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The ubiquinol:cytochrome c oxidoreductase is a key component of several aerobic respiratory chains in different organisms. It is an integral membrane protein complex, made up of three catalytic subunits (cytochrome b, cytochrome c1 and Rieske iron sulphur protein) and up to eight additional subunits in mitochondria. The complex oxidizes one quinol molecules and reduces two cytochrome c during the Q cycle, originally described by Peter Mitchell. Electrons are split between the low and the high potential chain and protons are released on the positive side of the membrane, increasing the protonmotive force needed by the ATP-synthase for energy transduction. The cytochrome bc1 complex from P. denitrificans is a perfect model for structural and functional studies. Bacteria are easy to grow and the genetic material is readily accessible for genetic manipulation. Moreover, the P. denitrificans aerobic respiratory chain is very close to the mitochondrial one: the complexes involved in electron transfer resemble the ones found in mitochondria, but lack most of the additional subunits. As a unique feature, P. denitrificans has a strongly acidic domain at the N-terminal region of the cytochrome c1, a sequence of 150 aminoacids which does not correlate with any known protein. An analogous composition can be found in the eukaryotic cytochrome bc1 complex as a part of an accessory subunit, proposed to be involved in facilitating electron transfer between the complex and the electron acceptor cytochrome c. In order to study the function of this domain in the P. denitrificans cytochrome bc1 complex, a deletion mutant has been previously cloned and modified with an affinity tag as a C-terminal extension of cytochrome b. The complex is purified by affinity chromatography and characterized by steady-state kinetics using not only horse heart cytochrome c but also the endogenous electron acceptor, the membrane bound cytochrome c552, employed here as a soluble fragment. Steady–state kinetics indicate that the deletion of the long acidic domain had effects neither on the turnover rate nor on the apparent affinity for the substrate. To understand wether the deletion affects the reaction between the cytochrome bc1 complex and the substrate, laser flash photolysis experiments are performed, showing that the interaction observed was not changed in the complex missing the acidic domain. The results presented in this work confirm the ones previously obtained by Julia Janzon using soluble fragments of the same interaction partners. The deletion, however, affected the oligomerization state of the complex, as shown by LILBID (Laser Induced Liquid Bead Ion Desorption) analysis. The wild type complex has a tetrameric structure, better described as a “dimer of dimers”. The deletion of the acidic domain on the cytochrome c1 results in the separation of the two dimers, yielding the canonical dimer. Therefore, the complex deleted in the acidic domain is used for cloning and expression of a heterodimeric complex, containing an inactivating mutation in the quinol oxidation site in only one monomer, thus allowing a selective switch-off for half the complex. Such a complex is needed for the verification of an internal regulation mechanism, the half-of-the-sites reactivity. According to it, the dimeric structure of the cytochrome bc1 complex has functional implications, since the two monomers can communicate and work in a coordinated manner. This approach confirms that substrate oxidation does effectively take place only in one of the two monomers constituting the dimer, and that the binding of substrate at the Qo and Qi site regulates the switch between active and inactive monomer. Moreover, this mechanism works also as an effective protection against the reaction of quinone intermediates with oxygen and the formation of reactive oxygen species (ROS), responsable for cellular aging. The motion of the ISP head domain is also addressed in this work; in particular the mechanism which regulates the movements towards the cytochrome c1 and the electron bifurcation at the quinol oxidation site. Laser flash kinetics in presence of several inhibitors and the substrate allow studying the response of the ISP to the binding of different species at the quinol oxidation site. The binding of ligand at the Qo site in the complex triggers the conformational switch in the ISP head domain, supporting the mechanism proposed in the literature according to which the Qo site is able to “sense” the presence of substrate and transfer the information to the ISP, regulating its mobility. The internal electron pathway between the ISP and the cytochrome c1 has been analyzed also by stopped-flow kinetics, in presence and absence of inhibitors. The results indicate that two kinetic phases describe the reduction of cytochrome c1 by the ISP, and a model for the simulation of the data is proposed.
