Development of serial X-ray fluorescence holography for radiation-sensitive protein crystals.

X-ray fluorescence holography (XFH) is a powerful atomic resolution technique capable of directly imaging the local atomic structure around atoms of a target element within a material. Although it is theoretically possible to use XFH to study the local structures of metal clusters in large protein crystals, the experiment has proven difficult to perform, especially on radiation-sensitive proteins. Here, the development of serial X-ray fluorescence holography to allow the direct recording of hologram patterns before the onset of radiation damage is reported. By combining a 2D hybrid detector and the serial data collection used in serial protein crystallography, the X-ray fluorescence hologram can be directly recorded in a fraction of the measurement time needed for conventional XFH measurements. This approach was demonstrated by obtaining the Mn Kα hologram pattern from the protein crystal Photosystem II without any X-ray-induced reduction of the Mn clusters. Furthermore, a method to interpret the fluorescence patterns as real-space projections of the atoms surrounding the Mn emitters has been developed, where the surrounding atoms produce large dark dips along the emitter-scatterer bond directions. This new technique paves the way for future experiments on protein crystals that aim to clarify the local atomic structures of their functional metal clusters, and for other related XFH experiments such as valence-selective XFH or time-resolved XFH.

Tracking the Structural Development of Amyloid Precursors in the Insulin B Chain and the Inhibition Effect by Fibrinogen.

Amyloid fibrils are abnormal protein aggregates associated with several amyloidoses and neurodegenerative diseases. Prefibrillar intermediates, which emerge before amyloid fibril formation, play an important role in structure formation. Therefore, to prevent fibril formation, the mechanisms underpinning the structural development of prefibrillar intermediates must be elucidated. An insulin-derived peptide, the insulin B chain, is known for its stable accumulation of prefibrillar intermediates. In this study, the structural development of B chain prefibrillar intermediates and their inhibition by fibrinogen (Fg) were monitored by transmission electron microscopy (TEM) and small-angle X-ray scattering (SAXS) combined with solid-state nuclear magnetic resonance spectroscopy (NMR) and size exclusion chromatography. TEM images obtained in a time-lapse manner demonstrated that prefibrillar intermediates were wavy rod-like structures emerging from initial non-rod-like aggregates, and their bundling was responsible for protofilament formation. Time-resolved SAXS revealed that the prefibrillar intermediates became thicker and longer as a function of time. Solid-state NMR measurement suggested a ß-sheet formation around Ala14 residue was crucial for the structural conversion from prefibrillar intermediates to amyloid fibril. These observations suggested that prefibrillar intermediates serve as reaction fields for amyloid nucleation and its structural propagation. Time-resolved SAXS also demonstrated that Fg prevented elongation of the prefibrillar intermediates by forming specific complexes together, which implied that regulation of the length of prefibrillar intermediates upon Fg binding was the factor suppressing the prefibrillar intermediate elongation. The fibril formation mechanism and the inhibition strategy found in this study will be helpful in seeking appropriate methods against amyloid-related diseases.

X-ray fluorescence holography of biological metal sites: Application to myoglobin.

X-ray fluorescence holography (XFH) is a relatively new technique capable of providing unique three-dimensional structural information around specific atoms that act as a light source in crystalline samples. So far, XFH has typically been applied to inorganic materials such as dopants in metals and semiconductors. Here, we investigate the possibility of using XFH to visualize the metal active site in sperm whale myoglobin (Mb), a monomeric oxygen storage heme protein. We demonstrate that the atomic images reconstructed from the hologram data of crystals of carbonmonoxy myoglobin (MbCO) are moderately consistent with the crystal structure, which is also determined in this study by X-ray crystallography in the near-atomic resolution, as well as simulation results. These results open up a new avenue for the application of XFH to local atomic and electronic structure imaging of metal-sites in biomolecules.

Heme-bound tyrosine vibrations in hemoglobin M: Resonance Raman, crystallography, and DFT calculation.

