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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.
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.
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.