11,12-Dihydrodibenzo[c,g]-1,2-diazocines have been established as a viable alternative to azobenzene for photoswitching, in particular, as they show an inverted switching behavior: the ground state is the Z isomer. In this paper, we present an improved method to obtain dibenzodiazocine and its derivatives from the respective 2-nitrotoluenes in two reaction steps, each proceeding in minutes. This fast access to a variety of derivatives permitted the study of substitution effects on the synthesis and on the photochemical properties. With biochemical applications in mind, methanol was chosen as a protic solvent system for the photochemical investigations. In contrast to the azobenzene system, none of the tested substitution patterns resulted in more efficient switching or in significantly prolonged half-lives, showing that the system is dominated by the ring strain.
Folding of RNA molecules into their functional three-dimensional structures is often supported by RNA chaperones, some of which can catalyse the two elementary reactions helix disruption and helix formation. Hfq is one such RNA chaperone, but its strand displacement activity is controversial. Whereas some groups found Hfq to destabilize secondary structures, others did not observe such an activity with their RNA substrates. We studied Hfq’s activities using a set of short RNAs of different thermodynamic stabilities (GC-contents from 4.8% to 61.9%), but constant length. We show that Hfq’s strand displacement as well as its annealing activity are strongly dependent on the substrate’s GC-content. However, this is due to Hfq’s preferred binding of AU-rich sequences and not to the substrate’s thermodynamic stability. Importantly, Hfq catalyses both annealing and strand displacement with comparable rates for different substrates, hinting at RNA strand diffusion and annealing nucleation being rate-limiting for both reactions. Hfq’s strand displacement activity is a result of the thermodynamic destabilization of the RNA through preferred single-strand binding whereas annealing acceleration is independent from Hfq’s thermodynamic influence. Therefore, the two apparently disparate activities annealing acceleration and duplex destabilization are not in energetic conflict with each other.
Studies on the transport of anions and zwitterions of acidic amino acids in Streptomyces hydrogenans
(1983)
n Streptomyces hydrogenans, acidic amino acfds are taken up either as anions by a specific transport system or as zwitterions via a nonspecific one. Variations in the zwitterion concentration caused by changes in pH influence the uptake and exchange diffusion by the nonspecific system. Differences in pH-optima for ʟ-glutamate and ʟ-aspartate transport are due to the different pK2-values of these amino acids. The anion transport by the specific system is accompanied by a short hyperpolarization of the membrane potential followed by a secondary influx of potassium ions into the cells.
Infections with multidrug resistant bacterial strains like Escherichia coli, Klebsiella pneumoniae, Pseudomonas aeruginosa or Acinetobacter baumanii that can accumulate resistance mechanisms against different groups of drugs cause increasing problems for the health care system. Multidrug efflux pumps are able to transport different classes of substances, providing a basic resistance to different antibiotics. Especially when they are overexpressed they can keep bacterial cells alive under antibiotic pressure unless other high level resistance mechanisms like expression of β-lactamases are established. One example for a clinically relevant multidrug efflux pump is the AcrAB/TolC tripartite system of E. coli, that transports a variety of different substrates, including besides antibiotics dyes, detergents, bile salts and organic compounds from the periplasm or the inner membrane out of the cell. AcrB is the inner membrane component of the protein complex that determines not only the substrate specificity of the tripartite system but energises the transport through the whole system process via proton transduction as well. TolC is the outer membrane spanning protein that forms a pore in the outer membrane enabling the system to transport drugs over the latter out of the cell. The periplasmic membrane fusion protein AcrA connects AcrB and TolC in the periplasm completing the channel from the periplasm, respective the inner membrane to the extracellular space. AcrB assembles as trimers, in asymmetric crystal structures each of the protomers adapts a different conformation designated L(oose), T(ight) and O(pen). In the protomers tunnels open up and collaps in different conformations. In the L protomer a periplasmic cleft opens up that can initially bind substrates to the periplasmic part of AcrB. In the T