Hemoglobins M (Hbs M) are human hemoglobin variants in which either the α or ß subunit contains a ferric heme in the α2ß2 tetramer. Though the ferric subunit cannot bind O2, it regulates O2 affinity of its counterpart ferrous subunit. We have investigated resonance Raman spectra of two Hbs, M Iwate (α87His → tyrosine [Tyr]) and M Boston (α58His → Tyr), having tyrosine as a heme axial ligand at proximal and distal positions, respectively, that exhibit unassigned resonance Raman bands arising from ferric (not ferrous) hemes at 899 and 876 cm-1. Our quantum chemical calculations using density functional theory on Fe-porphyrin models with p-cresol and/or 4-methylimidazole showed that the unassigned bands correspond to the breathing-like modes of Fe3+-bound Tyr and are sensitive to the Fe-O-C(Tyr) angle. Based on the frequencies of the Raman bands, the Fe-O-C(Tyr) angles of Hbs M Iwate and M Boston were predicted to be 153.5° and 129.2°, respectively. Consistent with this prediction, x-ray crystallographic analysis showed that the Fe-O-C(Tyr) angles of Hbs M Iwate and M Boston in the T quaternary structure were 153.6° and 134.6°, respectively. It also showed a similar Fe-O bond length (1.96 and 1.97 Å) and different tilting angles.

Fast in-vitro screening of FLT3-ITD inhibitors using silkworm-baculovirus protein expression system.

We report expression and purification of a FLT3 protein with ITD mutation (FLT3-ITD) with a steady tyrosine kinase activity using a silkworm-baculovirus system, and its application as a fast screening system of tyrosine kinase inhibitors. The FLT3-ITD protein was expressed in Bombyx mori L. pupae infected by gene-modified nucleopolyhedrovirus, and was purified as an active state. We performed an inhibition assay using 17 kinase inhibitors, and succeeded in screening two inhibitors for FLT3-ITD. The result has paved the way for screening FLT3-ITD inhibitors in a fast and easy manner, and also for structural studies.

Freezable and Unfreezable Hydration Water: Distinct Contributions to Protein Dynamics Revealed by Neutron Scattering.

Hydration water plays a crucial role for activating the protein dynamics required for functional expression. Yet, the details are not understood about how hydration water couples with protein dynamics. A temperature hysteresis of the ice formation of hydration water is a key phenomenon to understand which type of hydration water, unfreezable or freezable hydration water, is crucial for the activation of protein dynamics. Using neutron scattering, we observed a temperature-hysteresis phenomenon in the diffraction peaks of the ice of freezable hydration water, whereas protein dynamics did not show any temperature hysteresis. These results show that the protein dynamics is not coupled with freezable hydration water dynamics, and unfreezable hydration water is essential for the activation of protein dynamics. Decoupling of the dynamics between unfreezable and freezable hydration water could be the cause of the distinct contributions of hydration water to protein dynamics.

Direct observation of ligand migration within human hemoglobin at work.

Hemoglobin is one of the best-characterized proteins with respect to structure and function, but the internal ligand diffusion pathways remain obscure and controversial. Here we captured the CO migration processes in the tense (T), relaxed (R), and second relaxed (R2) quaternary structures of human hemoglobin by crystallography using a high-repetition pulsed laser technique at cryogenic temperatures. We found that in each quaternary structure, the photodissociated CO molecules migrate along distinct pathways in the α and ß subunits by hopping between the internal cavities with correlated side chain motions of large nonpolar residues, such as α14Trp(A12), α105Leu(G12), ß15Trp(A12), and ß71Phe(E15). We also observe electron density evidence for the distal histidine [α58/ß63His(E7)] swing-out motion regardless of the quaternary structure, although less evident in α subunits than in ß subunits, suggesting that some CO molecules have escaped directly through the E7 gate. Remarkably, in T-state Fe(II)-Ni(II) hybrid hemoglobins in which either the α or ß subunits contain Ni(II) heme that cannot bind CO, the photodissociated CO molecules not only dock at the cavities in the original Fe(II) subunit, but also escape from the protein matrix and enter the cavities in the adjacent Ni(II) subunit even at 95 K, demonstrating the high gas permeability and porosity of the hemoglobin molecule. Our results provide a comprehensive picture of ligand movements in hemoglobin and highlight the relevance of cavities, nonpolar residues, and distal histidines in facilitating the ligand migration.

Pumping mechanism of NM-R3, a light-driven bacterial chloride importer in the rhodopsin family.

