33 kDa. The structural accuracy was assessed by atomic coordinate RMSD values from the reference structures of the proteins. In addition, we monitored also the number of assigned NOESY cross peaks, the average signal sensitivity, and the chemical shift spectral overlap. We show that high resolution is equally important for proteins of every molecular size. The chemical shift spectral overlap depends strongly on the corresponding spectral digital resolution. Thus, knowing the extent of overlap can be a predictor of the resulting structural accuracy. Our results show that for every molecular size a minimal digital resolution, corresponding to the natural linewidth, needs to be achieved for obtaining the highest accuracy possible for the given protein size using state-of-the-art automated NOESY assignment and structure calculation methods.
Molecular dynamics has been employed to study the effect of ion treatment on the stability of 14-nucleotide RNA hairpin of Coxsackievirus B3. Three AMBER force fields were used: AMBER94, AMBER98, and AMBER99, which showed no significant structural difference of the hairpin. Thereafter, we applied two different long-range electrostatic treatments that were reaction field and PME methods, and calculated the distribution of ions around the hairpin. Although the structural stabilities of the MD simulations using both methods were similar in 0.14 M Na+, ion environment around the hairpin was notably different. In particular, structural stabilition of the hairpin with increasing ion concentration and with ion Mg2+ cannot be accommodated by simulations using reaction field method. Furthermore, the MD simulations using PME method suggested the strong similarity in structural and dynamical properties of the hairpin with 0.14 M Na+, 0.50 M Na+, 1,03 M Na+, and 0.08 M Mg2+ concentrations. However, the simulations revealed different ion occupations of Na+ and Mg2+.
The discovery of antibiotics represented a key milestone in the history of medicine. However, with the rise of these life-saving drugs came the awareness that bacteria deploy defense mechanisms to resist these antibiotics, and they are good at it. Today, we appear at a crossroads between discovery of new potent drugs and omni-resistant superbugs. Moreover, the misuse of antibiotics in different industries has increased the rate of resistance development by providing permanent selective pressure and, subsequently, enrichment of multidrug resistant pathogens. As a result, antimicrobial resistance has now become an urgent threat to public health worldwide (http:// www.who.int/drugresistance/documents/surveillancereport/en/). The development of multidrug resistance (MDR) in an increasing number of pathogens, including Pseudomonas, Acinetobacter, Klebsiella, Salmonella, Burkholderia, and other Gram-negative bacteria is a serious issue. Membrane efflux pump complexes of the Resistance-Nodulation-Division (RND) superfamily play a key role in the development of MDR in these bacteria. These pumps, together with other transporters, contribute to intrinsic and acquired resistance of bacteria toward most, if not all, of the compounds available in our antimicrobial arsenal. Given the enormous drug polyspecificity of MDR efflux pumps, studies on their mechanism of action are extremely challenging, and this has negatively impacted both on the development of new antibiotics that are able to evade these efflux pumps and on the design of pump inhibitors. The collection of articles in this eBook, published as a Research Topic in Frontiers in Microbiology, section of Antimicrobials, Resistance, and Chemotherapy, aims to update the reader about the latest advances on the structure and function of RND efflux transporters, their roles in the overall multidrug resistance phenotype of Gram-negative pathogens, and on the strategies to inhibit their activities. ...
Cell-free (CF) synthesis with highly productive E. coli lysates is a convenient method to produce labeled proteins for NMR studies. Despite reduced metabolic activity in CF lysates, a certain scrambling of supplied isotope labels is still notable. Most problematic are conversions of 15N labels of the amino acids L-Asp, L-Asn, L-Gln, L-Glu and L-Ala, resulting in ambiguous NMR signals as well as in label dilution. Specific inhibitor cocktails suppress most undesired conversion reactions, while limited availability and potential side effects on CF system productivity need to be considered. As alternative route to address NMR label conversion in CF systems, we describe the generation of optimized E. coli lysates with reduced amino acid scrambling activity. Our strategy is based on the proteome blueprint of standardized CF S30 lysates of the E. coli strain A19. Identified lysate enzymes with suspected amino acid scrambling activity were eliminated by engineering corresponding single and cumulative chromosomal mutations in A19. CF lysates prepared from the mutants were analyzed for their CF protein synthesis efficiency and for residual scrambling activity. The A19 derivative “Stablelabel” containing the cumulative mutations asnA, ansA/B, glnA, aspC and ilvE yielded the most useful CF S30 lysates. We demonstrate the optimized NMR spectral complexity of selectively labeled proteins CF synthesized in “Stablelabel” lysates. By taking advantage of ilvE deletion in "Stablelabel", we further exemplify a new strategy for methyl group specific labeling of membrane proteins with the proton pump proteorhodopsin.
Ribosomes are the central cellular assembly lines for protein synthesis. To cope with the translational needs, a proliferating mammalian cell can produce up to 7500-ribosomes per minute. However, under growth limiting conditions, such as nutrient depletion, ribosome synthesis is rapidly shut down exemplifying the importance of a tight coordination between ribosome supply and cellular energy status. In addition to the quantitative regulation, a strict quality control of ribosome synthesis is equally important, because alterations in the composition or function of ribosomes can lead to a variety of pathologies. To cope with these challenges a highly regulated, multi-step pathway of ribosome biogenesis has evolved. In mammals this pathway generates the mature 80S ribosomes that comprise the large 60S and the small 40S subunits. Together they contain around 80 ribosomal proteins and the 28S, 18S, 5.8S and 5S rRNAs. The 28S, 5.8S and 5S rRNAs are assembled into the large subunit, while the 18S rRNA is part of the small subunit. The pathway of ribosome biogenesis is a multi-step cellular process, where specific stages occur in distinct subcellular compartments. Transcription of the 47S rRNA, which is the precursor for the 28S, 18S and 5.8S species, occurs in the nucleolus. Modification of distinct bases and early processing of this precursor also take place in the nucleolus. Subsequently, the 40S and 60S pre-ribosomes take separate maturation routes through the nucleoplasm before their export and final assembly in the cytoplasm. The various stages of preribosomal maturation require the constant and sequential action of a large number of non-ribosomal proteins, known as trans-acting factors. These factors coordinate the delicate remodeling of the pre-ribosomal intermediates and thereby ensure proper progression of the maturation process. The remodeling events largely depend on the dynamics of post-translational modifications, such as phosphorylation or SUMOylation. This requires that the enzymes controlling these modifications are properly targeted to their sites of activity as they fulfill their functions within specific compartments. Here we studied the regulatory principles that govern the subcellular partitioning of the SUMO-specific isopeptidase SENP3 and its associated factor PELP1. Previous work from our laboratory has delineated the importance of the SUMO system for proper ribosome biogenesis in mammalian cells. In particular, we have shown that SENP3 is critically involved in 28S rRNA formation, which is a key step for pre-60S subunit maturation. A critical involvement of SENP3 at this stage of the maturation process is in agreement with the observed enrichment of SENP3 in the nucleolus, since 28S rRNA processing is considered to occur in the nucleolus. Our subsequent work identified the nucleolar scaffold protein NPM1 and the ribosomal trans-acting factor PELP1 as bona fide substrates of SENP3. For both proteins we could demonstrate modification by SUMO2/3 and define SENP3 as the demodifying enzyme. Depletion of SENP3 enhanced the conjugation of SUMO to both proteins and concomitantly reduced conversion of the 32S pre-rRNA to the mature 28S rRNA. PELP1 is part of a larger protein complex consisting of the core components PELP1, TEX10 and WDR18. We could show that the balanced SUMOylation/deSUMOylation of PELP1 controls the nucleolar/nucleoplasmic distribution of this complex. Enhanced SUMOylation, which is observed in the absence of SENP3, triggers the nucleolar release of the complex suggesting that SENP3-mediated deSUMOylation controls the dynamics of nucleolar trans-acting factors. Based on these findings we first wanted to understand, in which cellular compartment(s) SENP3 exerts its function on 28S maturation. Next, we wanted to tackle the question how the subcellular distribution of SENP3 is controlled. Finally
we addressed the question how the SUMOylation of PELP1 determines the subnuclear distribution of the PELP1 complex. This work initially revealed that the nucleolar localization of SENP3 is crucial for proper 28S rRNA formation and 60S ribosome maturation. Importantly, we could demonstrate that the nucleolar compartmentalization of SENP3 depends on its direct physical interaction with NPM1. Further, we could show that the amino-terminal region of SENP3 is necessary for its binding to NPM1 and nucleolar recruitment. Strikingly, this interaction requires the phosphorylation of SENP3, which is brought about by the mTOR kinase. By in-vitro kinase assays and mass-spectrometric approaches we identified five serine/threonine residues within the amino-terminal region of SENP3 that are targeted by mTOR (S/T 25, 26, 141, 142, 143). We could further demonstrate by mutagenesis that these sites in SENP3 are in fact critical for the phospho-dependent binding of SENP3 to NPM1 and its nucleolar recruitment.
Consistent with these data, we found that chemical inhibitors of the mTOR kinase trigger the nucleolar release of SENP3 and impair its interaction with NPM1. Strikingly, this goes along with severe 28S rRNA maturation defects demonstrating the physiological importance of mTOR signaling in the regulation SENP3 function and rRNA processing. By specifically depleting components of the either mTORC1 or mTORC2, we could attribute the observed effects to signaling by mTORC1 rather than mTORC2. In an attempt to find the negative regulators of SENP3 phosphorylation, we identified PP1-γ as the candidate phosphatase in this pathway. We found a strong physical interaction of SENP3 with PP1-γ and observed a loss of SENP3 nucleolar localization upon ectopic expression of PP1-γ. Thus we could define mTOR/PP1-γ mediated phosphorylation/dephosphorylation of SENP3 as an important
mechanism in the control of ribosome maturation. Given that mTOR activity is controlled by nutrient availability, SENP3 functions as a sensor that couples ribosome synthesis with nutrient availability. The second part of this work delineated the role of SUMOylated PELP1 in nucleoplasmic partitioning of the SENP3-PELP1 complex. It was revealed that the AAA-ATPase MDN1 binds preferentially to SUMO modified PELP1 and likely segregates SUMOylated PELP1 from nucleolar pre-60S particles. We initially found that the PELP1 complex associates with MDN1, a factor known to be involved in the 28S rRNA maturation. Notably, depletion of MDN1 led to an enhanced accumulation of the PELP1 complex in the nucleolus and a strong association of PELP1 with pre-60S particles, suggesting that MDN1 is required for the release of this complex from the pre-ribosomes. Intriguingly, the interaction of PELP1 with MDN1 requires SUMO2/3 and SUMOylated PELP1 shows enhanced binding to MDN1 when compared to unmodified PELP1. Taken together this work provides new insights in the control of the SENP3-PELP1 complex dynamics. We could define several layers for the coordinated spatial regulation of SENP3 and the PELP1 complex. This work therefore underscores the crucial importance of dynamic post-translational modifications for the control of ribosome maturation.
The field of dynamic nuclear polarization has undergone tremendous developments and diversification since its inception more than 6 decades ago. In this review we provide an in-depth overview of the relevant topics involved in DNP-enhanced MAS NMR spectroscopy. This includes the theoretical description of DNP mechanisms as well as of the polarization transfer pathways that can lead to a uniform or selective spreading of polarization between nuclear spins. Furthermore, we cover historical and state-of-the art aspects of dedicated instrumentation, polarizing agents, and optimization techniques for efficient MAS DNP. Finally, we present an extensive overview on applications in the fields of structural biology and materials science, which underlines that MAS DNP has moved far beyond the proof-of-concept stage and has become an important tool for research in these fields.
Nuclear Magnetic Resonance ("NMR") is a powerful and versatile technique relying on nuclei that posses a spin. Since its discovery more than 6 decades ago, NMR and related techniques has become a tool with innumerable applications throughout the fields of Physics, Chemistry, Biology and Medicine. Numerous Nobel Prizes have been awarded for work in the field and a multi billion dollar industry has developed on its basis.
One of NMR's major shortcomings is its inherent lack of sensitivity. Because it relies on the Boltzmann populations of spin states with a minuscule Zeeman splitting, this is particularly true for room temperature experiments.
As a result, in an enormous technological effort to enlarge the Zeeman splitting NMR magnets have been moving to higher and higher magnetic fields. However, even for proton spins possessing the largest magnetic moment of all nuclei, the degree of polarization that can be achieved in the strongest spectroscopic magnets available today (~24 T) at room temperature is merely ~ 8*(10 exp (-5)). In other words, this low polarization theoretically allows a sensitivity enhancement of 104 towards full polarization.
Since Magnetic Resonance Imaging ("MRI") is based on the same principle, it shares this problem with NMR. Furthermore, for technical and physiological reasons full body MRI tomographs do not reach the magnetic field strengths of spectroscopic NMR magnets, making this even more of an issue for MRI.
In consequence, MRI is chiefly restricted to detecting protons, while both MRI and NMR detection of 13C (or other low nuclei) under physiological conditions, i.e. low natural abundance of 13C and a low concentration of the respective substance, suffer from long acquisitions times that are necessary to obtain adequate signal to noise ratios ("SNR").
However, this drawb of NMR can be overcome. The enormous potential sensitivity increase of four orders of magnitude can - at least partially - be exploited by several hyperpolarization techniques, creating entirely new applications and fields of research.
These hyperpolarization techniques comprise chemical approaches like Parahydrogen Induced Polarization ("PHIP") or Photochemically Induced Dynamic Nuclear Polarization ("Photo-CIDNP"), as well as physical techniques like optically pumped (noble) gases13, 14 or Dynamic Nuclear Polarization ("DNP"), which will be the focus of this work. A hyperpolarized substance will render a larger signal without being physically or chemically altered in any other way. It is therefore "marked" without any marker, making it an agent free contrast agent for MRI.
DNP is a technique, in which hyperpolarization of nuclear spins is achieved by microwave (\MW") irradiation of unpaired electron spins in radicals, which are coupled to these nuclei, e.g. 1H, 13C or 15N. The electron spin population is perturbed if the microwave irradiation is resonant with the electron spin transition, which affects the polarization of hyperfine-coupled close nuclei. For large microwave power (i.e. saturating the electron spin transition) the orders of magnitude larger thermal electron spin polarization is effectively transferred to these nuclear spins in the sample. For proton spins the maximum polarization gain amounts to 660, whereas for 13C the sensitivity gain can be as large as 2600. In contrast to e.g. PHIP, which is restricted to specific reaction precursors, DNP is not limited to specific nuclei or hyperpolarization target molecules, making it a very versatile technique. DNP has been first proposed by Overhauser in 1953,15 and experimentally observed shortly thereafter in metals16 and liquids,17 both being systems with mobile electrons. In the 1960s and 70s, DNP was used as a spectroscopic tool in liquids, thoroughly mapping the effect in the low field regime. As well, several other transfer mechanisms were discovered, which are active in the solid state with localized electrons, namely the solid effect the cross effect and thermal mixing. The theory for all three of these mechanisms predicts reduced transfer efficiencies at higher magnetic fields. This fact and the lack of high frequency microwave sources to excite electron spins at magnetic field strengths above 1 T, effectively relegated DNP to a position of an interesting scientifi curiosity.
In the early 1990s, DNP came to a renaissance, when DNP was performed at high field in solid state magic angle spinning ("MAS") experiments using high power gyrotron microwave sources. This pioneering work sparked a surge of new developments and applications.
As well, this success triggered attempts to investigate also the potential of DNP in the liquid state at high magnetic fields, e.g. at 3.4 T35{38 and 9.2 T. To date, DNP can be considered one of the "hot topics" in the field of magnetic resonance, bringing about special issue in magnetic resonance journals and DNP sections on magnetic resonance conferences.
This thesis deals with the development of an in-bore liquid state DNP polarizer for MRI applications operating in ow through mode at a magnetic field strength of 1.5 T. Following this introductory chapter, the theoretical background necessary to understand and interpret the experimental results is explained in chapter 2. Subsequently, chapter 3 deals with the issue of performing liquid state DNP at high magnetic fields and its challenges. The chapter comprises a quick overview of the necessary hardware, the experimental findings for various samples and the interpretation of these findings. along with the ramifications for the aim of this work. Chapter 4 deals with the issue of increasing sensitivity and contrast in MRI, in particular by means of DNP. The chapter illustrates the development of our polarizer by presenting the hardware that was developed and demonstrating its performance under various conditions. As well, several alternative approaches are introduced and compared to our approach. Finally, chapter 5 summarizes the findings and gives an outlook on further developments.