conformation the deep binding pocket opens that is assumed to bind substrates tightly that were bound to the access pocket before. As well in the T conformation a second pathway leading to the deep binding pocket opens that can guide substrates from a groove between transmembrane helices TM7, TM8 and TM9, the TM8 groove, that is connected with socalled tunnel 1 that ends in the deep binding pocket. In the O conformation a new tunnel opens that connects the collapsing deep binding pocket with the periplasmic space, respective the channel through the periplasmic space formed from AcrA and TolC. Substrates were cocrystallised in access and deep binding pocket verifying their role in substrate transport. In the TM8 groove in high resolution crystal structures DDM molecules were cocrystallised in L and T conformation, indicating that the AcrB substrate DDM may utilise this entrance to the deep binding pocket. The asymmetry observed in the AcrB trimers trongly suggests a peristaltic pump mechanism. The functional rotation cycle demands communication between the subunits and tight control of substrate load of protomers during the transport to optimise the ration between protons that are transduced and substrates transported. Indeed it was shown that AcrB transport mechanism is positively cooperative for some β-lactam substrates. For the communication between the subunits it was assumed that ionic interaction between ion pairs established between charged amino acids at the interfaces of protomers in different conformations are of special importance. Thus the amino acids engaged in ionic interactions, respective ion pairs D73-K131, E130-K110, D174-K110, R168, R259-E734 were substituted with non-charged amino acids pairwise and phenotypes were determined in plate dilution assays and MIC experiments. No evidence for a general, substrate independent, reduction of AcrB activity, that would be expected when the ionic residues are of special importance for AcrB function, could be found with the methods applied. Substitutions were not only combined pairwise according to the putative ion pairs but as well in combinations of R168A with D174N, E130Q and K131M. AcrB activity is reduced for the variant R168A_D174N significantly, activity decreases further for quadruple variant E130Q_K131M_ R168A_D174N. Because the reduced activity is only observed in this combination of substitutions the phenotype must result from accumulation of small effects of the single substitutions. R168A may destabilise the protomer interfaces, as its side chain is oriented in direction to the neighbouring protomer at all interfaces, enhancing substratespecific effects of substitutions E130Q, K131M, D174N that are not in all conformations oriented towards the neighbouring protomer but as well along the substrate transport pathway. Further investigations to figure out the details of the effects observed were not conducted because fluctuating expression of the variants hindered experimental procedures.
In another approach TM8 was in focus of the interest. As mentioned above it is a possible substrate entrance in the inner membrane. The linker between TM8 and the periplasmic PC2 subdomain undergoes a coil-to-helix transition when AcrB cycles through L, T and O conformations. Linking the transmembrane part of AcrB that provides the energy for the transport process via proton transduction with the periplasmic part harbouring the major part of the substrate pathway assignes TM8 and the periplasmic linker (859-876) an important role in the function of AcrB. Thus it was investigated with an alanine-scan of residues 859 to 884 and G/P respective P/G exchange followed by phenotype characterisation in growth curve and plate dilution assays of selected variants. In the phenotype determinations none of the variants, except G861P that seems to cause massive sterical restriction in an α-helical region, displayed a general, substrate independent decrease of AcrB activity. Thus it is concluded that the individual properties of amino acids in TM8 and the periplasmic linker are not of general importance for the mechanism of AcrB. The substitution of individual amino acids had impact on uptake of different substrates in plate dilution assays in a substrate dependent manner. The uptake of some substrates, like erythromycin or chloramphenicol is more affected than that of others with rhodamine 6G resistance being only reduced for the G861P variant. A relation between the PSA of substrates and reduced activity of AcrB was observed. in Substrates with higher PSA values are more affected by substitutions in TM8 or periplasmic linker, resulting in the conclusion that substrates with higher PSA are more likely to be taken up via the TM8 groove/tunnel 1 pathway than those with lower PSA values.