A newly identified microbial rhodopsin, NM-R3, from the marine flavobacterium Nonlabens marinus, was recently shown to drive chloride ion uptake, extending our understanding of the diversity of mechanisms for biological energy conversion. To clarify the mechanism underlying its function, we characterized the crystal structures of NM-R3 in both the dark state and early intermediate photoexcited states produced by laser pulses of different intensities and temperatures. The displacement of chloride ions at five different locations in the model reflected the detailed anion-conduction pathway, and the activity-related key residues-Cys105, Ser60, Gln224, and Phe90-were identified by mutation assays and spectroscopy. Comparisons with other proteins, including a closely related outward sodium ion pump, revealed key motifs and provided structural insights into light-driven ion transport across membranes by the NQ subfamily of rhodopsins. Unexpectedly, the response of the retinal in NM-R3 to photostimulation appears to be substantially different from that seen in bacteriorhodopsin.

Allosteric transitions in hemoglobin revisited.

BACKGROUND: Human hemoglobin is an allosteric protein that exerts exquisite control over ligand binding through large-scale conformational changes. The two-state model without intermediates offers a simple qualitative description of the allosteric behavior of hemoglobin, as presented in textbooks. However, there is renewed interest in this topic due to recent experimental breakthroughs that show how hemoglobin actually undergoes conformational transitions in response to environmental changes. SCOPE OF REVIEW: I review the current understanding of hemoglobin structure-function relationships revealed by recent discoveries. A unique single crystal, in which three protein molecules are allowed to express a whole range of quaternary structures, helped to reveal the detailed transition pathway including various intermediate forms. I also discuss the potential of single-molecule techniques that are currently under examination. MAJOR CONCLUSIONS: New crystallographic approaches reveal that the hemoglobin allosteric transition involves population shifts in multiple quaternary conformers rather than a simple two-state switch, and that coexisting individual conformers may have disproportionate effects on the apparent O2 affinity of hemoglobin. GENERAL SIGNIFICANCE: These approaches provide a further level of complexity on the textbook statement of hemoglobin allostery, highlighting the relevance of conformational distributions in controlling the function and regulation of allosteric proteins.

Saturated Fatty Acids Undergo Intracellular Crystallization and Activate the NLRP3 Inflammasome in Macrophages.

OBJECTIVE: Inflammation provoked by the imbalance of fatty acid composition, such as excess saturated fatty acids (SFAs), is implicated in the development of metabolic diseases. Recent investigations suggest the possible role of the NLRP3 (nucleotide-binding oligomerization domain, leucine-rich repeat and pyrin domain containing 3) inflammasome, which regulates IL-1ß (interleukin 1ß) release and leads to inflammation, in this process. Therefore, we investigated the underlying mechanism by which SFAs trigger NLRP3 inflammasome activation. APPROACH AND RESULTS: The treatment with SFAs, such as palmitic acid and stearic acid, promoted IL-1ß release in murine primary macrophages while treatment with oleic acid inhibited SFA-induced IL-1ß release in a dose-dependent manner. Analyses using polarized light microscopy revealed that intracellular crystallization was provoked in SFA-treated macrophages. As well as IL-1ß release, the intracellular crystallization and lysosomal dysfunction were inhibited in the presence of oleic acid. These results suggest that SFAs activate NLRP3 inflammasome through intracellular crystallization. Indeed, SFA-derived crystals activated NLRP3 inflammasome and subsequent IL-1ß release via lysosomal dysfunction. Excess SFAs also induced crystallization and IL-1ß release in vivo. Furthermore, SFA-derived crystals provoked acute inflammation, which was impaired in IL-1ß-deficient mice. CONCLUSIONS: These findings demonstrate that excess SFAs cause intracellular crystallization and subsequent lysosomal dysfunction, leading to the activation of the NLRP3 inflammasome, and provide novel insights into the pathogenesis of metabolic diseases.

Direct observation of conformational population shifts in crystalline human hemoglobin.

