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In the pursuit of potential therapeutic agents for type 2 diabetes, non-amyloidogenic forms of the human Islet Amyloid Polypeptide (hIAPP) containing site-specific mutations are of significant interest. In the present study, we dissect the three proline mutations present in the core region of the non-amyloidogenic rat IAPP into single-point mutations at A25P, S28P, and S29P sites. We apply high-resolution cryo-electron microscopy and solve the structures of 6 polymorphs formed by these mutants, revealing the peptide's self-assembly patterns and identifying critical interactions that reinforce these structures in the presence of the b-sheet breaker. A unique trimeric aggregate with C3 symmetry was identified in the A25P mutant, which we resolved with a 3.05 A resolution, while asymmetric trimeric assemblies were observed in the other mutants. Guided by the high-resolution structural models of A25P and S28P fibrils obtained in our study, we successfully designed novel non-amyloidogenic mutants of IAPP with potential therapeutic value. Our findings demonstrate the immense potential of structure-based approaches in developing effective therapeutics against amyloid diseases. 

Myxobacteria are non-photosynthetic, soil-dwelling bacteria distinguished by a multicellular stage in their life cycle known as fruiting bodies that are stimulated by light. Myxobacterial phytochromes are candidates for the perception of red-light. The mechanism how light is perceived and converted to a physiological response is unknown. Here, time-resolved serial femtosecond crystallographic (TR-SFX) experiments were conducted on microcrystals of the photosensory core module of the Stigmatella aurantiaca bacteriophytochrome 2 (SaBphP2). Initial events of the Z to E isomerization reaction of the covalently bound, open-chain tetrapyrrole biliverdin (BV) chromophore were determined. At 3 ps after light activation, the BV ring-D assumes a configuration needed for the isomerization. At 100 ps, a mixture of BV in the Z or E configuration is observed in subunit A, while in the other subunit the chromophore remains in the Z configuration. In conjunction with prior results, these structures reveal the molecular mechanism of phytochrome activation in the photomorphogenesis of the myxobacteria and provide the molecular foundation for physiological responses to red light in other bacteria.

Solution NMR reveals the structure and dynamics of biomolecules in solution. In particular, the method can detect changes due to perturbation of the molecules, without limiting effects of frozen particles or crystal environments. Phytochromes are photosensors which control the response to red/far-red light in bacteria, fungi and plants, undergo specific structural changes when photoactivated from the Pr to the Pfr state. While structures of phytochromes have been revealed in both states, the structural mechanism of photoconversion remains incompletely understood. Our previous NMR studies of the entire photosensory core module of the D. radiodurans phytochrome have revealed novel structural changes, but the backbone assignment was incomplete. In particular, a lack of the assignment in the protein core hindered more detailed insight in signaling mechanism. Here, we outline an efficient procedure for the refolding of the three-domain, photosensory core fragment of the D. radiodurans phytochrome in its monomeric form. We find that treatment with guanidinium hydrochloride and subsequent dilution effectively refolds the phytochrome, maintaining its functionality. We characterize the refolded protein with solution NMR spectroscopy newly assigning 27 (44) residues in Pr (Pfr), out of which 12 exhibit notable chemical shift perturbation upon photoactivation. The study presents a functional method for purification and refolding of a multidomain protein and opens the door for further structural and dynamic analysis of phytochromes.

In photoactive proteins, coupling between the chromophore and protein matrix is exquisitely tuned. Proton transfer reactions can mediate this coupling, as in proton-coupled electron transfer and excited-state proton transfer. Additional mechanisms involving proton dislocations may exist but remain undiscovered. Here, we present a femtosecond crystallographic movie of the phytochrome from Deinococcus radiodurans. The structures reveal a space-conserving mechanism for rotation of the D-ring in the excited state. We observe rearrangement of a conserved hydrogen bond network within 300 fs, which precedes the isomerization reaction of the chromophore. Aided by molecular modeling and independently confirmed by femtosecond infrared spectroscopy, we attribute these changes to a protonation shift of the strictly conserved histidine-260. Although this histidine lies close to the photoexcited π-orbitals of the chromophore, it is not directly part of them. We propose that this “remote-controlled” proton transfer relays photoexcitation near-instantaneously to the protein matrix. This mechanism may be widely used to transduce cofactor signals to their hosting enzymes.

Phytochromes are photoreceptor proteins in plants, fungi and bacteria. They can adopt two photochromic states with differential biochemical responses. The structural changes transducing the signal from the chromophore to the biochemical output modules are poorly understood due to challenges in capturing structures of the dynamic, full-length protein. Here, we present cryo-electron microscopy structures of the phytochrome from Pseudomonas aeruginosa (PaBphP) in its resting Pfr and photoactivated Pr state. The kinase-active Pr state has an asymmetric, dimeric structure, whereas the kinase-inactive Pfr state opens up. This behaviour is different from other known phytochromes and we explain it with the unusually short connection between the photosensory and output modules. Multiple sequence alignment of this region suggests evolutionary optimisation for different modes of signal transduction in sensor proteins. The results establish a new mechanism for light-sensing by phytochrome histidine kinases and provide input for the design of optogenetic phytochrome variants.