The cytochrome bc1 complex is a cornerstone in bioenergetic electron transfer chains, where it carries out tasks as diverse as respiration, photosynthesis, and nitrogen fixation. This homodimeric multisubunit membrane protein has been studied extensively for several decades and the enzyme mechanism is described with the modified protonmotive Q cycle. Still, the molecular and kinetic description of the catalytic cycle is not complete and questions remain regarding the bifurcation of electron transfer at the quinol oxidation (Qo) site, substrate occupancy, pathways of proton conduction, and the nature of the Rieske protein domain movement. We used competitive inhibitors to study the molecular architecture at the Qo site with X-ray crystallography. The structure of the enzyme with the substrate analog 5-n-heptyl-6-hydroxy-4,7-dioxobenzothiazole (HHDBT) bound at the Qo site was determined at 2.5 Å resolution. Spectroscopic studies showed that HHDBT is negatively charged when bound at the active site. Mechanistic interpretations from inhibitor binding are in line with single occupancy model for quinol oxidation and structural analysis supports the proposed proton transfer pathway. For functional insight into the enzyme mechanism, redox-sensitive protonation changes were studied by Fourier transform infrared spectroscopy. The protein purification procedure was optimized for less delipidation and the isolated enzyme was more active. Furthermore, two new phospholipids were identified in the X-ray structures, including a cardiolipin. Strikingly, conserved lipid binding cavities were observed in structural comparison with homologous enzymes. The functional role of tightly bound phospholipids will be discussed. Finally, the Qo site is a target for various compounds of agricultural and pharmaceutical importance. Importantly, the X-ray structures permit detailed analysis of the molecular reasons for acquired resistance to and treatment failure of Qo site inhibitors, such as atovaquone, that is used to treat malaria and pneumonia, as discussed herein.
The P300/CBP-associated factor plays a central role in retroviral infection and cancer development, and the C-terminal bromodomain provides an opportunity for selective targeting. Here, we report several new classes of acetyl-lysine mimetic ligands ranging from mM to low micromolar affinity that were identified using fragment screening approaches. The binding modes of the most attractive fragments were determined using high resolution crystal structures providing chemical starting points and structural models for the development of potent and selective PCAF inhibitors.
We present the rapid biophysical characterization of six previously reported putative G‐quadruplex‐forming RNAs from the 5′‐untranslated region (5′‐UTR) of silvestrol‐sensitive transcripts for investigation of their secondary structures. By NMR and CD spectroscopic analysis, we found that only a single sequence—[AGG]2[CGG]2C—folds into a single well‐defined G‐quadruplex structure. Sequences with longer poly‐G strands form unspecific aggregates, whereas CGG‐repeat‐containing sequences exhibit a temperature‐dependent equilibrium between a hairpin and a G‐quadruplex structure. The applied experimental strategy is fast and provides robust readout for G‐quadruplex‐forming capacities of RNA oligomers.
Ribosome recycling orchestrated by the ATP binding cassette (ABC) protein ABCE1 can be considered as the final—or the first—step within the cyclic process of protein synthesis, connecting translation termination and mRNA surveillance with re-initiation. An ATP-dependent tweezer-like motion of the nucleotide-binding domains in ABCE1 transfers mechanical energy to the ribosome and tears the ribosome subunits apart. The post-recycling complex (PRC) then re-initiates mRNA translation. Here, we probed the so far unknown architecture of the 1-MDa PRC (40S/30S·ABCE1) by chemical cross-linking and mass spectrometry (XL-MS). Our study reveals ABCE1 bound to the translational factor-binding (GTPase) site with multiple cross-link contacts of the helix–loop–helix motif to the S24e ribosomal protein. Cross-linking of the FeS cluster domain to the ribosomal protein S12 substantiates an extreme lever-arm movement of the FeS cluster domain during ribosome recycling. We were thus able to reconstitute and structurally analyse a key complex in the translational cycle, resembling the link between translation initiation and ribosome recycling.
Archaea are motile by the rotation of the archaellum. The archaellum switches between clockwise and counterclockwise rotation, and movement along a chemical gradient is possible by modulation of the switching frequency. This modulation involves the response regulator CheY and the archaellum adaptor protein CheF. In this study, two new crystal forms and protein structures of CheY are reported. In both crystal forms, CheY is arranged in a domain-swapped conformation. CheF, the protein bridging the chemotaxis signal transduction system and the motility apparatus, was recombinantly expressed, purified and subjected to X-ray data collection.