Ubiquitination relies on a subtle balance between selectivity and promiscuity achieved through specific interactions between ubiquitin-conjugating enzymes (E2s) and ubiquitin ligases (E3s). Here, we report how a single aspartic to glutamic acid substitution acts as a dynamic switch to tip the selectivity balance of human E2s for interaction toward E3 RING-finger domains. By combining molecular dynamic simulations, experimental yeast-two-hybrid screen of E2-E3 (RING) interactions and mutagenesis, we reveal how the dynamics of an internal salt-bridge network at the rim of the E2-E3 interaction surface controls the balance between an “open”, binding competent, and a “closed”, binding incompetent state. The molecular dynamic simulations shed light on the fine mechanism of this molecular switch and allowed us to identify its components, namely an aspartate/glutamate pair, a lysine acting as the central switch and a remote aspartate. Perturbations of single residues in this network, both inside and outside the interaction surface, are sufficient to switch the global E2 interaction selectivity as demonstrated experimentally. Taken together, our results indicate a new mechanism to control E2-E3 interaction selectivity at an atomic level, highlighting how minimal changes in amino acid side-chain affecting the dynamics of intramolecular salt-bridges can be crucial for protein-protein interactions. These findings indicate that the widely accepted sequence-structure-function paradigm should be extended to sequence-structure-dynamics-function relationship and open new possibilities for control and fine-tuning of protein interaction selectivity.
The blue light-dependent interaction between the proteins iLID and Nano allows recruiting and patterning proteins on GUV membranes, which thereby capture key features of patterns observed in nature. This photoswitchable protein interaction provides non-invasive, reversible and dynamic control over protein patterns of different sizes with high specificity and spatiotemporal resolution.
The nuclear farnesoid X receptor (FXR) and the enzyme soluble epoxide hydrolase (sEH) are validated molecular targets to treat metabolic disorders such as non‐alcoholic steatohepatitis (NASH). Their simultaneous modulation in vivo has demonstrated a triad of anti‐NASH effects and thus may generate synergistic efficacy. Here we report dual FXR activators/sEH inhibitors derived from the anti‐asthma drug Zafirlukast. Systematic structural optimization of the scaffold has produced favorable dual potency on FXR and sEH while depleting the original cysteinyl leukotriene receptor antagonism of the lead drug. The resulting polypharmacological activity profile holds promise in the treatment of liver‐related metabolic diseases.
We present a computational method for the reaction-based de novo design of drug-like molecules. The software DOGS (Design of Genuine Structures) features a ligand-based strategy for automated ‘in silico’ assembly of potentially novel bioactive compounds. The quality of the designed compounds is assessed by a graph kernel method measuring their similarity to known bioactive reference ligands in terms of structural and pharmacophoric features. We implemented a deterministic compound construction procedure that explicitly considers compound synthesizability, based on a compilation of 25'144 readily available synthetic building blocks and 58 established reaction principles. This enables the software to suggest a synthesis route for each designed compound. Two prospective case studies are presented together with details on the algorithm and its implementation. De novo designed ligand candidates for the human histamine H4 receptor and γ-secretase were synthesized as suggested by the software. The computational approach proved to be suitable for scaffold-hopping from known ligands to novel chemotypes, and for generating bioactive molecules with drug-like properties.
Flavins are employed to transform physical input into biological output signals. In this function, flavins catalyze a variety of light-induced reactions and redox processes. However, nature also provides flavoproteins with the ability to uncouple the mediation of signals. Such proteins are the riboflavin-binding proteins (RfBPs) with their function to store riboflavin for fast delivery of FMN and FAD. Here we present in vitro and in vivo data showing that the recently discovered archaeal dodecin is an RfBP, and we reveal that riboflavin storage is not restricted to eukaryotes. However, the function of the prokaryotic RfBP dodecin seems to be adapted to the requirement of a monocellular organism. While in eukaryotes RfBPs are involved in trafficking riboflavin, and dodecin is responsible for the flavin homeostasis of the cell. Although only 68 amino acids in length, dodecin is of high functional versatility in neutralizing riboflavin to protect the cellular environment from uncontrolled flavin reactivity. Besides the predominant ultrafast quenching of excited states, dodecin prevents light-induced riboflavin reactivity by the selective degradation of riboflavin to lumichrome. Coordinated with the high affinity for lumichrome, the directed degradation reaction is neutral to the cellular environment and provides an alternative pathway for suppressing uncontrolled riboflavin reactivity. Intriguingly, the different structural and functional properties of a homologous bacterial dodecin suggest that dodecin has different roles in different kingdoms of life.
The production of haploid gametes through meiosis is central to the principle of sexual reproduction. The genetic diversity is further enhanced by exchange of genetic material between homologous chromosomes by the crossover mechanism. This mechanism not only requires correct pairing of homologous chromosomes but also efficient repair of the induced DNA double-strand breaks. Oocytes have evolved a unique quality control system that eliminates cells if chromosomes do not correctly align or if DNA repair is not possible. Central to this monitoring system that is conserved from nematodes and fruit fly to humans is the p53 protein family, and in vertebrates in particular p63. In mammals, oocytes are stored for a long time in the prophase of meiosis I which, in humans, can last more than 50 years. During the entire time of this arrest phase, the DNA damage checkpoint remains active. The treatment of female cancer patients with DNA damaging irradiation or chemotherapeutics activates this checkpoint and results in elimination of the oocyte pool causing premature menopause and infertility. Here, we review the molecular mechanisms of this quality control system and discuss potential therapeutic intervention for the preservation of the oocyte pool during chemotherapy.
DNA damage in oocytes induces a switch of the quality control factor TAp63α from dimer to tetramer
(2011)
TAp63a, a homolog of the p53 tumor suppressor, is a quality control factor in the female germline. Remarkably, already undamaged oocytes express high levels of the protein, suggesting that TAp63a’s activity is under tight control of an inhibitory mechanism. Biochemical studies have proposed that inhibition requires the C-terminal transactivation inhibitory domain. However, the structural mechanism of TAp63a inhibition remains unknown. Here, we show that TAp63a is kept in an inactive dimeric state. We reveal that relief of inhibition leads to tetramer formation with ~20-fold higher DNA affinity. In vivo, phosphorylation-triggered tetramerization of TAp63a is not reversible by dephosphorylation. Furthermore, we show that a helix in the oligomerization domain of p63 is crucial for tetramer stabilization and competes with the transactivation domain for the same binding site. Our results demonstrate how TAp63a is inhibited by complex domain-domain interactions that provide the basis for regulating quality control in oocytes.
Long-range tertiary interactions determine the three-dimensional structure of a number of metabolite-binding riboswitch RNA elements and were found to be important for their regulatory function. For the guanine-sensing riboswitch of the Bacillus subtilis xpt-pbuX operon, our previous NMR-spectroscopic studies indicated pre-formation of long-range tertiary contacts in the ligand-free state of its aptamer domain. Loss of the structural pre-organization in a mutant of this RNA (G37A/C61U) resulted in the requirement of Mg2+ for ligand binding. Here, we investigate structural and stability aspects of the wild-type aptamer domain (Gsw) and the G37A/C61U-mutant (Gswloop) of the guanine-sensing riboswitch and their Mg2+-induced folding characteristics to dissect the role of long-range tertiary interactions, the link between pre-formation of structural elements and ligand-binding properties and the functional stability. Destabilization of the long-range interactions as a result of the introduced mutations for Gswloop or the increase in temperature for both Gsw and Gswloop involves pronounced alterations of the conformational ensemble characteristics of the ligand-free state of the riboswitch. The increased flexibility of the conformational ensemble can, however, be compensated by Mg2+. We propose that reduction of conformational dynamics in remote regions of the riboswitch aptamer domain is the minimal pre-requisite to pre-organize the core region for specific ligand binding.
Short linear motifs (SLiMs) located in disordered regions of multidomain proteins are important for the organization of protein–protein interaction networks. By dynamic association with their binding partners, SLiMs enable assembly of multiprotein complexes, pivotal for the regulation of various aspects of cell biology in higher organisms. Despite their importance, there is a paucity of molecular tools to study SLiMs of endogenous proteins in live cells. LC3 interacting regions (LIRs), being quintessential for orchestrating diverse stages of autophagy, are a prominent example of SLiMs and mediate binding to the ubiquitin-like LC3/GABARAP family of proteins. The role of LIRs ranges from the posttranslational processing of their binding partners at early stages of autophagy to the binding of selective autophagy receptors (SARs) to the autophagosome. In order to generate tools to study LIRs in cells, we engineered high affinity binders of LIR motifs of three archetypical SARs: OPTN, p62, and NDP52. In an array of in vitro and cellular assays, the engineered binders were shown to have greatly improved affinity and specificity when compared with the endogenous LC3/GABARAP family of proteins, thus providing a unique possibility for modulating LIR interactions in living systems. We exploited these novel tools to study the impact of LIR inhibition on the fitness and the responsiveness to cytarabine treatment of THP-1 cells – a model for studying acute myeloid leukemia (AML). Our results demonstrate that inhibition of LIR of a single autophagy receptor is insufficient to sensitize the cells to cytarabine, while simultaneous inhibition of three LIR motifs in three distinct SARs reduces the IC50 of the chemotherapeutic.
The industry‐scale production of methylchloromonosilanes in the Müller–Rochow Direct Process is accompanied by the formation of a residue, the direct process residue (DPR), comprised of disilanes MenSi2Cl6‐n (n=1–6). Great research efforts have been devoted to the recycling of these disilanes into monosilanes to allow reintroduction into the siloxane production chain. In this work, disilane cleavage by using alkali and alkaline earth metal salts is reported. The reaction with metal hydrides, in particular lithium hydride (LiH), leads to efficient reduction of chlorine containing disilanes but also induces disproportionation into mono‐ and oligosilanes. Alkali and alkaline earth chlorides, formed in the course of the reduction, specifically induce disproportionation of highly chlorinated disilanes, whereas highly methylated disilanes (n>3) remain unreacted. Nearly quantitative DPR conversion into monosilanes was achieved by using concentrated HCl/ether solutions in the presence of lithium chloride.
Directed deposition of silicon nanowires using neopentasilane as precursor and gold as catalyst
(2012)
In this work the applicability of neopentasilane (Si(SiH3)4) as a precursor for the formation of silicon nanowires by using gold nanoparticles as a catalyst has been explored. The growth proceeds via the formation of liquid gold/silicon alloy droplets, which excrete the silicon nanowires upon continued decomposition of the precursor. This mechanism determines the diameter of the Si nanowires. Different sources for the gold nanoparticles have been tested: the spontaneous dewetting of gold films, thermally annealed gold films, deposition of preformed gold nanoparticles, and the use of “liquid bright gold”, a material historically used for the gilding of porcelain and glass. The latter does not only form gold nanoparticles when deposited as a thin film and thermally annealed, but can also be patterned by using UV irradiation, providing access to laterally structured layers of silicon nanowires.
In prokaryotes, RNA thermometers regulate a number of heat shock and virulence genes. These temperature sensitive RNA elements are usually located in the 5'-untranslated regions of the regulated genes. They repress translation initiation by base pairing to the Shine–Dalgarno sequence at low temperatures. We investigated the thermodynamic stability of the temperature labile hairpin 2 of the Salmonella fourU RNA thermometer over a broad temperature range and determined free energy, enthalpy and entropy values for the base-pair opening of individual nucleobases by measuring the temperature dependence of the imino proton exchange rates via NMR spectroscopy. Exchange rates were analyzed for the wild-type (wt) RNA and the A8C mutant. The wt RNA was found to be stabilized by the extraordinarily stable G14–C25 base pair. The mismatch base pair in the wt RNA thermometer (A8–G31) is responsible for the smaller cooperativity of the unfolding transition in the wt RNA. Enthalpy and entropy values for the base-pair opening events exhibit linear correlation for both RNAs. The slopes of these correlations coincide with the melting points of the RNAs determined by CD spectroscopy. RNA unfolding occurs at a temperature where all nucleobases have equal thermodynamic stabilities. Our results are in agreement with a consecutive zipper-type unfolding mechanism in which the stacking interaction is responsible for the observed cooperativity. Furthermore, remote effects of the A8C mutation affecting the stability of nucleobase G14 could be identified. According to our analysis we deduce that this effect is most probably transduced via the hydration shell of the RNA.
Observation and tracking of fluorescently labeled molecules and particles in living cells reveals detailed information about intracellular processes on the molecular level. Whereas light microscopic particle observation is usually limited to two-dimensional projections of short trajectory segments, we report here image-based real-time three-dimensional single particle tracking in an active feedback loop with single molecule sensitivity. We tracked particles carrying only 1-3 fluorophores deep inside living tissue with high spatio-temporal resolution. Using this approach, we succeeded to acquire trajectories containing several hundred localizations. We present statistical methods to find significant deviations from random Brownian motion in such trajectories. The analysis allowed us to directly observe transitions in the mobility of ribosomal (r)RNA and Balbiani ring (BR) messenger (m)RNA particles in living Chironomus tentans salivary gland cell nuclei. We found that BR mRNA particles displayed phases of reduced mobility, while rRNA particles showed distinct binding events in and near nucleoli.
The loading of antigenic peptides onto major histocompatibility complex class I (MHC I) molecules is an essential step in the adaptive immune response against virally or malignantly transformed cells. The ER-resident peptide-loading complex (PLC) consists of the transporter associated with antigen processing (TAP1 and TAP2), assembled with the auxiliary factors tapasin and MHC I. Here, we demonstrated that the N-terminal extension of each TAP subunit represents an autonomous domain, named TMD0, which is correctly targeted to and inserted into the ER membrane. In the absence of coreTAP, each TMD0 recruits tapasin in a 1:1 stoichiometry. Although the TMD0s lack known ER retention/retrieval signals, they are localized to the ER membrane even in tapasin-deficient cells. We conclude that the TMD0s of TAP form autonomous interaction hubs linking antigen translocation into the ER with peptide loading onto MHC I, hence ensuring a major function in the integrity of the antigen-processing machinery.
The membrane-bound heterotrimeric nitrate reductase A (NarGHI) catalyzes the oxidation of quinols in the cytoplasmic membrane of Escherichia coli and reduces nitrate to nitrite in the cytoplasm. The enzyme strongly stabilizes a menasemiquinone intermediate at a quinol oxidation site (Q(D)) located in the vicinity of the distal heme b(D). Here molecular details of the interaction between the semiquinone radical and the protein environment have been provided using advanced multifrequency pulsed EPR methods. (14)N and (15)N ESEEM and HYSCORE measurements carried out at X-band ( approximately 9.7 GHz) on the wild-type enzyme or the enzyme uniformly labeled with (15)N nuclei reveal an interaction between the semiquinone and a single nitrogen nucleus. The isotropic hyperfine coupling constant A(iso)((14)N) approximately 0.8 MHz shows that it occurs via an H-bond to one of the quinone carbonyl group. Using (14)N ESEEM and HYSCORE spectroscopies at a lower frequency (S-band, approximately 3.4 GHz), the (14)N nuclear quadrupolar parameters of the interacting nitrogen nucleus (kappa = 0.49, eta = 0.50) were determined and correspond to those of a histidine N(delta), assigned to the heme b(D) ligand His-66 residue. Moreover S-band (15)N ESEEM spectra enabled us to directly measure the anisotropic part of the nitrogen hyperfine interaction (T((15)N) = 0.16 MHz). A distance of approximately 2.2 Abetween the carbonyl oxygen and the nitrogen could then be calculated. Mechanistic implications of these results are discussed in the context of the peculiar properties of the menasemiquinone intermediate stabilized at the Q(D) site of NarGHI.