Charge-transfer reactions in proteins are important for life, such as in photolyases which repair DNA, but the role of structural dynamics remains unclear. Here, using femtosecond X-ray crystallography, we report the structural changes that take place while electrons transfer along a chain of four conserved tryptophans in the Drosophila melanogaster (6-4) photolyase. At femto- and picosecond delays, photoreduction of the flavin by the first tryptophan causes directed structural responses at a key asparagine, at a conserved salt bridge, and by rearrangements of nearby water molecules. We detect charge-induced structural changes close to the second tryptophan from 1 ps to 20 ps, identifying a nearby methionine as an active participant in the redox chain, and from 20 ps around the fourth tryptophan. The photolyase undergoes highly directed and carefully timed adaptations of its structure. This questions the validity of the linear solvent response approximation in Marcus theory and indicates that evolution has optimized fast protein fluctuations for optimal charge transfer.

Detecting microsecond structural perturbations in biomolecules has wide relevance inbiology, chemistry, and medicine. Here, we show how MHz repetition rates at X-ray freeelectron lasers (XFELs) can be used to produce microsecond time-series of proteinscattering with exceptionally low noise levels of 0.001%. We demonstrate the approach byderiving new mechanistic insight into Jɑ helix unfolding of a Light-Oxygen-Voltage (LOV)photosensory domain. This time-resolved acquisition strategy is easy to implement andwidely applicable for direct observation of structural dynamics of many biochemicalprocesses. 

X-ray free-electron lasers (XFELs) can probe chemical and biological reactions as they unfold with unprecedented spatial and temporal resolution. A principal challenge in this pursuit involves the delivery of samples to the X-ray interaction point in such a way that produces data of the highest possible quality and with maximal efficiency. This is hampered by intrinsic constraints posed by the light source and operation within a beamline environment. For liquid samples, the solution typically involves some form of high-speed liquid jet, capable of keeping up with the rate of X-ray pulses. However, conventional jets are not ideal because of radiation-induced explosions of the jet, as well as their cylindrical geometry combined with the X-ray pointing instability of many beamlines which causes the interaction volume to differ for every pulse. This complicates data analysis and contributes to measurement errors. An alternative geometry is a liquid sheet jet which, with its constant thickness over large areas, eliminates the problems related to X-ray pointing. Since liquid sheets can be made very thin, the radiation-induced explosion is reduced, boosting their stability. These are especially attractive for experiments which benefit from small interaction volumes such as fluctuation X-ray scattering and several types of spectroscopy. Although their use has increased for soft X-ray applications in recent years, there has not yet been wide-scale adoption at XFELs. Here, gas-accelerated liquid sheet jet sample injection is demonstrated at the European XFEL SPB/SFX nano focus beamline. Its performance relative to a conventional liquid jet is evaluated and superior performance across several key factors has been found. This includes a thickness profile ranging from hundreds of nanometres to 60 nm, a fourfold increase in background stability and favorable radiation-induced explosion dynamics at high repetition rates up to 1.13 MHz. Its minute thickness also suggests that ultrafast single-particle solution scattering is a possibility.

Phytochromes belong to a group of photoreceptor proteins containing a covalently bound biliverdin chromophore that inter-converts between two isomeric forms upon photoexcitation. The existence and stability of the photocycle products are largely determined by the protein sequence and the presence of conserved hydrogen-bonding interactions in the vicinity of the chromophore. The vibrational signatures of biliverdin, however, are often weak and obscured under more intense protein bands, limiting spectroscopic studies of its non-transient signals. In this study, we apply isotope-labeling techniques to isolate the vibrational bands from the protein-bound chromophore of the bacterial phytochrome from Deinococcus radiodurans. We elucidate the structure and ultrafast dynamics of the chromophore with 2D infra-red (IR) spectroscopy and molecular dynamics simulations. The carbonyl stretch vibrations of the pyrrole rings show the heterogeneous distribution of hydrogen-bonding structures, which exhibit distinct ultrafast relaxation dynamics. Moreover, we resolve a previously undetected 1678 cm(-1) band that is strongly coupled to the A- and D-ring of biliverdin and demonstrate the presence of complex vibrational redistribution pathways between the biliverdin modes with relaxation-assisted measurements of 2D IR cross peaks. In summary, we expect 2D IR spectroscopy to be useful in explaining how point mutations in the protein sequence affect the hydrogen-bonding structure around the chromophore and consequently its ability to photoisomerize to the light-activated states.