With only a 2.6 Å resolution laboratory powder diffraction pattern of the θ phase of Pigment Yellow 181 (P.Y. 181) available, crystal-structure solution and Rietveld refinement proved challenging; especially when the crystal structure was shown to be a triclinic dimethylsulfoxide N-methyl-2-pyrrolidone (1:1:1) solvate. The crystal structure, which in principle has 28 possible degrees of freedom, was determined in three stages by a combination of simulated annealing, partial Rietveld refinement with dummy atoms replacing the solvent molecules and further simulated annealing. The θ phase not being of commercial interest, additional experiments were not economically feasible and additional dispersion-corrected density functional theory (DFT-D) calculations were employed to confirm the correctness of the crystal structure. After the correctness of the structure had been ascertained, the bond lengths and valence angles from the DFT-D minimized crystal structure were fed back into the Rietveld refinement as geometrical restraints (‘polymorph-dependent restraints’) to further improve the details of the crystal structure; the positions of the H atoms were also taken from the DFT-D calculations. The final crystal structure is a layered structure with an elaborate network of hydrogen bonds.
β-barrel proteins mediate nutrient uptake in bacteria and serve vital functions in cell signaling and adhesion. For the 14-strand outer membrane protein G of Escherichia coli, opening and closing is pH-dependent. Different roles of the extracellular loops in this process were proposed, and X-ray and solution NMR studies were divergent. Here, we report the structure of outer membrane protein G investigated in bilayers of E. coli lipid extracts by magic-angle-spinning NMR. In total, 1847 inter-residue 1H–1H and 13C–13C distance restraints, 256 torsion angles, but no hydrogen bond restraints are used to calculate the structure. The length of β-strands is found to vary beyond the membrane boundary, with strands 6–8 being the longest and the extracellular loops 3 and 4 well ordered. The site of barrel closure at strands 1 and 14 is more disordered than most remaining strands, with the flexibility decreasing toward loops 3 and 4. Loop 4 presents a well-defined helix.
Highlights
• Cryo-EM structure of a yeast F1Fo-ATP synthase dimer
• Inhibitor-free X-ray structure of the F1 head and rotor complex
• Mechanism of ATP generation by rotary catalysis
• Structural basis of cristae formation in the inner mitochondrial membrane
Summary
We determined the structure of a complete, dimeric F1Fo-ATP synthase from yeast Yarrowia lipolytica mitochondria by a combination of cryo-EM and X-ray crystallography. The final structure resolves 58 of the 60 dimer subunits. Horizontal helices of subunit a in Fo wrap around the c-ring rotor, and a total of six vertical helices assigned to subunits a, b, f, i, and 8 span the membrane. Subunit 8 (A6L in human) is an evolutionary derivative of the bacterial b subunit. On the lumenal membrane surface, subunit f establishes direct contact between the two monomers. Comparison with a cryo-EM map of the F1Fo monomer identifies subunits e and g at the lateral dimer interface. They do not form dimer contacts but enable dimer formation by inducing.
Rhodopsins are the most universal biological light-energy transducers and abundant phototrophic mechanisms that evolved on Earth and have a remarkable diversity and potential for biotechnological applications. Recently, the first sodium-pumping rhodopsin KR2 from Krokinobacter eikastus was discovered and characterized. However, the existing structures of KR2 are contradictory, and the mechanism of Na+ pumping is not yet understood. Here, we present a structure of the cationic (non H+) light-driven pump at physiological pH in its pentameric form. We also present 13 atomic structures and functional data on the KR2 and its mutants, including potassium pumps, which show that oligomerization of the microbial rhodopsin is obligatory for its biological function. The studies reveal the structure of KR2 at nonphysiological low pH where it acts as a proton pump. The structure provides new insights into the mechanisms of microbial rhodopsins and opens the way to a rational design of novel cation pumps for optogenetics.
Riboswitches are an important class of regulatory RNA elements that respond to cellular metabolite concentrations to regulate gene expression in a highly selective manner. 2’-deoxyguanosine-sensing (2’dG) riboswitches represent a unique riboswitch subclass only found in the bacterium Mesoplasma florum and are closely related to adenine- and guanine-sensing riboswitches. The I-A type 2’dG-sensing riboswitch represses the expression of ribonucleotide reductase genes at high cellular concentrations of 2’dG as a result of premature transcription termination.
Increasing evidence within the last decade suggests that transcriptional regulation by riboswitches is controlled kinetically and emphasizes the importance of co-transcriptional folding.2–4 Addition of single nucleotides to nascent transcripts causes a continuous shift in structural equilibrium, where refolding rates are competing with the rate of transcription.5,6
For transcriptional riboswitches, both ligand binding and structural rearrangements within the expression platform are precisely coordinated in time with the rate of transcription. The current thesis investigates the mechanistic details of transcriptional riboswitch regulation using the I-A 2’dG-sensing riboswitch as an example for a riboswitch that acts under kinetic control.