We report the first evidence for the formation of the "607- and 580-nm forms" in the cytochrome oxidase aa3/H2O2 reaction without the involvement of tyrosine 280. The pKa of the 607-580-nm transition is 7.5. The 607-nm form is also formed in the mixed valence cytochrome oxidase/O2 reaction in the absence of tyrosine 280. Steady-state resonance Raman characterization of the reaction products of both the wild-type and Y280H cytochrome aa3 from Paracoccus denitrificans indicate the formation of six-coordinate low spin species, and do not support, in contrast to previous reports, the formation of a porphyrin pi-cation radical. We observe three oxygen isotope-sensitive Raman bands in the oxidized wild-type aa3/H2O2 reaction at 804, 790, and 358 cm-1. The former two are assigned to the Fe(IV)[double bond]O stretching mode of the 607- and 580-nm forms, respectively. The 14 cm-1 frequency difference between the oxoferryl species is attributed to variations in the basicity of the proximal to heme a3 His-411, induced by the oxoferryl conformations of the heme a3-CuB pocket during the 607-580-nm transition. We suggest that the 804-790 cm-1 oxoferryl transition triggers distal conformational changes that are subsequently communicated to the proximal His-411 heme a3 site. The 358 cm-1 mode has been found for the first time to accumulate with the 804 cm-1 mode in the peroxide reaction. These results indicate that the mechanism of oxygen reduction must be reexamined.
We previously proposed that the dimeric cytochrome bc(1) complex exhibits half-of-the-sites reactivity for ubiquinol oxidation and rapid electron transfer between bc(1) monomers (Covian, R., Kleinschroth, T., Ludwig, B., and Trumpower, B. L. (2007) J. Biol. Chem. 282, 22289-22297). Here, we demonstrate the previously proposed half-of-the-sites reactivity and intermonomeric electron transfer by characterizing the kinetics of ubiquinol oxidation in the dimeric bc(1) complex from Paracoccus denitrificans that contains an inactivating Y147S mutation in one or both cytochrome b subunits. The enzyme with a Y147S mutation in one cytochrome b subunit was catalytically fully active, whereas the activity of the enzyme with a Y147S mutation in both cytochrome b subunits was only 10-16% of that of the enzyme with fully wild-type or heterodimeric cytochrome b subunits. Enzyme with one inactive cytochrome b subunit was also indistinguishable from the dimer with two wild-type cytochrome b subunits in rate and extent of reduction of cytochromes b and c(1) by ubiquinol under pre-steady-state conditions in the presence of antimycin. However, the enzyme with only one mutated cytochrome b subunit did not show the stimulation in the steady-state rate that was observed in the wild-type dimeric enzyme at low concentrations of antimycin, confirming that the half-of-the-sites reactivity for ubiquinol oxidation can be regulated in the wild-type dimer by binding of inhibitor to one ubiquinone reduction site.
CD44v6, a member of the CD44 family of transmembrane glycoproteins is a co-receptor for two receptor tyrosine kinases (RTKs), Met and VEGFR-2 (vascular endothelial growth factor receptor 2). CD44v6 is not only required for the activation of these RTKs but also for signalling. In order to understand the role of CD44v6 in Met and VEGFR-2 activation and signalling we tested whether CD44v6 binds to their ligands, HGF (hepatocyte growth factor) and VEGF (vascular endothelial growth factor), respectively. FACS analysis and cellular ELISA showed binding of HGF and VEGF only to cells expressing CD44v6. Direct binding of CD44v6 to HGF and VEGF was demonstrated in pull-down assays and the binding affinities were determined using MicroScale Thermophoresis, fluorescence correlation spectroscopy and fluorescence anisotropy. The binding affinity of CD44v6 to HGF is in the micromolar range in contrast with the high-affinity binding measured in the case of VEGF and CD44v6, which is in the nanomolar range. These data reveal a heparan sulfate-independent direct binding of CD44v6 to the ligands of Met and VEGFR-2 and suggest different roles of CD44v6 for these RTKs.
The title compound, C20H22O4S2, was synthesized by the reaction of 1,4-dibromobutene with methyl thiosalicylate. The aliphatic segment of this ligand is in an all-trans conformation. The bridging chain, –S-(CH2)4-S–, is almost planar (r.m.s. deviation for all non-H atoms: 0.056 Å) and its mean plane forms dihedral angles of 16.60 (7) and 5.80 (2)° with the aromatic rings. In the crystal, the molecules are linked by weak C—H ... O interactions into chains with graph-set notation C(14) along [0 0 1]. The crystal studied was a racemic twin, the ratio of the twin components being 0.27 (9):0.73 (9).
Mitochondrial ATP synthases form dimers, which assemble into long ribbons at the rims of the inner membrane cristae. We reconstituted detergent-purified mitochondrial ATP synthase dimers from the green algae Polytomella sp. and the yeast Yarrowia lipolytica into liposomes and examined them by electron cryotomography. Tomographic volumes revealed that ATP synthase dimers from both species self-assemble into rows and bend the lipid bilayer locally. The dimer rows and the induced degree of membrane curvature closely resemble those in the inner membrane cristae. Monomers of mitochondrial ATP synthase reconstituted into liposomes do not bend membrane visibly and do not form rows. No specific lipids or proteins other than ATP synthase dimers are required for row formation and membrane remodelling. Long rows of ATP synthase dimers are a conserved feature of mitochondrial inner membranes. They are required for cristae formation and a main factor in mitochondrial morphogenesis.
Decades of work have demonstrated that messenger RNAs (mRNAs) are localized and translated within neuronal dendrites and axons to provide proteins for remodeling and maintaining growth cones or synapses. It remains unknown, however, whether specific forms of plasticity differentially regulate the dynamics and translation of individual mRNA species. To address this, we targeted three individual synaptically localized mRNAs, CamkIIa, β-actin, Psd95, and used molecular beacons to track endogenous mRNA movements. We used reporters and CRISPR/Cas9 gene editing to track mRNA translation in cultured neurons. We found alterations in mRNA dynamic properties occurred during two forms of synaptic plasticity, long-term potentiation (cLTP) and depression (mGluR-LTD). Changes in mRNA dynamics following either form of plasticity resulted in an enrichment of mRNA in the vicinity of dendritic spines. Both the reporters and tagging of endogenous proteins revealed the transcript-specific stimulation of protein synthesis following cLTP or mGluR-LTD. As such, the plasticity-induced enrichment of mRNA near synapses could be uncoupled from its translational status. The enrichment of mRNA in the proximity of spines allows for localized signaling pathways to decode plasticity milieus and stimulate a specific translational profile, resulting in a customized remodeling of the synaptic proteome.
Decades of work have demonstrated that mRNAs are localized and translated within neuronal dendrites and axons to provide proteins for remodeling and maintaining growth cones or synapses. It remains unknown, however, whether specific forms of plasticity differentially regulate the dynamics and translation of individual mRNA species. To address these issues, we targeted three individual synaptically-localized mRNAs, CamkIIa, Beta actin, Psd95, and used molecular beacons to track endogenous mRNA movements and reporters and Crispr-Cas9 gene editing to track their translation. We found widespread alterations in mRNA behavior during two forms of synaptic plasticity, long-term potentiation (LTP) and depression (LTD). Changes in mRNA dynamics following plasticity resulted in an enrichment of mRNA in the vicinity of dendritic spines. Both the reporters and tagging of endogenous proteins revealed the transcript-specific stimulation of protein synthesis following LTP or LTD. The plasticity-induced enrichment of mRNA near synapses could be uncoupled from its translational status. The enrichment of mRNA in the proximity of spines allows for localized signaling pathways to decode plasticity milieus and stimulate a specific translational profile, resulting in a customized remodeling of the synaptic proteome.
Dichlorido(3-phenylindenylidene)bis(triphenylphosphane)ruthenium(II) tetrahydrofuran disolvate
(2011)
The RuII atom in the title compound, [RuCl2(C15H10)(C18H15P)2]·2C4H8O, has a distorted square-pyramidal conformation. The P and Cl atoms are at the base of the pyramid and the Ru-Cindenylidene bond is in the axial position. The two Cl ligands and the two phosphane ligands are in trans positions. The Cl-Ru-Cl and P-Ru-P angles are 157.71 (2) and 166.83 (2)°, respectively. The two independent tetrahydrofuran (THF) solvent molecules are disordered. One THF molecule was refined using a split-atom model. The second THF molecule was accounted for by using program PLATON/SQUEEZE [Spek (2009). Acta Cryst. D65, 148-155]. The molecular conformation shows three intramolecular C-H...Cl contacts and two C-H...[pi] interactions while the crystal packing features an intermolecular C-H...Cl contact and two very weak intermolecular C-H...[pi] contacts.
Di-μ-bromido-bis-[(diethyl ether-κO)(2,4,6-trimethylphenyl)magnesium] : the mesityl Grignard reagent
(2013)
The crystal structure of the title compound, [Mg2Br2(C9H11)2(C4H10O)2], features a centrosymmetric two-centre magnesium complex with half a mol-ecule in the asymmetric unit. The Mg atom is in a considerably distorted Br2CO coordination. Bond lengths and angles are comparable with already published values. The crystal packing is stabilized by C-H⋯π inter-actions linking the complexes into sheets parallel to (0-11).
As cryo-EM approaches the physical resolution limits imposed by electron optics and radiation damage, it becomes increasingly urgent to address the issues that impede high-resolution structure determination of biological specimens. One of the persistent problems has been beam-induced movement, which occurs when the specimen is irradiated with high-energy electrons. Beam-induced movement results in image blurring and loss of high-resolution information. It is particularly severe for biological samples in unsupported thin films of vitreous water. By controlled devitrification of conventionally plunge-frozen samples, the suspended film of vitrified water was converted into cubic ice, a polycrystalline, mechanically stable solid. It is shown that compared with vitrified samples, devitrification reduces beam-induced movement in the first 5 e Å−2 of an exposure by a factor of ∼4, substantially enhancing the contribution of the initial, minimally damaged frames to a structure. A 3D apoferritin map reconstructed from the first frames of 20 000 particle images of devitrified samples resolved undamaged side chains. Devitrification of frozen-hydrated specimens helps to overcome beam-induced specimen motion in single-particle cryo-EM, as a further step towards realizing the full potential of cryo-EM for high-resolution structure determination.
This cumulative thesis discusses the development of optimized force field parameters for Magnesium and resulting improved simulations of Magnesium-RNA interactions, including the in silico exploration of binding sites. This thesis is based on four publications as well as unpublished data. A fifth publication that was written during the time of the Ph.D. is discussed in the Appendix. This publication analyzes monovalent ion-specific effects at mica surfaces.
Nucleic acids in general and RNA in particular are fundamental to life itself. Especially in the folding and function of RNA, metal cations are crucial to screen the negatively charged nucleic acid backbones to allow for complex functional structures. They stabilize the tertiary structure of RNA and even drive its folding. Furthermore, similarly to proteins, RNAs can catalyze multiple reactions, rather than consisting of the 20 amino acids of a protein, RNA constitues of only four different building blocks. Metal cations play an important role here as additional cofactors. One essential ion is Magnesium (Mg2+), commonly referred to as the most important cofactor for nucleic acids. Mg2+ carries two positive charges. Its comparably small size and high charge result in a high charge density that has strong polarizing effects on its surroundings. Furthermore, Mg2+ forms a sharply defined first hydration shell with an integer number of coordinating water molecules. As a result, an exclusion zone exists around the ion within which no water molecules are observed. Moreover, Mg2+ displays a high solvation free energy and a low exchange rate of waters from its first hydration shell. Finally, it contains a strong preference towards oxygens . Together, this makes Mg2+ a particularly well suited interaction partner for the charged non-bridging phosphate oxygens on nucleic acid backbones and explains its crucial biological role.
The immense number of physiological and technological functions and applications indicates the significant scientific attention Mg2+ received. In experimental studies, however, severe difficulties arise for multiple reasons: Mg2+ is spectroscopically silent and cannot be detected directly by resonance techniques like NMR or EPR. Indirect observation is possible, either by detecting changes in the overall RNA structure with and without bound Mg2+, or by replacing the Mg2+ ion with another spectroscopically visible ion. In the latter, however, it cannot be guaranteed that the altered ion does not also alter the interaction site or even the whole structure. Another detection method is X-ray crystallography, but here challenges arise from Mg2+ being almost indistinguish- able from other ions as well as from water if not for very high resolutions and precise stereochemical considerations.
Alternatively, molecular dynamics (MD) simulations can be performed, with the power of adding atomistic insight to the interplay of metal cations and nucleic acids. MD simulations, however, are only as accurate as their underlying interaction models and the development of accurate models for the description of Mg2+ faces challenges especially in describing three properties:
(i) Polarizability. Commonly used simple models like the 12-6 type Lennard-Jones model typically fail to reproduce simultaneously thermodynamic and structural properties of a single ion in water. Alternative strategies include the use of a 12-6-4 type Lennard-Jones potential as proposed by Li and Merz, where the additional r−4 term explicitly accounts for polarization effects. The resulting Lennard-Jones potential is thereby more attractive and more long-ranged than for typical models of the 12-6 type.
(ii) Kinetics. Most Mg2+ models either fully ignore considerations about the timescales on which water exchanges from the first hydration shell of the ion or use inappropriate methodology to calculate the underlying kinetics. A realistic characterization of the involved timescales is imperative to be able to describe a seemingly simple process like the transition from inner-to-outer sphere binding and vice versa. This transition governs most biochemical reactions involving Mg2+ and therefore subsequent processes can only by as fast as the transition itself. However, already the previous step – the exchange of a water from the first hydration shell of the ion – is described my current Mg2+ models up to four orders of magnitude too slowly, which makes the observation of such events on the timescale of a typical simulation difficult or even impossible. Alln ́er et al. [48] as well as Lemkul and MacKerell explicitly considered the exchange rate into their parameter optimization procedure. To compute the rate, both studies applied Transition State Theory along a single reaction coordinate – the distance towards one of the exchanging waters. However, it could be shown that the water exchange from the first hydration shell requires at least the consideration of both exchanging water molecules in order to be able to realistically record the underlying rate using Transition State Theory. Furthermore, the model of Alln ́er et al. significantly underestimates the free energy of solvation of the ion.
(iii) Interactions between Mg2+ and nucleic acids. Typically, ionic force field parame- terization concentrates on the optimization of solution properties. The trans- ferability of these solution optimized parameters towards interactions with biomolecules, however, often fails.
Die Sulfonyl-Gruppe (-SO2-) ist ein weit verbreitetes Strukturmotiv in der organischen Chemie und Bestandteil vieler biologisch aktiver Moleküle, insbesondere Arzneistoffen. Zwei der am häufigsten auftretenden Gruppen sind Sulfone und Sulfonamide, die in über 100 zugelassenen Medikamenten und 10% der meistverkauften Medikamente sind. Insofern kommt der Entwicklung neuer Synthesemethoden eine große Bedeutung zu. Dabei stehen besonders einfache, wirtschaftliche und zeitsparende Vorgehensweisen im Vordergrund, die eine große Bandbreite an neuen Substanzen generieren können. Ein Ansatz hierfür sind Multikomponenten- oder Eintopfreaktionen.
Aufgrund der Wichtigkeit dieser zwei Strukturklassen, sollen im Rahmen der hier vorliegenden Doktorarbeit neue Syntheserouten für Sulfone und Sulfonamide entwickelt werden. Besonderes Augenmerk wird auf die die Einführung der SO2-Einheit während der Reaktionsführung gelegt. Im Vergleich zu bereits existierenden Verfahren ist dies ein enormer Fortschritt, da die Mehrheit der bekannten Routen auf Schwefel- oder Schwefeldioxid-haltige Startmaterialien zurückgreift.
In der vorliegenden Arbeit gelang es, einen synthetischen Zugang zu Arylsulfonen basierend auf von Natrium-, Lithium-, Magnesium- und Zinksulfinaten zu finden. Diese Reaktion besitzt eine sehr große Anwendungsbandbreite und setzt sowohl Aryl- als auch Alkylsulfinate effizient um. Außerdem weisen Reaktionen mit unsymmetrischen Diaryliodoniumsalzen hohe Chemoselektivitäten auf.
Auf der Grundlage auf der Reaktion zwischen Natriumsulfinaten und Iodoniumsalzen wurde eine simple Route zur Synthese von Diarylsulfonen abgeleitet, jedoch war hierbei die Sulfonylgruppe noch Bestandteil eines der Edukte. Um die SO2-Einheit während der Reaktion einführen zu können, wurde ein praktisches Eintopf-Protokoll entwickelt, welches die direkte Umsetzung von (hetero)aromatischen und alkylischen Halogeniden zu Arylsulfonen gestattet. Diese innovative Methode besteht aus folgenden vier Schritten: (1) Generierung des Organometallreagenzes via Halogen-Metall-Austausch, direkte Metallinsertion oder Deprotonierung; (2) Reaktion des Organometallreagenzes mit SO2 zum Sulfinat; (3) Entfernen des SO2-Überschusses und flüchtiger Komponenten und (4) Umsetzung des nicht aufgereinigten Sulfinates mit einem Iodoniumsalz.