Channelrhodopsin-2 (ChR2) is a light-gated cation selective channel from the unicellular alga Chlamydomonas reinhardtii, which is involved in phototaxis and photophobic responses. As other rhodopsins, ChR2 comprises a seven-transmembrane helix (TMH) motif and a retinal as the light-sensitive chromophore. The chromophore is covalently attached via a protonated Schiff base to the conserved lysine residue Lys257 located in TMH7. Based on its primary sequence and the all-trans configuration of the retinal in the ground state, ChR2 is assigned to the type I rhodopsins, also referred to as microbial-type rhodopsins. Upon light activation, the retinal isomerizes from the all-trans to the 13-cis form. This photoisomerization, which is accompanied by conformational changes of the protein, eventually leads to the opening of the channel and cation translocation. Cation flux during the conductive state leads to depolarization of the cell membrane and subsequent triggering of action potentials when expressed in neurons. Therefore, ChR2 has become the most versatile optogenetic tool, enabling a non-invasive investigation of neural circuits at high spatial and temporal resolution. With the rapidly increasing importance of ChR2 as a tool in neurobiology and cell biology, structural information is the prerequisite to an unambiguous understanding of the molecular mechanisms of this unique light-activated ion channel. The coupling between isomerization and structural alterations is well understood for other microbial-type rhodopsins, like bacteriorhodopsin (bR), halorhodopsin (HR) and sensory rhodopsin II (SRII). In case of ChR2, the first data on light-induced conformational changes came from spectroscopic studies and structural information is still missing. However, in order to fully understand the mechanism of light transduction by ChR2, it is necessary to determine the changes in the protein structure at specific steps in the photocycle.
By the time I started my PhD thesis, there was no structural information of ChR2 available. Therefore, the objective of this thesis was to obtain structural information of the transmembrane domain containing the first 315 amino acids of ChR2 by cryo electron crystallography. Besides revealing the structure of membrane proteins, cryo-EM of two-dimensional (2D) crystals is ideal for investigating conformational changes in membrane proteins induced by different stimuli. Therefore, the second objective of my thesis was the investigation of light-induced conformational changes in the slow C128T ChR2 mutant. The ~1,000 times longer lifetime of the open state of the C128T mutant compared to the wild-type allowed to trap different intermediates that accumulate during the photocycle.
In 2012, the X-ray structure of a channelrhodopsin-1/channelrhodopsin-2 chimaera (C1C2) at 2.3 Å resolution in the closed dark-adapted state was published (Kato et al., 2012). The structure revealed the essential molecular architecture of C1C2, including the retinal-binding pocket and the putative cation conduction pathway. Together with biochemical, spectroscopic, mutagenesis experiments, and the high-resolution model, some functionally important residues of ChR2 have been identified. However, unambiguous explanation of the molecular determinants that contribute to activation (gating) and transport were still mostly unknown.
RESULTS AND CONCLUSIONS
The first half of my theses dealt with 2D crystallization of ChR2. I succeeded in obtaining 2D crystals of ChR2 of four different types, which differed in size, crystal packing, crystal contacts and resolution, yielding structure factors up to 6 Å resolution. The crystals were grown by reconstituting the protein with different lipids at various lipid-to-protein ratios. The best crystals formed with the synthetic lipid DMPC and EPL upon detergent removal by dialysis. The projection maps calculated from these crystals revealed the overall structure of C128T ChR2 at 6 Å resolution and were published in 2011 (Müller et al., 2011). Surprisingly, ChR2 was found to be a dimer in all crystal types. The ChR2 dimer was stable both in detergent solution and in the presence of lipids for 2D crystallization. The monomers clearly showed the expected densities for the seven TMHs.
The arrangement of the ChR2 dimers on the four 2D lattices was different. However, comparison of the individual rojection maps revealed no significant differences within the ChR2 interface in the four crystal forms. The observation that the structure of the dimer was the same in all four crystal forms and in different lipids suggested strong specific contacts between the two protomers and implied that the protein was also dimeric in the native membrane. These findings were in agreement with Western blot analysis of plasma membranes from oocytes expressing ChR2 and laser-induced liquid bead ion desorption mass spectrometry, which both showed ChR2 as a dimer. The unusual stability of the ChR2 dimer contrasts with other microbial rhodopsins, which exist in different oligomeric states, i.e. monomers, trimers or dimers. These observations raised the question whether the functional unit is the monomer or the dimer.
The comparison of the projection map of the light-driven proton pump bR at the same resolution showed similar overall dimensions. Based on this comparison, the densities which became evident in the ChR2 projection maps could be assigned to the corresponding seven densities in bR. The shape of the densities near the dimer interface suggested that TMHs 2, 3, and 4 are oriented more or less perpendicular to the membrane plane, while the other four helices appear to be more tilted, as in bR.
Based on the high-resolution bR structure and the projection structures obtained, I have built a homology model. On the basis of this homology model, several residues found in the dimer interface were selected for mutational studies in order to disrupt the dimer interface.
The investigation of light-induced conformational changes in C128T ChR2 was the second part of my thesis. I designed an experimental setup for trapping light-induced conformational changes in C128T ChR2. In addition, I optimized the sample preparation in a way that the different illumination conditions did not alter the quality of the crystals. I have trapped two different functional states, namely the conductive open state and the non-conductive closed dark-adapted state.
In order to visualize the location and the extent of conformational changes, projection difference maps were calculated between the open and the closed state. Visual inspection of the difference maps between the open and the two closed states revealed three difference peaks that map to the TMHs 2, 6, and 7, indicating significant and specific rearrangements of these helices. The strong pair of positive/negative peaks at TMH6 suggests an outward tilt movement of approximately 2 Å. Close comparison of similar work on bR revealed that this movement is likely to occur at the cytoplasmic end of TMH6. A second highly significant negative peak is observed at TMH7, indicating a less pronounced tilt compared to TMH6. The third negative peak at TMH2 indicates a loss of density in this region. No significant differences were recorded at the TMH1, 5 and at the dimer interface formed by TMH3 and 4.
I succeeded in trapping and characterizing the open and closed state in the photocycle of ChR2 and could demonstrate that the transition from the closed to the open state is linked to significant light-induced tilt movements of TMH6 and 7, plus a loss of order in TMH2. These conformational changes are likely to create a large water-filled conducting pore, which seems to be required for the conductance of up to 2,000 ions per photocycle. The previously mentioned spectroscopic studies support the difference structures I obtained. This approach sets the stage for studying structural changes accompanying the formation and decay of other photocycle intermediates in ChR2. Future studies will aim at three-dimensional maps of the open and closed state at higher resolution.
The mfl-riboswitch regulates expression of ribonucleotide reductase subunit in Mesoplasma florum by binding to 2´-deoxyguanosine and thereby promoting transcription termination. We characterized the structure of the ligand-bound aptamer domain by NMR spectroscopy and compared the mfl-aptamer to the aptamer domain of the closely related purine-sensing riboswitches. We show that the mfl-aptamer accommodates the extra 2´-deoxyribose unit of the ligand by forming a more relaxed binding pocket than these found in the purine-sensing riboswitches. Tertiary structures of the xpt-aptamer bound to guanine and of the mfl-aptamer bound to 2´-deoxyguanosine exhibit very similar features, although the sequence of the mfl-aptamer contains several alterations compared to the purine-aptamer consensus sequence. These alterations include the truncation of a hairpin loop which is crucial for complex formation in all purine-sensing riboswitches characterized to date. We further defined structural features and ligand binding requirements of the free mfl-aptamer and found that the presence of Mg2+ is not essential for complex formation, but facilitates ligand binding by promoting pre-organization of key structural motifs in the free aptamer.