Desweiteren wird in dieser Arbeit ein neuartiger Übergangsmetall-katalysierter Ansatz zur Darstellung von Diarylsulfonen ausgehend von Arylhalogeniden und Sulfinaten diskutiert. Erste Experimente deuten auf Nickel-Katalysatoren als gute Wahl für die Reaktion. Optimierungsreaktionen zeigten eine starke Abhängigkeit der Ausbeute in Hinsicht auf die Bisswinkel der an das zentrale Nickelatom koordinierten Liganden. Da die bis dato besten Ergebnisse mit dem Komplex [o-tol-Ni(PPh2Me)2Cl] erzielt wurden, wird der [o-tol-Ni(PMe3)2Cl]-Komplex momentan in unserem Labor weiteren Studien unterzogen. Bislang ist davon auszugehen, dass dieser Katalysator hervorragende Ergebnisse liefert und zu einer allgemein gültigen Methode führt.
In weiteren Kapiteln wird die Anwendbarkeit von SO2-Surrogaten, Metabisulfiten „S2O52-„ oder DABSO; untersucht; mit dem Ziel eine Eintopf- oder Multikomponentenreaktion zu entwickeln.
Zum einen wird die Entwicklung einer Ein-Topf-Reaktion von Alkylhalogeniden mit Metabisulfiten und Organozinkreagenzien zur Darstellung von Alkylarylsulfonen vorgestellt. Darüber hinaus wird eine Übergangsmetall-katalysierte Multikomponenten Reaktion zur Synthese von Sulfonsäureamiden vorgestellt. Eine Reaktion zwischen Aminen, Arylhalogeniden und DABSO als SO2-Quelle wurde in Form einer Palladium-katalysierten Aminosulfonylierung entwickelt.
The fact that the interaction of oligonucleotides follows strict rules has been utilized to create two- or three-dimensional objects made of DNA. With computer-assisted design of DNA sequences, any arbitrary structure on the nanometer- to micrometer-scale can be generated just by hybridization of the needed strands. As astonishing these structures are, without any modification of the DNA strands involved no function can be assigned to them. Many different ways of functionalizing DNA-nanostructures have been developed with light-responsive nanostructures having a rather subordinated role. Almost all light responsive DNA-nanostructures involve the acyclic azobenzene-linking system tAzo based on D-threoninol which is known to work best at elevated temperatures to ensure optimal switching. As the structure of DNA-constructs is mainly maintained by hydrogen-bonding, variation of the temperature should be avoided in order to keep the structure intact.
To develop a light-responsive nanostructure model system with low-temperature operating azobenzene C-nucleosides, DNA-minicircles have been utilized. Those minicircles bear a lariat-like protrusion with a 10 base long single-stranded overhang, which is responsible for the dimerization with a ring bearing a complementary binding region. DNA-minicircles have been produced in a sequential manner by building and purifying the single stranded minicircle first by splint ligation and prepratative PAGE or RP-HPLC, followed by annealing it to the outer ring and subsequent purification by molecular-weight cut-off. Imaging of DNA-minicircles by atomic force microscopy (AFM) was possible with several methods of sample preparation leading to images of varying quality. With the help of AFM, qualitative analysis of the minicircles was possible. It could be shown, that theoretical and empirical size dimensions of the rings and their interactions were in great accordance. Designing the interaction site of the minicircles proved to be the main task in this project. The amount of C-nucleosidic modifications was identified by screening, followed by a screening of their optimal position and binding partners in the counterstrand. Two azobenzene C-nucleosides in a 10mer binding region and abasic sites opposing them appeared to give the best compromise between absolute dimerization ratio and photocontrolled change of it, as identified by native PAGE. In the following, the dimerization ratios of minicircles containing azobenzene C-nucleosides were compared with minicircles containing tAzo and unmodified minicircles. It could be shown, that the tAzo-modification leads to an elevated binding affinity compared to the unmodified minicircles, but the change upon irradiation is relatively humble compared to the C-nucleosides. For the C-nucleosidic modifications dimerization ratios reached a maximum of 40% in favored trans-state, but could be almost completely turned-off when switching into cis-state. In addition, arylazopyrazole-modified C-nucleosides could be switched into trans-state by irradiating at 530 nm, which is an improvement compared to standard azobenzene, as it shifts irradiation wavelength closer to the phototherapeutic window.
The utilization of DNA-analogous C-nucleosides bring two drawbacks with them: the ribose units include the flexibility of the sugar conformation and it is reasonable to think, that upon isomerization of the azobenzene, part of the steric stress generated is compensated by the sugar reconfiguration, which is lost for duplex
destabilization. In addition, the combination of the ribosidic linker end the end-to-end distance of trans-azobenzene causes the chromophore to penetrate deep into the base stack of the opposing strand, causing a serious destabilization even in favored trans-state. The goal was to find a linker system, that combines the benefits of the azobenzene C-nucleoside without the possibility to change sugar conformation and the strong destabilization in the trans-state. For this reason locked azobenzene C-nucleosides in analogy to LNA nucleosides have been synthesized. The synthesis of LNA analogous azobenzene C-nucleosides (LNAzo) was possible over a 16-step synthesis, with the critical step being the addition of in situ lithiated azobenzene to protected sugar aldehyde. Both anomers of LNAzo and mAzo as reference where incorporated into different oligonucleotide test systems by solid phase synthesis for thorough evaluation. It could be shown, that LNAzo β has a similar performance to mAzo in DNA with overall slightly increased TM- and ΔTM-values. Performance of LNAzo β was similar to mAzo even if steric stress is reduced by using abasic sites in the counterstrand opposing the azobenzene. Only in a RNA context, the true potential of LNAzo β could be observed. In a DNA/RNA duplex, photocontrol could be improved by almost 50%, in a RNA/RNA duplex even by over 100%. Although the primary goal was the improvement of the azobenzene C-nucleoside for a DNA-nanostructure context, LNAzo β proved not to give a sufficient improvement in regard to the cost-value ratio. Never the less, the invention of the locked azobenzene C-nucleoside was a huge success for reversible photoregulation of RNA hybridization. With this, a new way to regulate RNA hybridization has been found, which could be used to create RNA therapeutics in an antisense-approach.
As LNAzo β improved duplex stability only in a limited amount in DNA, further improvements on the backbone have been declared futile and focus shifted onto optimization of the chromophore. First, the azobenzene as it is installed on the ribosidic linker decreases duplex stability by forcing its distal aromat deep into opposing base stacking region. It would be an improvement, if in favored trans-state the distal aromat would be positioned in the less confined space of either major or minor groove and only upon isomerization would shift into base pairing region. Second, the azobenzene itself is not able to contribute to attractive interactions aside from relatively weak π-interactions to adjacent nucleobases, which could be improved, if it could partake in hydrogen bonding. For those apparent reasons, 2-phenyldiazenyl-modified purines have been selected as targets. They combine the ability to contribute to hydrogen bonding of nucleobases with the photochomicity of azobenzenes. Both 2’-deoxyadenosine- and 2’-deoxyguanosine-analogue photoswitches dAAzo and dGAzo have been synthesized and incorporated into 10mer DNA test systems by solid phase synthesis. It could be shown, that duplex stability could be increased compared to established azobenzene C-nucleoside. The improvement was stronger for dAAzo than for dGAzo as in the case for guanosine the amino function on the C2-position had to be replaced by the phenyldiazenyl function, reducing its ability to form hydrogen bonds. Unfortunately, photocontrol of duplex stability caused by 2-phenyldiazenyl purines was rather limited. A reason for this could be the positioning of the distal aromat within the duplex, which can be close to the opposing nucleobase (endo-helical) or in greater distance (exo-helical). The exo-helical conformation of the trans-isomer can only switch to the exo-P-cis-conformation, which relocates the distal aromat in the minor groove, without significant impact on duplex stability.
Silicon wafers such as Silicon on Insulator (SOI) and strained silicon on Insulator (sSOI) are the essential and basic materials of advanced microelectronic devices. However, they often show various kinds of crystal defects which impair the function of these devices. The most efficient method to date, for detecting such defects and for determining their density, is to delineate them by etching the wafers with a suitable etching solution and characterise them via light optical microscopy. Etch pits are formed at defect sites which are etched at a faster rate than at the perfect lattice. The standard etching solution used for SOI and sSOI is a dilute version of Secco. As Secco contains carcinogenic and environmentally hazardous chromium (VI), the use of which is or will be restricted by law in many countries, suitable chromium (VI)-free etching solutions like Organic Peracid Etches (OPE), modified Chemical Polishing Etches (CP) like CP4 mod and mixtures with organic oxidizing agents like chloranil (CA) have been developed for the successful delineation of various types of crystal defects.
However there are still nanometer-sized defects which are hard to detect or escape detection by this method. Copper decoration is a well known method to magnify these defects. It consists in applying a copper nitrate solution to the back of the SOI or sSOI wafer. On annealing, copper diffuses through the substrate and the BOX (buried oxide) to the SOI/sSOI film and on quenching to room temperature, copper precipitates as copper silicide, SiCu3, foremost at crystal defects where the lattice strain is greater than at perfect lattice sites. These silicides increase the volume in these parts of the crystal lattice and defect magnification occurs. A considerable disadvantage of this method is its tendency for artefact formation, when the copper concentration used is too high, with the copper precipitating at the film surface. The consequence is a higher density of etch pits whereby true defect etch pits cannot be differentiated from those caused by artefacts.
The aim of this thesis is to show that the processes of decorating and etching can be combined successfully to delineate all crystal defects in SOI and sSOI. An ideal result would have been to find a copper decoration procedure that decorates all existing crystal defects at a copper concentration that avoids artefact formation.
Development and implementation of novel optogenetic tools in the nematode Caenorhabditis elegans
(2016)
Optogenetics, though still only a decade old field, has revolutionized research in neurobiology. It comprises of methods that allow control of neural activity by light in a minimally-invasive, spatio-temporally precise and genetically targeted manner. The optogenetic actuators or the genetically encoded light sensitive elements mediate light driven manipulation of membrane potential, intracellular signalling, neuronal network activity and behaviour (Fenno et al. 2011; Dugué et al. 2012). These techniques have been particularly useful for dissecting neural circuits and behaviour in the transparent and genetically amenable nematode model system Caenorhabditis elegans (Husson et al. 2013; Fang-yen et al. 2015).
In fact, C. elegans was the first living organism in which microbial rhodopsin based optogenetic tools (Channelrhodopsin-2 or ChR2, and Halorhodopsin or NpHR) were successfully implemented and bimodal 'remote' control of behaviour was achieved (Nagel et al. 2005; Zhang et al. 2007). Since then it has been a prominent model for the development and application of novel optogenetic tools and techniques, especially in the nervous system which comprises of 302 neurons and is organised in a hierarchical organization. The environmental stimuli are sensed by the sensory neurons, leading to the processing of information by the downstream interneurons, that relay to motor neurons which in-turn synapse onto muscles that drive the movement-based responses.
The microbial rhodopsins like ChR2 and NpHR mediate light driven depolarization and hyperpolarization, respectively and thereby activate or inhibit neural activity. However, they do not allow local control of membrane potential as they are expressed all over the plasma membrane of the cell rather than being restricted to specific domains, for example synaptic sites. Moreover, they completely over-ride the intrinsic activity of the cell, completely bypassing the signal transduction processes inside the cell. Thus, in order to study intracellular signalling and to answer questions pertaining to the endogenous role of receptors and channels in an in-vivo context, the optogenetic tool-kit needs to be expanded.
This thesis aimed at developing and implementing novel optogenetic tools in C. elegans that allow for sub-cellular signalling control as well as endogenous receptor control. These are: two light activated guanylyl cyclases (bPGC and BeCyclOp) to modify cyclic guanosine monophosphate (cGMP) mediated signalling in the sensory neurons, as well as attempts towards rendering endogenous C. elegans receptors - glutamate receptor (GLR-3/-6), acetylcholine receptor (ACR-16), glutamate gated chloride channel (GLC-1) light switchable and to understand their biological function in-vivo.
Organisms respond to sensory cues by activation of a primary receptor followed by relay of information downstream to effector targets by secondary signalling molecules. cGMP is a widely used 2nd messenger in cellular signaling, acting via protein kinase G or cyclic nucleotide gated (CNG) channels. In sensory neurons, cGMP allows for signal modulation and amplification, before depolarization. Chemo-, thermo-, and oxygen-sensation in C. elegans involve sensory neurons that use cGMP as the main 2nd messenger. For example, ASJ is the pheromone sensing neuron regulating larval development, AWC is the chemosensory neuron responding to volatile odours and BAG senses oxygen and carbon dioxide in the environment. In these neurons, cGMP acts downstream of the GPCRs and functions by activating cationic TAX-2/-4 CNG channels, thereby depolarising the sensory neuron. Manipulating cGMP levels is required to access signalling between sensation and sensory neuron depolarization, thereby provide insights into signal encoding. We achieve this by implementing two photo-activatable guanylyl cyclases - 1) a mutated version of Beggiatoa sp. bacterial light-activated adenylyl cyclase, with specificity for GTP (Ryu et al. 2010), termed BlgC or bPGC (Beggiatoa photoactivated guanylyl cyclase) and 2) guanylyl cyclase rhodopsin (Avelar et al. 2014) from Blastocladiella emersonii (BeCyclOp).
bPGC is a BLUF (blue light sensing using flavin) domain containing cyclase which uses FAD as the co-factor and catalyses the synthesis of cGMP from GTP upon activation by blue light. Prior to implementation in sensory neurons, a simpler heterologous system with co-expression of the TAX-2/-4 CNG channel in C. elegans body wall muscle (BWM) was used. The cGMP generated by the light activated cyclases activates the CNG channel leading to the muscle depolarization, thereby causing changes in body length which can be easily scored.
In Nervensystemen werden zahlreiche Informationen wahrgenommen und verarbeitet um ein adäquates Verhalten hervorzurufen. Für die Untersuchung der funktionellen Zusammenhänge hierbei wurden verschiedene Methoden entwickelt, die eine gezielte Manipulation neuronaler Prozesse ermöglichen. Durch Analyse der resultierenden Effekte können dabei synaptische Proteine, einzelne Neuronen oder neuronale Netzwerke funktionell charakterisiert werden. Bisherige Ansätze verfügen jedoch nur über eine geringe zeitliche und räumliche Auflösung oder erlauben lediglich eine eingeschränkte Anwendung im frei beweglichen Tier.
Diese Nachteile können durch die heterologe Expression von lichtgesteuerten, mikrobiellen Rhodopsinen zur gezielten Manipulation des Membranpotentials umgangen werden. So induziert die Photoaktivierung des Kationenkanals Channelrhodopsin 2 (ChR2; (Nagel et al., Curr Biol 2005)) eine Depolarisation, während die Chloridpumpe Halorhodopsin (NpHR; (Zhang et al., Nature 2007)) für die Hyperpolarisation verwendet werden kann. Dabei ermöglichen die schnellen Kinetiken der Rhodopsine eine zeitlich präzise Steuerung des Membranpotentials. Durch Auswahl geeigneter Promotoren ist zudem oftmals eine zell spezifische Expression möglich. Dieser Ansatz wird daher allgemein als Optogenetik bezeichnet.
In der vorliegenden Arbeit wurden zunächst konventionelle Techniken genutzt, um die Funktion von zwei assoziierten Proteinen eines Acetylcholin Rezeptors in C. elegans zu untersuchen. Des Weiteren wurden verschiedene Methoden für den Fadenwurm entwickelt und angewendet, die die Vorteile optogenetischer Techniken für die funktionelle Charakterisierung synaptischer Proteine und neuronaler Netzwerke nutzbar machen. Hierbei erlaubt die Transparenz von C. elegans die optogenetische Stimulation im lebenden Organismus unter nicht invasiven Bedingungen. Weitere Vorteile von C. elegans als neurobiologischem Modellorganismus liegen in seiner einfachen Handhabung (Hope, 1999) und der stereotypen Entwicklung seines Nervensystems mit bekannten anatomischen Ausprägungen (Sulston and Horvitz, Dev Biol 1977; Varshney et al., PLoS Comput Biol 2011; White et al., Philos Trans R Soc Lond B Biol Sci 1986). Durch ihre Häufigkeit und die experimentelle Zugänglichkeit wird hierbei die neuromuskuläre Synapse oftmals zur Erforschung der synaptischen Reizweiterleitung genutzt (Von Stetina et al., Int Rev Neurobiol 2006). Durch pharmakologische (Lewis et al., Neuroscience 1980; McIntire et al., Nature 1993; Miller et al., Proc Natl Acad Sci U S A 1996; Richmond and Jorgensen, Nat Neurosci 1999) und elektrische Stimulation (Richmond and Jorgensen, Nat Neurosci 1999) können dabei Defekte der Transmission hervorgehoben werden, während Verhaltensexperimente oder elektrophysiologische Messungen der post synaptischen Ströme in Muskelzellen eine quantitative Analyse ermöglichen (Richmond and Jorgensen, Nat Neurosci 1999).
Diese Methoden wurden für die funktionelle Charakterisierung von NRA 2 und NRA 4 verwendet, die beide als akzessorische Proteine zusammen mit dem Levamisol sensitiven Acetylcholin Rezeptor der Körperwandmuskelzellen aufgereinigt wurden (Gottschalk et al., EMBO J 2005). Dabei konnte gezeigt werden, dass NRA 2 und NRA 4 im Endoplasmatischen Retikulum (ER) der Muskelzellen einen Komplex bilden, der die Sensitivität von beiden nikotinischen Acetylcholin Rezeptoren gegenüber verschiedenen cholinergen Agonisten verändert. In diesem Zusammenhang wurde auch nachgewiesen, dass die Oberflächenexpression einzelner Untereinheiten der beiden Rezeptoren durch NRA 2/4 beeinflusst wird. Diese Resultate legen die Vermutung nahe, dass beide Proteine die Zusammensetzung der Rezeptoren und somit ihre pharmakologischen Eigenschaften modulieren. Denkbar ist dabei eine regulatorische Funktion bei der Assemblierung verschiedener Untereinheiten zu einem funktionellen Rezeptor oder bei der Kontrolle des ER Austritts von Rezeptoren mit bestimmter Zusammensetzung. In dieser Hinsicht konnte jedoch keine Interaktion von NRA 2/4 mit der Notch Signalkaskade nachgewiesen werden, wie sie für die homologen Proteine nicalin und NOMO in Vertebraten gezeigt wurde (Haffner et al., J Biol Chem 2007; Haffner et al., EMBO J 2004).
Für die Untersuchung synaptischer Proteine durch optogenetische Techniken wurde ChR2(H134R) selektiv in cholinergen oder GABAergen Motorneuronen exprimiert, um die akute und lichtgesteuerte Freisetzung des jeweiligen Neurotransmitters zu ermöglichen. Die resultierende Stimulation bzw. Inhibition von Muskelzellen wurde hierbei durch elektrophysiologische Messungen der post synaptischen Ströme und durch Analyse von Kontraktionen respektive Relaxationen untersucht. Dabei wurde gezeigt, dass Störungen der synaptischen Reizweiterleitung die Ausprägung und Dynamik dieser lichtinduzierten Effekte beeinflussen und dadurch charakterisiert werden können. So zeigten beispielsweise Mutanten von Synaptojanin und Endophilin nachlassende Effekte bei anhaltender oder wiederholter Stimulation, was durch die gestörte Regeneration synaptischer Vesikel erklärt werden kann (Harris et al., J Cell Biol 2000; Schuske et al., Neuron 2003; Verstreken et al., Neuron 2003).
Die hohe Sensitivität dieser Methode wurde im Nachfolgenden dazu verwendet, die Inhibition cholinerger Motorneuronen durch den metabotropen GABAB Rezeptor zu untersuchen, der in C. elegans aus den beiden Untereinheiten GBB 1 und GBB 2 gebildet wird (Dittman and Kaplan, J Neurosci 2008; Vashlishan et al., Neuron 2008). Dabei konnte zunächst gezeigt werden, dass diese heterosynaptische Inhibition verschiedene lokomotorische Verhaltensweisen der Tiere beeinflusst. Für die mechanistische Untersuchung wurden anschließend cholinerge Motorneuronen durch ChR2(H134R) photoaktiviert, während resultierende Kontraktionseffekte in Abhängigkeit von GBB 1/2 analysiert wurden. Um hierbei die Funktion von GBB 1/2 durch erhöhte GABA Konzentrationen hervorzuheben, wurden zusätzlich GABAerge Motorneuronen optogenetisch stimuliert oder die Wiederaufnahme von GABA aus dem synaptischen Spalt durch Mutation des Membran ständigen GABA Transporters blockiert. So konnte gezeigt werden, dass GBB 1/2 eine akute Inhibition der cholinergen Motorneuronen bewirken, was vermutlich für die Regulation von Bewegungsabläufen eine wichtige Rolle spielt. Die geringe Dynamik der GBB 1/2 induzierten Effekte deutet allerdings darauf hin, dass die synaptische Aktivität durch den metabotropen Rezeptor kaum nachhaltig moduliert wird.
In nachfolgenden Versuchen wurde die optogenetische Stimulation von Motorneuronen außerdem mit der elektronenmikroskopischen Analyse der präsynaptischen Feinstruktur kombiniert. Dadurch konnte die Dynamik der Exozytose und Endozytose synaptischer Vesikel (SV) in Abhängigkeit von neuronaler Aktivität untersucht werden. So wurde gezeigt, dass synaptische Vesikel nahe der aktiven Zone während einer 30 sekündigen Hyperstimulation nahezu komplett aufgebraucht waren. Die vollständige Regeneration der SV Pools benötigte anschließend etwa 12 Sekunden und erfolgte zunächst in der Peripherie der aktiven Zone, was auf eine laterale Heranführung der Vesikel schließen lässt. Nach etwa 20 Sekunden erholte sich ebenfalls die Wirksamkeit der Stimulation von Muskelzellen durch die Motorneuronen, was durch elektrophysiologische Messungen der photo induzierten post synaptischen Ströme gezeigt wurde. Während der Hyperstimulation bildeten sich außerdem große vesikuläre Strukturen, die sich anschließend nach etwa acht Sekunden wieder aufgelöst hatten. In Analogie zu vergleichbaren Experimenten in anderen Organismen liegt die Vermutung nahe, dass es sich dabei um Zwischenprodukte der so genannten Bulk Phase Endozytose handelt, die das Clathrin abhängige Recycling von synaptischen Vesikeln bei starker neuronaler Aktivität ergänzt (Heuser and Reese, J Cell Biol 1973; Miller and Heuser, J Cell Biol 1984; Richards et al., Neuron 2000). Bemerkenswerterweise war der Abbau der vesikulären Strukturen in Synaptojanin und Endophilin defizienten Tieren stark verzögert. Denkbar ist, dass beide Proteine für die Synthese von synaptischen Vesikeln aus den vesikulären Zwischenprodukten der Bulk Phase Endozytose wichtig sind, analog zur ihrer Funktion bei der Clathrin abhängigen Endozytose an der Plasmamembran.
Durch die zielgerichtete Manipulation der Zellaktivität ermöglichen optogenetische Techniken außerdem die funktionelle Charakterisierung von Neuronen und neuronalen Netzwerken. Um die zelluläre Spezifität dieses Ansatzes zu erhöhen, wurde ein Tracking System entwickelt das die Position frei beweglicher Tiere in Echtzeit bestimmt und nachverfolgt. Dadurch konnte die Photoaktivierung optogenetischer Proteine auf definierte Bereiche der Fadenwürmer und somit auf ausgewählte Neuronen innerhalb der Expressionsmuster von verwendeten Promotoren eingeschränkt werden. Des Weiteren ermöglichte hierbei die Auswertung translatorischer Parameter die Analyse verschiedener lokomotorischer Merkmale wie Geschwindigkeit, Bewegungsbahn oder Ausprägung der Körperbiegungen. Dieses System wurde beispielhaft für die konzertierte Photoaktivierung durch ChR2(H134R) bzw. Photoinhibition durch MAC von zwei verschiedenen Gruppen von Neuronen angewendet, um die Integration mechanosensorischer Informationen durch Command Interneuronen zu untersuchen. In diesem Zusammenhang wurde zudem eine Rekombinase basierte Methode für optogenetische Proteine adaptiert, die die Transkription auf die zelluläre Schnittmenge von zwei verschiedenen Promotoren einschränkt und somit die Spezifität der Expression erhöht. Idealerweise kann dieser Ansatz außerdem mit der gezielten Photoaktivierung kombiniert werden, um die zelluläre Selektivität optogenetischer Anwendungen weiter zu verbessern.
Weiterhin ist die Anwendung optogenetischer Techniken bisher durch intrinsische Eigenschaften der verwendeten Rhodopsine auf die relativ kurzzeitige Manipulation des Membranpotentials von Zellen beschränkt. So benötigt ChR2 durch die schnelle Schließung seines offenen Kanals eine kontinuierliche Photoaktivierung, um eine andauernde Depolarisation hervorzurufen. Dies ist jedoch potentiell mit phototoxischen und – besonders bei C. elegans – phototaktischen Nebeneffekten verbunden. Deswegen wurden diverse Mutanten von ChR2 mit stark verlangsamter Inaktivierung (Berndt et al., Nat Neurosci 2009) für ihren Nutzen zur Langzeit Stimulation von erregbaren Zellen im Nematode getestet. Dabei wurde gezeigt, dass ChR2(C128S) durch einen kurzen Photostimulus mit vergleichsweise niedriger Intensität eine anhaltende Depolarisation über mehrere Minuten auslösen kann. Die wiederholte Stimulation in ASJ Neuronen ermöglichte zudem eine langzeitige Depolarisation über mehrere Tage, wodurch die genetisch veranlagte Entwicklung von Tieren manipuliert werden konnte. Durch gezielte Punktmutation konnten außerdem relevante Eigenschaften von ChR2(C128S) für die Langzeit Stimulation weiter verbessert werden.
Als weiteres optogenetisches Werkzeug wurde zudem die Photoaktivierbare Adenylatzyklase alpha (PACa) aus Euglena gracilis (Iseki et al., Nature 2002; Ntefidou et al., Plant Physiol 2003; Schroder-Lang et al., Nat Methods 2007) für die akute und lichtgetriebene Synthese des sekundären Botenstoffs cAMP in C. elegans etabliert. Die Photoaktivierung von PACa in cholinergen Motorneuronen verstärkte dabei die Neurotransmitterfreisetzung und induzierte hyperlokomotorische Phänotypen, vergleichbar zu Mutanten mit erhöhten cAMP Konzentrationen.
Zusammengefasst wurden diverse optogenetische Techniken für C. elegans entwickelt und optimiert, die die zellspezifische und nicht invasive Manipulation des Membranpotentials beziehungsweise die Synthese des sekundären Botenstoffs cAMP durch Licht im frei beweglichen Tier ermöglichen. Diese Methoden können zur gezielten Störung neuronaler Aktivität angewendet werden, um dadurch neurobiologische Fragestellungen im Fadenwurm zu untersuchen. Dies wurde beispielhaft für die Erforschung der synaptischen Reizweiterleitung und die funktionelle Analyse neuronaler Netzwerke demonstriert. Denkbar ist außerdem, diese für C. elegans etablierten Methoden vergleichbar in anderen Modellorganismen anzuwenden. So sind die Fruchtfliege ebenso wie der Zebrafisch Embryo bereits für optogenetische Techniken erprobt (Arrenberg et al., Proc Natl Acad Sci U S A 2009; Schroll et al., Curr Biol 2006). Für Säugetiere wie die Maus, die Ratte und den Makaken wurden zudem bereits Ansätze entwickelt, die die gezielte Photostimulation in lebenden und frei beweglichen Tieren ermöglichen (Han et al., Neuron 2009; Wentz et al., J Neural Eng 2011; Yizhar et al., Nature 2011; Zhang et al., Nat Rev Neurosci 2007).
Escherichia coli nitrate reductase A (NarGHI) is a membrane-bound enzyme that couples quinol oxidation at a periplasmically oriented Q-site (Q(D)) to proton release into the periplasm during anaerobic respiration. To elucidate the molecular mechanism underlying such a coupling, endogenous menasemiquinone-8 intermediates stabilized at the Q(D) site (MSQ(D)) of NarGHI have been studied by high-resolution pulsed EPR methods in combination with (1)H2O/2H2O exchange experiments. One of the two non-exchangeable proton hyperfine couplings resolved in hyperfine sublevel correlation (HYSCORE) spectra of the radical displays characteristics typical from quinone methyl protons. However, its unusually small isotropic value reflects a singularly low spin density on the quinone carbon α carrying the methyl group, which is ascribed to a strong asymmetry of the MSQ(D) binding mode and consistent with single-sided hydrogen bonding to the quinone oxygen O1. Furthermore, a single exchangeable proton hyperfine coupling is resolved, both by comparing the HYSCORE spectra of the radical in 1H2O and 2H2O samples and by selective detection of the exchanged deuterons using Q-band 2H Mims electron nuclear double resonance (ENDOR) spectroscopy. Spectral analysis reveals its peculiar characteristics, i.e. a large anisotropic hyperfine coupling together with an almost zero isotropic contribution. It is assigned to a proton involved in a short ∼1.6 Å in-plane hydrogen bond between the quinone O1 oxygen and the Nδ of the His-66 residue, an axial ligand of the distal heme b(D). Structural and mechanistic implications of these results for the electron-coupled proton translocation mechanism at the Q(D) site are discussed, in light of the unusually high thermodynamic stability of MSQ(D).
Pulsed electron-electron double resonance (PELDOR), also called Double Electron-Electron Resonance, (DEER) is a pulsed EPR technique that can provide structural information of biomolecules, such as proteins or nucleic acids, complementary to other structure determination methods by measuring long distances (from 1.5 up to 10 nm) between two paramagnetic labels. Incorporation of the rigid Ç-label pairwise into DNA or RNA molecules enables the determination not only of the distance but also of the mutual orientation between the two Ç-labels by multi-frequency orientation-selective PELDOR data (X-, Q- and G-band frequencies). Thus, information about the orientation of secondary structure elements of nucleic acids can be revealed and used as additional angular information for structure determination. Since Ç does not have motion independent from the helix where it resides, the conformational flexibility of the nucleic acid molecule can be directly determined. This thesis demonstrates the advancement of PELDOR spectroscopy, beyond its original scope of distance measurements, to determine the mutual orientation between two rigid spin labels towards the characterization of the conformational space sampled by highly flexible nucleic acid molecules. Applications of the methodology are shown on two systems: a three-way junction, namely a cocaine aptamer in its bound-state, and a two-way junction, namely a bent DNA.
More in detail, the conformational changes of the cocaine aptamer upon cocaine binding were investigated by analysis of the distance distributions. The cocaine-bound and the unbound states could be differentiated by their conformational flexibility, which decreases in the presence of the ligand. Moreover, the obtained distance distributions revealed a small change in the mean distance between the two spin labels upon cocaine binding. This indicates a ligand-induced conformational change, which presumably originates at the junction where cocaine is known to bind. The investigation of the relative orientation between the two spin-labeled helices of the aptamer revealed further structural insights into the conformational dynamics of the cocaine-bound state. The angular information from the orientation-selective PELDOR data and the a priori knowledge about the secondary structure of the aptamer were helpful in obtaining a molecular model describing its global folding and flexibility. In spite of a large flexible aptamer, the kink angle between the Ç-labeled helices was found to be rather well-defined.
As for the bent DNA molecule, a two-step protocol was proposed to investigate the conformational flexibility. In the first step, a database with all the possible conformers was created, using available restraints from NMR and distance restraints derived from PELDOR. In a second step, a weighted ensemble of these conformers fitting the multi-frequency PELDOR data was built. The uniqueness of the obtained structural ensemble was checked by validation against an independent PELDOR data set recorded at a higher magnetic field strength. In addition, the kink and twist angle pairs were determined and the resulting structural ensemble was compared with the conformational space deduced both from FRET experiments and from the structure determined by the NMR restraints alone.