Large amplitude intramolecular motions in non-rigid molecules are a fundamental issue in chemistry and biology. The conventional approaches for study these motions by far-infrared and microwave spectroscopy are not applicable when the molecule is non-polar. Therefore, in the current thesis an alternative approach for the investigation of large amplitude intramolecular motions was developed and tested. This new method is based on femtosecond rotational degenerate four-wave mixing spectroscopy (fs DFWM), which is a particular implementation of rotational coherence spectroscopy. The method was successfully applied for the investigation of pseudorotation in pyrrolidine and the ring-puckering vibration in cyclopentene. Another important subject is the photophysics of molecules and molecular clusters which have an ultrashort lifetime of their electronically excited state (photoreactivity). These ultrashort lifetimes often represent a protective mechanism causing photostability. The photoreactivity is usually the manifestation either of an “elementary” reaction, such as proton or electron transfer, which occurs in the excited state or of a fast non-radiative deactivation processes, such as internal conversion via conical intersection of the electronically excited and ground state. Due to a short-lived excited state, the conventional vibrational spectroscopic methods, such as IR depletion detected by resonance two-photon ionization spectroscopy (IR/R2PI), are not applicable for the structural investigation of these systems. Therefore, new approach, termed IR depletion detected by multiphoton ionization with femtosecond laser pulses (IR/fsMPI), was developed for studying the structure of photoreactive microsolvated molecules. The IR/fsMPI technique was applied for investigating the clusters of 1H-pyrrolo[3,2-h]quinoline with water/methanol as well as adenine- and 9-methyl-adenine-hydrates. In addition, the excited state dynamics of bifunctional azaaromatic molecule 7-(2'-pyridyl)indole (7PyIn) was studied by femtosecond pump-probe resonance excitation multiphoton ionization technique (fs REMPI). Under electronic excitation of this molecule a fast proton transfer (phototautomerization) takes place, which is followed by radiationless excited state deactivation process. The fs REMPI spectra lead to the conclusion that the phototautomerization in 7PyIn is coupled with a twisting of the molecule, and that the twisting provides an efficient channel for ultrafast radiationless excited state deactivation. This pattern of excited-state tautomerization/deactivation might be quite general.
The transporter associated with antigen processing (TAP) selectively translocates antigenic peptides into the endoplasmic reticulum. Loading onto major histocompatibility complex class I molecules and proofreading of these bound epitopes are orchestrated within the macromolecular peptide-loading complex, which assembles on TAP. This heterodimeric ABC-binding cassette (ABC) transport complex is therefore a major component in the adaptive immune response against virally or malignantly transformed cells. Its pivotal role predestines TAP as a target for infectious diseases and malignant disorders. The development of therapies or drugs therefore requires a detailed comprehension of structure and function of this ABC transporter, but our knowledge about various aspects is still insufficient. This review highlights recent achievements on the structure and dynamics of antigenic peptides in complex with TAP. Understanding the binding mode of antigenic peptides in the TAP complex will crucially impact rational design of inhibitors, drug development, or vaccination strategies.
In every established species, protein-protein interactions have evolved such that they are fit for purpose. However, the molecular details of the evolution of new protein-protein interactions are poorly understood. We have used nuclear magnetic resonance spectroscopy to investigate the changes in structure and dynamics during the evolution of a protein-protein interaction involving the intrinsically disordered CREBBP (CREB-binding protein) interaction domain (CID) and nuclear coactivator binding domain (NCBD) from the transcriptional coregulators NCOA (nuclear receptor coactivator) and CREBBP/p300, respectively. The most ancient low-affinity “Cambrian-like” [540 to 600 million years (Ma) ago] CID/NCBD complex contained less secondary structure and was more dynamic than the complexes from an evolutionarily younger “Ordovician-Silurian” fish ancestor (ca. 440 Ma ago) and extant human. The most ancient Cambrian-like CID/NCBD complex lacked one helix and several interdomain interactions, resulting in a larger solvent-accessible surface area. Furthermore, the most ancient complex had a high degree of millisecond-to-microsecond dynamics distributed along the entire sequences of both CID and NCBD. These motions were reduced in the Ordovician-Silurian CID/NCBD complex and further redistributed in the extant human CID/NCBD complex. Isothermal calorimetry experiments show that complex formation is enthalpically favorable and that affinity is modulated by a largely unfavorable entropic contribution to binding. Our data demonstrate how changes in structure and motion conspire to shape affinity during the evolution of a protein-protein complex and provide direct evidence for the role of structural, dynamic, and frustrational plasticity in the evolution of interactions between intrinsically disordered proteins.