Overall, this thesis underlines the potential of using PELDOR spectroscopy combined with rigid spin labels in the context of structure determination of nucleic acids in order to determine the relative orientation between two helices, the conformational flexibility and the conformational changes of nucleic acid molecules upon ligand binding.
A novel series of ribonucleosides of 1,2,3-triazolylbenzyl-aminophosphonates was synthesized through the Kabachnik–Fields reaction using I2 as catalyst followed by copper-catalyzed cycloaddition of the azide–alkyne reaction (CuAAC). All structures of the newly prepared compounds were characterized by 1H NMR, 13C NMR, and HRMS spectra. The structures of 2e, 2f, 3d, and 3g were further confirmed by X-ray diffraction analysis. These compounds were tested against various strains of DNA and RNA viruses; compounds 4b and 4c showed a modest inhibitory activity against respiratory syncytial virus (RSV) and compound 4h displayed modest inhibitory activity against Coxsackie virus B4.
The arachidonic acid cascade is a key player in inflammation, and numerous well-established drugs interfere with this pathway. Previous studies have suggested that simultaneous inhibition of 5-lipoxygenase (5-LO) and soluble epoxide hydrolase (sEH) results in synergistic anti-inflammatory effects. In this study, a novel prototype of a dual 5-LO/sEH inhibitor KM55 was rationally designed and synthesized. KM55 was evaluated in enzyme activity assays with recombinant enzymes. Furthermore, activity of KM55 in human whole blood and endothelial cells was investigated. KM55 potently inhibited both enzymes in vitro and attenuated the formation of leukotrienes in human whole blood. KM55 was also tested in a cell function-based assay. The compound significantly inhibited the LPS-induced adhesion of leukocytes to endothelial cells by blocking leukocyte activation.
Dual- or multi-target ligands have gained increased attention in the past years due to several advantages, including more simple pharmacokinetic and phamarcodynamic properties compared to a combined application of several drugs. Furthermore multi-target ligands often possess improved efficacy. We present a new approach for the discovery of dual-target ligands using aligned pharmacophore models combined with a shape-based scoring. Starting with two sets of known active compounds for each target, a number of different pharmacophore models is generated and subjected to pairwise graph-based alignment using the Kabsch-Algorithm. Since a compound may be able to bind to different targets in different conformations, the algorithm aligns pairs of pharmacophore models sharing the same features which are not necessarily at the exactly same spatial distance. Using the aligned models, a pharmacophore search on a multi-conformation-database is performed to find compounds matching both models. The potentially “dual” ligands are scored by a shape-based comparison with the known active molecules using ShaEP.
Using this approach, we performed a prospective fragment-based virtual screening for dual 5-LO/sEH inhibitors. Both enzymes play an important role in the arachidonic acid cascade and are involved in inflammatory processes, pain, cardiovascular diseases and allergic reactions. Beside several new selective inhibitors we were able to find a compound inhibiting both enzymes in low micromolar concentrations. The results indicate that the idea of aligned pharmacophore models can be successfully employed for the discovery of dual-target ligands.
Aptamers that can be regulated with light allow precise control of protein activity in space and time and hence of biological function in general. In a previous study, we showed that the activity of the thrombin-binding aptamer HD1 can be turned off by irradiation using a light activatable "caged" intramolecular antisense-domain. However, the activity of the presented aptamer in its ON state was only mediocre. Here we studied the nature of this loss in activity in detail and found that switching from 5'- to 3'-extensions affords aptamers that are even more potent than the unmodified HD1. In particular we arrived at derivatives that are now more active than the aptamer NU172 that is currently in phase 2 clinical trials as an anticoagulant. As a result, we present light-regulatable aptamers with a superior activity in their ON state and an almost digital ON/OFF behavior upon irradiation.
The transcriptional regulator far upstream binding protein 1 (FUBP1) is essential for fetal and adult hematopoietic stem cell (HSC) self-renewal, and the constitutive absence of FUBP1 activity during early development leads to embryonic lethality in homozygous mutant mice. To investigate the role of FUBP1 in murine embryonic stem cells (ESCs) and in particular during differentiation into hematopoietic lineages, we generated Fubp1 knockout (KO) ESC clones using CRISPR/Cas9 technology. Although FUBP1 is expressed in undifferentiated ESCs and during spontaneous differentiation following aggregation into embryoid bodies (EBs), absence of FUBP1 did not affect ESC maintenance. Interestingly, we observed a delayed differentiation of FUBP1-deficient ESCs into the mesoderm germ layer, as indicated by impaired expression of several mesoderm markers including Brachyury at an early time point of ESC differentiation upon aggregation to EBs. Coculture experiments with OP9 cells in the presence of erythropoietin revealed a diminished differentiation capacity of Fubp1 KO ESCs into the erythroid lineage. Our data showed that FUBP1 is important for the onset of mesoderm differentiation and maturation of hematopoietic progenitor cells into the erythroid lineage, a finding that is supported by the phenotype of FUBP1-deficient mice.
High-throughput protein localization studies require multiple strategies. Mass spectrometric analysis of defined cellular fractions is one of the complementary approaches to a diverse array of cell biological methods. In recent years, the protein content of different cellular (sub-)compartments was approached. Despite of all the efforts made, the analysis of membrane fractions remains difficult, in that the dissection of the proteomes of the envelope membranes of chloroplasts or mitochondria is often not reliable because sample purity is not always warranted. Moreover, proteomic studies are often restricted to single (model) species, and therefore limited in respect to differential individual evolution. In this study we analyzed the chloroplast envelope proteomes of different plant species, namely, the individual proteomes of inner and outer envelope (OE) membrane of Pisum sativum and the mixed envelope proteomes of Arabidopsis thaliana and Medicago sativa. The analysis of all three species yielded 341 identified proteins in total, 247 of them being unique. 39 proteins were genuine envelope proteins found in at least two species. Based on this and previous envelope studies we defined the core envelope proteome of chloroplasts. Comparing the general overlap of the available six independent studies (including ours) revealed only a number of 27 envelope proteins. Depending on the stringency of applied selection criteria we found 231 envelope proteins, while less stringent criteria increases this number to 649 putative envelope proteins. Based on the latter we provide a map of the outer and inner envelope core proteome, which includes many yet uncharacterized proteins predicted to be involved in transport, signaling, and response. Furthermore, a foundation for the functional characterization of yet unidentified functions of the inner and OE for further analyses is provided.
We have determined the crystal structures of two decachlorocyclopentasilanes, namely bis(tetra-n-butylammonium) dichloride decachlorocyclopentasilane dichloromethane disolvate, 2C16H36N+·2Cl−·Si5Cl10·2CH2Cl2, (I), and bis(tetraethylammonium) dichloride decachlorocyclopentasilane dichloromethane disolvate, 2C8H20N+·2Cl−·Si5Cl10·2CH2Cl2, (II), both of which crystallize with discrete cations, anions, and solvent molecules. In (I), the complete decachlorocyclopentasilane ring is generated by a crystallographic twofold rotation axis. In (II), one cation is located on a general position and the other two are disordered about centres of inversion. These are the first structures featuring the structural motif of a five-membered cyclopentasilane ring coordinated from both sides by a chloride ion. The extended structures of (I) and (II) feature numerous C—H⋯Cl interactions. In (II), the N atoms are located on centres of inversion and as a result, the ethylene chains are disordered over equally occupied orientations.
The asymmetric unit of the title compound, C18H18I2N2O2, consists of one half-molecule, completed by the application of inversion symmetry. The molecule adopts the typical structure for this class of bis-benxozazines, characterized by an anti orientation of the two benzoxazine rings around the central C—C bond. The oxazinic ring adopts a half-chair conformation. In the crystal, molecules are linked by C—I⋯N short contacts [I⋯N = 3.378 (2) Å], generating layers lying parallel to the bc plane.
Biogenesis of mitochondrial cytochrome c oxidase (COX) is a complex process involving the coordinate expression and assembly of numerous subunits (SU) of dual genetic origin. Moreover, several auxiliary factors are required to recruit and insert the redox-active metal compounds, which in most cases are buried in their protein scaffold deep inside the membrane. Here we used a combination of gel electrophoresis and pull-down assay techniques in conjunction with immunostaining as well as complexome profiling to identify and analyze the composition of assembly intermediates in solubilized membranes of the bacterium Paracoccus denitrificans. Our results show that the central SUI passes through at least three intermediate complexes with distinct subunit and cofactor composition before formation of the holoenzyme and its subsequent integration into supercomplexes. We propose a model for COX biogenesis in which maturation of newly translated COX SUI is initially assisted by CtaG, a chaperone implicated in CuB site metallation, followed by the interaction with the heme chaperone Surf1c to populate the redox-active metal-heme centers in SUI. Only then the remaining smaller subunits are recruited to form the mature enzyme which ultimately associates with respiratory complexes I and III into supercomplexes.
Understanding the conformational sampling of translation-arrested ribosome nascent chain complexes is key to understand co-translational folding. Up to now, coupling of cysteine oxidation, disulfide bond formation and structure formation in nascent chains has remained elusive. Here, we investigate the eye-lens protein γB-crystallin in the ribosomal exit tunnel. Using mass spectrometry, theoretical simulations, dynamic nuclear polarization-enhanced solid-state nuclear magnetic resonance and cryo-electron microscopy, we show that thiol groups of cysteine residues undergo S-glutathionylation and S-nitrosylation and form non-native disulfide bonds. Thus, covalent modification chemistry occurs already prior to nascent chain release as the ribosome exit tunnel provides sufficient space even for disulfide bond formation which can guide protein folding.
The excellent results of dispersion‐corrected density functional theory (DFT‐D) calculations for static systems have been well established over the past decade. The introduction of dynamics into DFT‐D calculations is a target, especially for the field of molecular NMR crystallography. Four 13C ss‐NMR calibration compounds are investigated by single‐crystal X‐ray diffraction, molecular dynamics and DFT‐D calculations. The crystal structure of 3‐methylglutaric acid is reported. The rotator phases of adamantane and hexamethylbenzene at room temperature are successfully reproduced in the molecular dynamics simulations. The calculated 13C chemical shifts of these compounds are in excellent agreement with experiment, with a root‐mean‐square deviation of 2.0 ppm. It is confirmed that a combination of classical molecular dynamics and DFT‐D chemical shift calculation improves the accuracy of calculated chemical shifts.
Crystallization and X-ray diffraction studies of a complete bacterial fatty-acid synthase type I
(2015)
While a deep understanding of the fungal and mammalian multi-enzyme type I fatty-acid synthases (FAS I) has been achieved in recent years, the bacterial FAS I family, which is narrowly distributed within the Actinomycetales genera Mycobacterium, Corynebacterium and Nocardia, is still poorly understood. This is of particular relevance for two reasons: (i) although homologous to fungal FAS I, cryo-electron microscopic studies have shown that bacterial FAS I has unique structural and functional properties, and (ii) M. tuberculosis FAS I is a drug target for the therapeutic treatment of tuberculosis (TB) and therefore is of extraordinary importance as a drug target. Crystals of FAS I from C. efficiens, a homologue of M. tuberculosis FAS I, were produced and diffracted X-rays to about 4.5 Å resolution.
1. Fab co-complexes of proton pumping NADH:ubiquinone oxidoreductase (complex I) Fab fragments suitable for co-crystallization with complex I were generated using an immobilized papainbased protocol. The binding of the antibody fragments to complex I was verified using Surface Plasmon Resonance and size exclusion chromatography. The binding constants of the antibodies and their respective Fab fragments were found to be in the nanomolar range. This work presents the first report on successful crystallization of complex I (proton pumping NADH:ubiquinone oxidoreductase) from Yarrowia lipolytica with proteolytic Fab fragments. The quality of the crystals was significantly improved when compared to the initial experiments and the best crystals diffracted X-rays to a resolution of ~7 Å. The activity of complex I remained uninfluenced by antibody fragment binding. The initial diffraction data suggest that the complex I/Fab co-complex crystals represent a space group different to the one observed for the native protein. Ongoing experiments are aimed at further enhancements of the diffraction quality of the crystals. Providing a different space group the CI/Fab co-complexes may become a very useful approach for structure determination of the enzyme. Moreover, the bound Fab offers an additional possibility to generate phase information. The antibody-mediated crystallization represents a valuable tool in structural characterization of the NADH:oxidoreductase subcomplexes or even single subunits. 2. UDP-glucose pyrophosphorylase UDP-glucose pyrophosphorylase from Yarrowia lipolytica displays affinity towards Ni2+ NTA and was first detected in a contaminated sample of complex I. Following, separation from complex I, Ugp1p was purified using anion exchange chromatography. Sequence similarity studies revealed high identity to other known pyrophosphorylases. As indicated by laser-based mass spectrometry method (LILBID) Ugp1p from Y. lipolytica builds octamers similarly to the enzyme from Saccharomyces cerevisiae. The initial crystals grew as thin needles favorably in sitting drop setups. The size of the crystals was increased by employment of a micro batch technique. The improved crystals diffracted X-rays to a resolution of 3.2 Å at the synchrotron beamline. Structural characterization is under way using a molecular replacement approach based on the published structure of baker’s yeast UGPase.
Large crystals of the methyl ester of the N-a-benzyloxycarbonyl protected Ala-Phe dipeptide (Z-AF-OMe) were obtained after the very slow evaporation of a solution of the corresponding carboxylic acid (Z-AF-OH) in methanol containing an excess of HCl. The structure was confirmed by single crystal X-ray diffraction data. It crystallizes in the orthorhombic space group P212121 with unit cell dimensions a = 5.0655(6) Å, b = 8.4614(8) Å, c = 46.856(5) Å, V = 2008.3(4) Å3, Z = 4. In the crystal, the molecules form hydrogen bonded chains running along the a axis of the unit cell. Other secondary interactions are also discussed.
The neuronal adaptor protein Fe65 is involved in brain development, Alzheimer disease amyloid precursor protein (APP) signaling, and proteolytic processing of APP. It contains three protein-protein interaction domains, one WW domain, and a unique tandem array of phosphotyrosine-binding (PTB) domains. The N-terminal PTB domain (Fe65-PTB1) was shown to interact with a variety of proteins, including the low density lipoprotein receptor-related protein (LRP-1), the ApoEr2 receptor, and the histone acetyltransferase Tip60. We have determined the crystal structures of human Fe65-PTB1 in its apo- and in a phosphate-bound form at 2.2 and 2.7A resolution, respectively. The overall fold shows a PTB-typical pleckstrin homology domain superfold. Although Fe65-PTB1 has been classified on an evolutionary basis as a Dab-like PTB domain, it contains attributes of other PTB domain subfamilies. The phosphotyrosine-binding pocket resembles IRS-like PTB domains, and the bound phosphate occupies the binding site of the phosphotyrosine (Tyr(P)) within the canonical NPXpY recognition motif. In addition Fe65-PTB1 contains a loop insertion between helix alpha2 and strand beta2(alpha2/beta2 loop) similar to members of the Shc-like PTB domain subfamily. The structural comparison with the Dab1-PTB domain reveals a putative phospholipid-binding site opposite the peptide binding pocket. We suggest Fe65-PTB1 to interact with its target proteins involved in translocation and signaling of APP in a phosphorylation-dependent manner.
The title compound, C21H26Cl2N2O2, was prepared in a solvent-free microwave-assisted synthesis, and crystallizes in the orthorhombic space group Pna21. The imidazolidine ring adopts an envelope conformation and its mean plane is almost perpendicular to the two pendant aromatic rings [dihedral angles = 84.61 (9) and 86.54 (9)°]. The molecular structure shows the presence of two intramolecular O—H⋯N hydrogen bonds between the phenolic hydroxy groups and imidazolidine N atoms. The two 3-chloro-6-hydroxy-2,4-dimethylbenzyl groups are located in a cis orientation with respect to the imidazolidine fragment. As a result, the lone pairs of electrons on the N atoms are presumed to be disposed in a syn conformation. This is therefore the first example of an exception to the `rabbit-ears' effect in such 2,2′-[imidazolidine-1,3-diylbis(methylene)]diphenol derivatives.
The asymmetric unit of the title co-crystalline adduct, 1,3,6,8-tetraazatricyclo[4.4.1.13,8]dodecane (TATD)–4-iodophenol (1/2), C8H16N4·2C6H5IO, comprises a half molecule of the aminal cage polyamine plus a 4-iodophenol molecule. A twofold rotation axis generates the other half of the adduct. The components are linked by two intermolecular O—H⋯N hydrogen bonds. The adducts are further linked into a three-dimensional framework structure by a combination of N⋯I halogen bonds and weak non-conventional C—H⋯O and C—H⋯I hydrogen bonds.
In the crystal of the title co-crystalline adduct, C8H16N4·C8H9ClO, (I), prepared by solid-state reaction, the molecules are linked by intermolecular O—H⋯N hydrogen bonds, forming a D motif. The azaadamantane structure in (I) is slightly distorted, with N—CH2—CH2—N torsion angles of 10.4 (3) and −9.0 (3)°. These values differ slightly from the corresponding torsion angles in the free aminal cage (0.0°) and in related co-crystalline adducts, which are not far from a planar geometry and consistent with a D2d molecular symmetry in the tetraazatricyclo structure. The structures also differ in that there is a slight elongation of the N—C bond lengths about the N atom that accepts the hydrogen bond in (I) compared with the other N—C bond lengths. In the crystal, the two molecules are not only linked by a classical O—H⋯N hydrogen bond but are further connected by weak C—H⋯π interactions, forming a two-dimensional supramolecular network parallel to the bc plane.
The structure of the 1:2 co-crystalline adduct C8H16N4·2C6H5BrO, (I), from the solid-state reaction of 1,3,6,8-tetraazatricyclo[4.4.1.13,8]dodecane (TATD) and 4-bromophenol, has been determined. The asymmetric unit of the title co-crystalline adduct comprises a half molecule of aminal cage polyamine plus a 4-bromophenol molecule. A twofold rotation axis generates the other half of the adduct. The primary inter-species association in the title compound is through two intermolecular O—H⋯N hydrogen bonds. In the crystal, the adducts are linked by weak non-conventional C—H⋯O and C—H⋯Br hydrogen bonds, giving a two-dimensional supramolecular structure parallel to the bc plane.
In the title compound, C7H14N4·2C6H5ClO, which crystallized with two crystallographically independent 4-chlorophenol molecules and one 1,3,6,8-tetraazatricyclo[4.3.1.13,8]undecane (TATU) molecule in the asymmetric unit, the independent components are linked by two O-H...N hydrogen bonds. The hydrogen-bond acceptor sites are two non-equivalent N atoms from the aminal cage structure, and the tricyclic system distorts by changing the C-N bond lengths. In the crystal, these hydrogen-bonded aggregates are linked into chains along the c axis by C-H...N hydrogen bonds. The crystal structure also features C-H...[pi] contacts.
In the title ternary co-crystalline adduct, C7H14N4·2C6H5NO3, molecules are linked by two intermolecular O—H⋯N hydrogen bonds, forming a tricomponent aggregates in the asymmetric unit. The hydrogen-bond formation to one of the N atoms is enough to induce structural stereoelectronic effects in the normal donor→acceptor direction. In the title adduct, the two independent nitrophenol molecules are essentially planar, with maximum deviations of 0.0157 (13) and 0.0039 (13) Å. The dihedral angles between the planes of the nitro group and the attached benzene rings are 4.04 (17) and 5.79 (17)°. In the crystal, aggregates are connected by C—H⋯O hydrogen bonds, forming a supramolecular dimer enclosing an R66(32) ring motif. Additional C—H⋯O intermolecular hydrogen-bonding interactions form a second supramolecular inversion dimer with an R22(10) motif. These units are linked via C—H⋯O and C—H⋯N hydrogen bonds, forming a three-dimensional network.
In the title salt, [Ag(C27H36N2)2]Cl·C4H8O, the AgI atom is coordinated by two 1,3-bis(2,6-dimethylphenyl)imidazol-2-ylidene ligands. The imidazole rings are inclined to one another by 46.69 (13)° and the benzene rings in each ligand are almost normal to the imdazole ring to which they are attached, with dihedral angles varying from 82.39 (13) to 88.27 (12)°. There are C—H⋯π interactions present in the cation, involving the two ligands, and the solvent molecule is linked to the cation via a C—H⋯O hydrogen bond. In the crystal, molecules are linked by trifurcated C—H⋯(Cl,Cl,Cl) hydrogen bonds, forming slabs parallel to (101). One isopropyl group is disordered over two sets of sites with an occupancy ratio of 0.447 (17):0.553 (17) and the THF molecule is disordered over two positions with an occupancy ratio of 0.589 (6):0.411 (6).
The title compound, di-μ3-chlorido-tetra-μ2-chlorido-tetrakis(diethyl ether-κO)bis(1,1-dimethylethyl)tetramagnesium, [Mg4(C4H9)2Cl6(C4H10O)4], features an Mg4Cl6 open-cube cluster. The two four-coordinate Mg2+ ions show an almost tetrahedral coordination, whereas the two six-coordinate Mg2+ ions have their ligands in an octahedral environment. The Mg—Cl bond lengths differ depending on the coordination number (2 or 3) of the bridging μ-Cl− ligands. There are few comparable structures deposited in the Cambridge Structural Database.
In the title compound, C20H24N2O4, both peptide bonds adopt a trans configuration with respect to the —N—H and —C=O groups. The dihedral angle between the aromatic rings is 53.58 (4)°. The molecular conformation is stabilized by an intramolecular N—H⋯O hydrogen bond. The crystal packing is characterized by zigzag chains of N—H⋯O hydrogen-bonded molecules running along the b-axis direction.
In the title compound, C26H24N2O2, the oxazine moiety is fused to a naphthalene ring system. The asymmetric unit consists of one half of the molecule, which lies about an inversion centre. The C atoms of the ethylene spacer group adopt an antiperiplanar arrangement. The oxazine ring adopts a half-chair conformation. In the crystal, supramolecular chains running along the b axis are formed via short C—H⋯π contacts. The crystal studied was a non-merohedral twin with a fractional contribution of 0.168 (2) of the minor twin component.
In the title compound, C23H19NO2, an oxazine Mannich base derivative, the oxazine ring has a half-chair conformation. The 2-hydroxynaphthalen-1-yl substituent is placed in an axial position. There is an intramolecular O-H...N hydrogen bond, forming an S(6) graph-set motif. In the crystal, molecules are connected by a pair of C-H...[pi] interactions into an inversion dimer, which is reinforced by another pair of weak C-H...[pi] interactions. The dimers are linked by a [pi]-[pi] interaction [centroid-centroid distance = 3.6268 (17) Å], consolidating a column along the a axis. Furthermore, the columns interact with each other by a weak C-H...[pi] interaction, generating a three-dimensional network.
In the title compound, C17H18N2O, the central carbon atom with the OH substituent and one of the (E)-benzylideneamino substituents are disordered over two sets of sites with occupancies of 0.851 (4) and 0.149 (4). The relative positions of the two disorder components is equivalent to a rotation of approximately 60° about the C—N single bond. In the crystal, the molecules are held together by O—H...N hydrogen bonds, forming simple C(5) chains along the b-axis direction. In addition, pairs of the chains are further aggregated by weak C—H...π interactions.
The title Schiff base, C19H22N2O3, was synthesized via the condensation reaction of 1,3-diaminopropan-2-ol with 4-methoxybenzaldehyde using water as solvent. The molecule exists in an E,E conformation with respect to the C=N imine bonds and the dihedral angle between the aromatic rings is 37.25 (15)°. In the crystal, O-H...N hydrogen bonds link the molecules into infinite C(5) chains propagating along the a-axis direction. The packing of these chains is consolidated by C-H...O interactions and C-H...[pi] short contacts, forming a three-dimensional network.
Crystal structure of 1,3-bis(3-tert-butyl-2-hydroxy-5-methylbenzyl)-1,3-diazinan-5-ol monohydrate
(2016)
In the title hydrate, C28H42N2O3·H2O, the central 1,3-diazinan-5-ol ring adopts a chair conformation with the two benzyl substituents equatorial and the lone pairs of the N atoms axial. The dihedral angle between the aromatic rings is 19.68 (38)°. There are two intramolecular O-H...N hydrogen bonds, each generating an S(6) ring motif. In the crystal, classical O-H...O hydrogen bonds connect the 1,3-diazinane and water molecules into columns extending along the b axis. The crystal structure was refined as a two-component twin with a fractional contribution to the minor domain of 0.0922 (18).
The title solvated salt, C29H41N2+·Br-·2CH2Cl2 was obtained from the reaction of the Arduengo-type carbene 1,3-bis(2,6-diisopropylphenyl)-1,3-dihydro-4,5-dimethyl-2H-imidazol-2-ylidene with Si2Br6 in dichloromethane. The complete cation is generated by a crystallographic mirror plane and the dihedral angle between the five-membered ring and the benzene ring is 89.8 (6)°; the dihedral angle between the benzene rings is 40.7 (2)°. The anion also lies on the mirror plane and both dichloromethane molecules are disordered across the mirror plane over two equally occupied orientations. In the crystal, the cations are linked to the anions via C-H...Br hydrogen bonds.
The title benzoxazine molecule, C18H18Br2N2O2, was prepared by a Mannich-type reaction of 4-bromophenol with ethane-1,2-diamine and formaldehyde. The title compound crystallizes in the monoclinic space group C2/c with a centre of inversion located at the mid-point of the C-C bond of the central CH2CH2 spacer. The oxazinic ring adopts a half-chair conformation. The structure is compared to those of other functionalized benzoxazines synthesized in our laboratory. In the crystal, weak C-H...Br and C-H...O hydrogen bonds stack the molecules along the b-axis direction.
The crystal structure of the title compound, C25H24N2O2, at 173 K has monoclinic (C2/c) symmetry. The molecule is located on a crystallographic twofold rotation axis with only half a molecule in the asymmetric unit. The imidazolidine ring adopts a twist conformation, with a twist about the ring C—C bond. The crystal structure shows the anticlinal disposition of the two (2-hydroxynaphthalen-1-yl)methyl substituents of the imidazolidine ring. The structure displays two intramolecular O—H⋯N hydrogen bonds, each forming an S(6) ring motif.
The title fluorinated bisbenzoxazine, C18H18F2N2O2, crystallizes with one half-molecule in the asymmetric unit, which is completed by inversion symmetry. The fused oxazine ring adopts an approximately half-chair conformation. The two benzoxazine rings are oriented anti to one another around the central C-C bond. The dominant intermolecular interaction in the crystal structure is a C-H...F hydrogen bond between the F atoms and the axial H atoms of the OCH2N methylene group in the oxazine rings of neighbouring molecules. C-H...[pi] contacts further stabilize the crystal packing.
Microbial rhodopsins are omnipresent on Earth, however the vast majority of them remain uncharacterized. Here we describe a new rhodopsin clade from cold-adapted organisms and cold environments, such as glaciers, denoted as CryoRhodopsins (CryoRs). Our data suggest that CryoRs have photosensory activity. A distinguishing feature of the clade is the presence of a buried arginine residue close to the cytoplasmic face of its members. Combining single-particle cryo-electron microscopy and X-ray crystallography with the rhodopsin activation by light, we demonstrate that the arginine stabilizes a strongly blue-shifted intermediate of an extremely slow CryoRhodopsin photocycle. Together with extensive spectroscopic characterization, our investigations on CryoR1 and CryoR2 proteins reveal mechanisms of photoswitching in the newly identified clade and demonstrate principles of the adaptation of these rhodopsins to low temperatures.
Microbial rhodopsins are omnipresent on Earth, however the vast majority of them remain uncharacterized. Here we describe a new rhodopsin group from cold-adapted organisms and cold environments, such as glaciers, denoted as CryoRhodopsins (CryoRs). Our data suggest that CryoRs have dual functionality switching between inward transmembrane proton translocation and photosensory activity, both of which can be modulated with UV light. CryoR1 exhibits two subpopulations in the ground state, which upon light activation lead to transient photocurrents of opposing polarities. A distinguishing feature of the group is the presence of a buried arginine residue close to the cytoplasmic face of its members. Combining single-particle cryo-electron microscopy and X-ray crystallography with the rhodopsin activation by lit, we demonstrate that the arginine stabilizes a UV-absorbing intermediate of an extremely slow CryoRhodopsin photocycle. Together with extensive spectroscopic characterization, our investigations on CryoR1 and CryoR2 proteins reveal mechanisms of photoswitching in the newly identified group and demonstrate principles of the adaptation of these rhodopsins to low temperatures.Microbial rhodopsins are omnipresent on Earth, however the vast majority of them remain uncharacterized. Here we describe a new rhodopsin group from cold-adapted organisms and cold environments, such as glaciers, denoted as CryoRhodopsins (CryoRs). Our data suggest that CryoRs have dual functionality switching between inward transmembrane proton translocation and photosensory activity, both of which can be modulated with UV light. CryoR1 exhibits two subpopulations in the ground state, which upon light activation lead to transient photocurrents of opposing polarities. A distinguishing feature of the group is the presence of a buried arginine residue close to the cytoplasmic face of its members. Combining single-particle cryo-electron microscopy and X-ray crystallography with the rhodopsin activation by light, we demonstrate that the arginine stabilizes a UV-absorbing intermediate of an extremely slow CryoRhodopsin photocycle. Together with extensive spectroscopic characterization, our investigations on CryoR1 and CryoR2 proteins reveal mechanisms of photoswitching in the newly identified group and demonstrate principles of the adaptation of these rhodopsins to low temperatures.
CryoEM structures of membrane pore and prepore complex reveal cytolytic mechanism of Pneumolysin
(2017)
Many pathogenic bacteria produce pore-forming toxins to attack and kill human cells. We have determined the 4.5 Å structure of the ~2.2 MDa pore complex of pneumolysin, the main virulence factor of Streptococcus pneumoniae, by cryoEM. The pneumolysin pore is a 400 Å ring of 42 membrane-inserted monomers. Domain 3 of the soluble toxin refolds into two ~85 Å β-hairpins that traverse the lipid bilayer and assemble into a 168-strand β-barrel. The pore complex is stabilized by salt bridges between β-hairpins of adjacent subunits and an internal α-barrel. The apolar outer barrel surface with large sidechains is immersed in the lipid bilayer, while the inner barrel surface is highly charged. Comparison of the cryoEM pore complex to the prepore structure obtained by electron cryo-tomography and the x-ray structure of the soluble form reveals the detailed mechanisms by which the toxin monomers insert into the lipid bilayer to perforate the target membrane.
CryoEM at IUCRJ: a new era
(2016)
Cryo-EM structures of KdpFABC suggest a K+ transport mechanism via two inter-subunit half-channels
(2018)
P-type ATPases ubiquitously pump cations across biological membranes to maintain vital ion gradients. Among those, the chimeric K+ uptake system KdpFABC is unique. While ATP hydrolysis is accomplished by the P-type ATPase subunit KdpB, K+ has been assumed to be transported by the channel-like subunit KdpA. A first crystal structure uncovered its overall topology, suggesting such a spatial separation of energizing and transporting units. Here, we report two cryo-EM structures of the 157 kDa, asymmetric KdpFABC complex at 3.7 Å and 4.0 Å resolution in an E1 and an E2 state, respectively. Unexpectedly, the structures suggest a translocation pathway through two half-channels along KdpA and KdpB, uniting the alternating-access mechanism of actively pumping P-type ATPases with the high affinity and selectivity of K+ channels. This way, KdpFABC would function as a true chimeric complex, synergizing the best features of otherwise separately evolved transport mechanisms.
In fungi, the mitochondrial respiratory chain complexes (complexes I–IV) are responsible for oxidative phosphorylation, as in higher eukaryotes. Cryo-EM was used to identify a 200 kDa membrane protein from Neurospora crassa in lipid nanodiscs as cytochrome c oxidase (complex IV) and its structure was determined at 5.5 Å resolution. The map closely resembles the cryo-EM structure of complex IV from Saccharomyces cerevisiae. Its ten subunits are conserved in S. cerevisiae and Bos taurus, but other transmembrane subunits are missing. The different structure of the Cox5a subunit is typical for fungal complex IV and may affect the interaction with complex III in a respiratory supercomplex. Additional density was found between the matrix domains of the Cox4 and Cox5a subunits that appears to be specific to N. crassa.
Single-molecule localization microscopy (SMLM) reports on protein organization in cells with near-molecular resolution and in combination with stoichiometric labeling enables protein counting. Fluorescent proteins allow stoichiometric labeling of cellular proteins; however, most methods either lead to overexpression or are complex and time demanding. We introduce CRISPR/Cas12a for simple and efficient tagging of endogenous proteins with a photoactivatable protein for quantitative SMLM and single-particle tracking. We constructed a HEK293T cell line with the receptor tyrosine kinase MET tagged with mEos4b and demonstrate full functionality. We determine the oligomeric state of MET with quantitative SMLM and find a reorganization from monomeric to dimeric MET upon ligand stimulation. In addition, we measured the mobility of single MET receptors in vivo in resting and ligand-treated cells. The combination of CRISPR/Cas12a-assisted endogenous protein labeling and super-resolution microscopy represents a powerful tool for cell biological research with molecular resolution.
ATP-binding cassette (ABC) transporters, a superfamily of integral membrane proteins, catalyse the translocation of substrates across the cellular membrane by ATP hydrolysis. Here we demonstrate by nucleotide turnover and binding studies based on 31P solid-state NMR spectroscopy that the ABC exporter and lipid A flippase MsbA can couple ATP hydrolysis to an adenylate kinase activity, where ADP is converted into AMP and ATP. Single-point mutations reveal that both ATPase and adenylate kinase mechanisms are associated with the same conserved motifs of the nucleotide-binding domain. Based on these results, we propose a model for the coupled ATPase-adenylate kinase mechanism, involving the canonical and an additional nucleotide-binding site. We extend these findings to other prokaryotic ABC exporters, namely LmrA and TmrAB, suggesting that the coupled activities are a general feature of ABC exporters.
(Coumarin‐4‐yl)methyl (c4m) and p‐hydroxyphenacyl (pHP)‐based compounds are well known for their highly efficient photoreactions, but often show limited solubility in aqueous media. To circumvent this, we synthesized and characterized the two new c4m and pHP‐based photoacid generators (PAGs), 7‐[bis(carboxymethyl)amino]‐4‐(acetoxymethyl)coumarin (c4m‐ac) and p‐hydroxyphenacyl‐2,5,8,11‐tetraoxatridecan‐13‐oate (pHP‐t), and determined their solubilities, stabilities and photolysis in aqueous media. The two compounds showed high solubilities in water of 2.77 mmol L−1±0.07 mmol L−1 (c4m‐ac) and 124.66 mmol L−1±2.1 mmol L−1 (pHP‐t). In basic conditions at pH 9, solubility increased for c4m‐ac to 646.46 mmol L−1±0.63 mmol L−1, for pHP‐t it decreased to 34.68 mmol L−1±0.62 mmol L−1. Photochemical properties of the two PAGs, such as the absorption maxima, the maximum molar absorption coefficients and the quantum yields, were found to be strongly pH‐dependent. Both PAGs showed high stabilities s24h ≥95 % in water for 24 h, but decreasing stability with increasing pH value due to hydrolysis. The present study contributes to a clearer insight into the synthesis, solubilities, stabilities, and photolysis of c4m and pHP‐based PAGs for further photochemical applications when high PAG concentrations are required, such as in polymeric foaming.
Correlative microscopy incorporates the specificity of fluorescent protein labeling into high-resolution electron micrographs. Several approaches exist for correlative microscopy, most of which have used the green fluorescent protein (GFP) as the label for light microscopy. Here we use chemical tagging and synthetic fluorophores instead, in order to achieve protein-specific labeling, and to perform multicolor imaging. We show that synthetic fluorophores preserve their post-embedding fluorescence in the presence of uranyl acetate. Post-embedding fluorescence is of such quality that the specimen can be prepared with identical protocols for scanning electron microscopy (SEM) and transmission electron microscopy (TEM); this is particularly valuable when singular or otherwise difficult samples are examined. We show that synthetic fluorophores give bright, well-resolved signals in super-resolution light microscopy, enabling us to superimpose light microscopic images with a precision of up to 25 nm in the x-y plane on electron micrographs. To exemplify the preservation quality of our new method we visualize the molecular arrangement of cadherins in adherens junctions of mouse epithelial cells.
The authors regret that there is an error present in the units displayed in the sentence “The dissociation constant of docking domains or modules connected by docking domains was found to be KD 70–130 mM (ref. 35) and KD 1–2 mM (ref. 59), respectively.” within Section 3.1. Module–module exchanges. The corrected version of this sentence is as follows:
The dissociation constant of docking domains or modules connected by docking domains was found to be KD 70–130 μM (ref. 35) and KD 1–2 mM (ref. 59), respectively.
The Royal Society of Chemistry apologises for these errors and any consequent inconvenience to authors and readers.
Corneal topometric, aberrometric and biomechanical parameters in mucopolysaccharidosis patients
(2019)
Aims: To report corneal topometric and aberrometric values in mucopolysaccharidosis (MPS) and to investigate their correlation with biomechanical corneal parameters.
Methods: One randomly chosen eye of 20 MPS patients with no to moderate corneal clouding and one eye of 23 healthy controls with comparable age were prospectively included into this study. Corneal surface regularity was assessed by index of surface variance (ISV), -vertical asymmetry (IVA), -height asymmetry (IHA), -height decentration (IHD); keratoconus index (KI), central keratoconus index (CKI) and Zernike indices of anterior and posterior corneal surface using Scheimpflug imaging (Pentacam). Corneal resistance factor (CRF) and corneal hysteresis (CH) were assessed by Ocular Response Analyzer. Statistical analyses were performed using Mann-Whitney-Test and Spearman Correlation Coefficients.
Results: IVA, ISV, IHD, IHA, but not KI and CKI were significantly higher in MPS patients compared to age matched healthy controls. Spherical aberration and asphericity coefficients either at the anterior or at the posterior corneal surface differed significantly between both groups. The grade of the MPS-associated corneal opacity correlated significantly with ISV (rho = 0.52), IVA (rho = 0.54), IHA (rho = 0.57) and IHD (rho = 0.48). Density of the MPS-affected corneas correlated significantly with ISV (rho = 0.52), IVA (rho = 0.72), IHA (rho = 0.57), IHD (rho = 0.69), 3rd order horizontal trefoil aberration at the posterior (rho = 0.62) and anterior surface (rho = 0.48) as well as with CH (rho = 0.55) and CRF (rho = 0.57). Spherical aberration at the back surface correlated with CRF and CH in MPS and in healthy controls.
Conclusions: This is the first study analyzing shape of the corneal surface in MPS patients. Topometric indices of corneal asymmetry are significantly increased and correlate with MPS-related corneal opacity and density. Spherical aberration and asphericity coefficient at the front and at the back corneal surface differ significantly between MPS and healthy controls.
The crystal structure of C12H11N2SiCl3 (monoclinic, P21/m, Z = 2, with a: 9.284(4), b: 7.226(2), c: 10.832(5) Å, β = 115.14(3)°) was refined to R(F) =0.035 from 1228 independent reflections. A trigonal bipyramidal, pentacoordinate silicon is observed. The chelated complex shows two different Si−N bonds, a coordinative bond (1.984(2) Å) between Si and N on the axial position and a Si−N single bond (1.737(3) A, equatorial plane), introduced by chemical reaction. The coordinative bond is 14.2% longer than the Si−N single bond. The lengthening of the coordinative bond in the present case is compared with distances in other extracoordinated silicon compounds.
RNA-protein complexes (RNPs) are essential components in a variety of cellular processes, and oftentimes exhibit complex structures and show mechanisms that are highly dynamic in conformation and structure. However, biochemical and structural biology approaches are mostly not able to fully elucidate the structurally and especially conformationally dynamic and heterogeneous nature of these RNPs, to which end single molecule Förster resonance energy transfer (smFRET) spectroscopy can be harnessed to fill this gap. Here we summarize the advantages of strategic smFRET studies to investigate RNP dynamics, complemented by structural and biochemical data. Focusing on recent smFRET studies of three essential biological systems, we demonstrate that investigation of RNPs on a single molecule level can answer important functional questions that remained elusive with structural or biochemical approaches alone: The complex structural rearrangements throughout the splicing cycle, unwinding dynamics of the G-quadruplex (G4) helicase RHAU, and aspects in telomere maintenance regulation and synthesis.
Metal-organic frameworks (MOFs) have emerged as a promising class of crystalline porous inorganic-organic hybrid materials showing a wide range of applications. In order to realize the integration of MOFs into specific devices, this thesis mainly focuses on the controlled growth and the properties of highly oriented surface-mounted metal-organic frameworks (SURMOFs).
The stepwise layer-by-layer (LbL) growth method exhibits vast advantages for the controllable growth of SURMOFs regarding the crystallite orientation, film thickness and homogeneity. However, up to date, only a few MOFs have been demonstrated to be suited for this protocol. So the first project of this thesis was designed to extend the applicability of the LbL growth. To this end, a semi-rigid linker based [Cu2(sdb)2(bipy)] (sdb = 4,4’-sulfonylbiphenyl dicarboxylate; bipy = 4,4’-bipyridine) MOF was chosen. Employing the LbL growth, [Cu2(sdb)2(bipy)] SURMOFs were successfully grown onto both pyridyl- and carboxyl-terminated surfaces at the temperature range of 15-65 °C. Interestingly, the orientation of the SURMOFs largely depends on temperature on both surfaces. At low temperatures (below 40 °C), SURMOFs with exclusive [010] orientation are obtained. In contrast, at high temperatures (40-65 °C), [001] oriented SURMOF growth is favored. A novel growth mode was demonstrated, which is, instead of surface chemistry, the temperature-induced ripening processes and the tendency to minimize surface energies can dominate the SURMOF growth.
Inspired by the advantages of LbL deposition of isoreticular SURMOFs, the second project was conceived to grow multivariate SURMOFs (MTV-SURMOFs) using mixed dicarboxylate linkers. We advance a hypothesis that linker acidity (expressed by the pKa values) may have an influence on the oriented growth of MTV-SURMOFs. To test the hypothesis, seven isoreticular [Cu2L2(dabco)] (L = single kind of dicarboxylate linker; dabco = 1,4-diazabicyclo[2.2.2]octane) SURMOFs were grown onto pyridyl-terminated surfaces at 60 °C. The quality of [001] orientation is greatly affected by the acidity of the linkers. With this observation, we deposited a series of [Cu2Lm2(dabco)] (Lm = mixed dicarboxylate linkers) SURMOFs under the same conditions. [Cu2Lm2(dabco)] SURMOFs with exclusive [001] orientation are obtained when the growth solution contains two linkers of relatively high pKa value or more than two kinds of linkers (independent of the pKa values), while the mixtures of ligands with relatively low pKa values or a high content of low pKa valued linkers can result in mis-oriented growth of SURMOFs with unexpected [100] orientation.
Moreover, the LbL growth shows enormous potential in the rational construction of functional SURMOFs. Therefore, the third project of this thesis was devised to deposit SURMOFs containing redox-active species. For this, the 4,4’-biphenyldicarboxylic acid (H2(bpdc)) linker was functionalized with ferrocene (Fc) and dimethyl ferrocene (Me2Fc) moieties. [Cu2(bpdc-amide-Fc)2(dabco)] SURMOF (Fc-SURMOF) is perfectly grown along the [100] direction, while mis-oriented growth of [Cu2(bpdc-amide-Me2Fc)2(dabco)] SURMOF (Me2Fc-SURMOF) was observed. Surprisingly, Fc-SURMOF shows excellent electrochemical properties due to the reversible oxidation and reduction of the ferrocene moieties in the oriented pores, while the Me2Fc-SURMOF was found to be a closely packed insulating layer since no extensive charge transfer is observed. A diffusion controlled mechanism of redox reaction is proposed, where the diffusion of the counter anions in the pores limits the current.
Besides the LbL growth protocol, the spin-coating technique is also promising for the oriented growth of SURMOFs. Driven by the specific applications, the fourth project of this thesis was planned to grow functional SURMOFs containing catalytically active units. The Keggin-type polyoxometalates (POMs) with high catalytic activities were chosen to functionalize the HKUST-1 SURMOFs. Combining the technique with methanol vapor induced growth, a series of POM functionalized HKUST-1 SURMOFs (denoted as POM@HKUST-1 SURMOFs) were controllably deposited onto pyridyl-terminated surfaces. The SURMOFs exhibit great potential as electrocatalysts in electrochemical devices due to the excellent redox properties of POMs. In addition, the PTA@HKUST-1 (PTA = phosphotungstic acid) SURMOF can be employed as an ideal platform for the selective loading of methylene blue (MB) dye with high efficiency. Owing to the strong binding between the dye molecules and the framework, the MB dye cannot be desorbed by ion exchange and MB loaded PTA@HKUST-1 SURMOF shows reliable redox properties under inert conditions, further confirming the application potential in electrochemical devices.
Background: How a dentist works, such as the patterns of movements performed daily, is also largely affected by the workstation Dental tasks are often executed in awkward body positions, thereby causing a very high degree of strain on the corresponding muscles. The objective of this study is to detect those dental tasks, during which awkward postures occur most frequently. The isolated analysis of static postures will examine the duration for which these postures are maintained during the corresponding dental, respectively non-dental, activities.
Methods: 21 (11f/10 m) dentists (age: 40.1 ± 10.4 years) participated in this study. An average dental workday was collected for every subject. To collect kinematic data of all activities, the CUELA system was used. Parallel to the kinematic examination, a detailed computer-based task analysis was conducted. Afterwards, both data sets were synchronized based on the chronological order of the postures assumed in the trunk and the head region. All tasks performed were assigned to the categories "treatment" (I), "office" (II) and "other activities" (III). The angle values of each body region (evaluation parameter) were examined and assessed corresponding to ergonomic standards. Moreover, this study placed a particular focus on static positions, which are held statically for 4 s and longer.
Results: For "treatment" (I), the entire head and trunk area is anteriorly tilted while the back is twisted to the right, in (II) and (III) the back is anteriorly tilted and twisted to the right (non-neutral position). Static positions in (I) last for 4–10s, static postures (approx. 60%) can be observed while in (II) and (III) in the back area static positions for more than 30 s are most common. Moreover, in (II) the back is twisted to the right for more than 60 s in 26.8%.
Conclusion: Awkward positions are a major part of a dentists’ work. This mainly pertains to static positions of the trunk and head in contrast to "office work." These insights facilitate the quantitative description of the dentist profession with regard to the related physical load along with the health hazards to the musculoskeletal system. Moreover, the results allow for a selective extraction of the most unfavorable static body positions that dentists assume for each of the activities performed.
Up to now, very small protein-coding genes have remained unrecognized in sequenced genomes. We identified an mRNA of 165 nucleotides (nt), which is conserved in Bradyrhizobiaceae and encodes a polypeptide with 14 amino acid residues (aa). The small mRNA harboring a unique Shine-Dalgarno sequence (SD) with a length of 17 nt was localized predominantly in the ribosome-containing P100 fraction of Bradyrhizobium japonicum USDA 110. Strong interaction between the mRNA and 30S ribosomal subunits was demonstrated by their co-sedimentation in sucrose density gradient. Using translational fusions with egfp, we detected weak translation and found that it is impeded by both the extended SD and the GTG start codon (instead of ATG). Biophysical characterization (CD- and NMR-spectroscopy) showed that synthesized polypeptide remained unstructured in physiological puffer. Replacement of the start codon by a stop codon increased the stability of the transcript, strongly suggesting additional posttranscriptional regulation at the ribosome. Therefore, the small gene was named rreB (ribosome-regulated expression in Bradyrhizobiaceae). Assuming that the unique ribosome binding site (RBS) is a hallmark of rreB homologs or similarly regulated genes, we looked for similar putative RBS in bacterial genomes and detected regions with at least 16 nt complementarity to the 3′-end of 16S rRNA upstream of sORFs in Caulobacterales, Rhizobiales, Rhodobacterales and Rhodospirillales. In the Rhodobacter/Roseobacter lineage of α-proteobacteria the corresponding gene (rreR) is conserved and encodes an 18 aa protein. This shows how specific RBS features can be used to identify new genes with presumably similar control of expression at the RNA level.