Although X-ray crystallography is the most commonly used technique for studying the molecular structure of proteins, it is not generally able to monitor the dynamic changes or global domain motions that often underlie allostery. These motions often prevent crystal growth or reduce crystal order. We have recently discovered a crystal form of human hemoglobin that contains three protein molecules allowed to express a full range of quaternary structures, whereas maintaining strong X-ray diffraction. Here we use this crystal form to investigate the effects of two allosteric effectors, phosphate and bezafibrate, by tracking the structures and functions of the three hemoglobin molecules following the addition of each effector. The X-ray analysis shows that the addition of either phosphate or bezafibrate not only induces conformational changes in a direction from a relaxed-state to a tense-state, but also within relaxed-state populations. The microspectrophotometric O2 equilibrium measurements on the crystals demonstrate that the binding of each effector energetically stabilizes the lowest affinity conformer more strongly than the intermediate affinity one, thereby reducing the O2 affinity of tense-state populations, and that the addition of bezafibrate causes an ∼5-fold decrease in the O2 affinity of relaxed-state populations. These results show that the allosteric pathway of hemoglobin involves shifts of populations rather than a unidirectional conversion of one quaternary structure to another, and that minor conformers of hemoglobin may have a disproportionate effect on the overall O2 affinity.

Ligation-Dependent Picosecond Dynamics in Human Hemoglobin As Revealed by Quasielastic Neutron Scattering.

Hemoglobin, the vital O2 carrier in red blood cells, has long served as a classic example of an allosteric protein. Although high-resolution X-ray structural models are currently available for both the deoxy tense (T) and fully liganded relaxed (R) states of hemoglobin, much less is known about their dynamics, especially on the picosecond to subnanosecond time scales. Here, we investigate the picosecond dynamics of the deoxy and CO forms of human hemoglobin using quasielastic neutron scattering under near physiological conditions in order to extract the dynamics changes upon ligation. From the analysis of the global motions, we found that whereas the apparent diffusion coefficients of the deoxy form can be described by assuming translational and rotational diffusion of a rigid body, those of the CO form need to involve an additional contribution of internal large-scale motions. We also found that the local dynamics in the deoxy and CO forms are very similar in amplitude but are slightly lower in frequency in the former than in the latter. Our results reveal the presence of rapid large-scale motions in hemoglobin and further demonstrate that this internal mobility is governed allosterically by the ligation state of the heme group.

Molecular mechanism of photoactivation of a light-regulated adenylate cyclase.

The photoactivated adenylate cyclase (PAC) from the photosynthetic cyanobacterium Oscillatoria acuminata (OaPAC) detects light through a flavin chromophore within the N-terminal BLUF domain. BLUF domains have been found in a number of different light-activated proteins, but with different relative orientations. The two BLUF domains of OaPAC are found in close contact with each other, forming a coiled coil at their interface. Crystallization does not impede the activity switching of the enzyme, but flash cooling the crystals to cryogenic temperatures prevents the signature spectral changes that occur on photoactivation/deactivation. High-resolution crystallographic analysis of OaPAC in the fully activated state has been achieved by cryocooling the crystals immediately after light exposure. Comparison of the isomorphous light- and dark-state structures shows that the active site undergoes minimal changes, yet enzyme activity may increase up to 50-fold, depending on conditions. The OaPAC models will assist the development of simple, direct means to raise the cyclic AMP levels of living cells by light, and other tools for optogenetics.

Development of an X-ray fluorescence holographic measurement system for protein crystals.

Experimental procedure and setup for obtaining X-ray fluorescence hologram of crystalline metalloprotein samples are described. Human hemoglobin, an α2ß2 tetrameric metalloprotein containing the Fe(II) heme active-site in each chain, was chosen for this study because of its wealth of crystallographic data. A cold gas flow system was introduced to reduce X-ray radiation damage of protein crystals that are usually fragile and susceptible to damage. A χ-stage was installed to rotate the sample while avoiding intersection between the X-ray beam and the sample loop or holder, which is needed for supporting fragile protein crystals. Huge hemoglobin crystals (with a maximum size of 8 × 6 × 3 mm(3)) were prepared and used to keep the footprint of the incident X-ray beam smaller than the sample size during the entire course of the measurement with the incident angle of 0°-70°. Under these experimental and data acquisition conditions, we achieved the first observation of the X-ray fluorescence hologram pattern from the protein crystals with minimal radiation damage, opening up a new and potential method for investigating the stereochemistry of the metal active-sites in biomacromolecules.

Structural insight into photoactivation of an adenylate cyclase from a photosynthetic cyanobacterium.

Cyclic-AMP is one of the most important second messengers, regulating many crucial cellular events in both prokaryotes and eukaryotes, and precise spatial and temporal control of cAMP levels by light shows great promise as a simple means of manipulating and studying numerous cell pathways and processes. The photoactivated adenylate cyclase (PAC) from the photosynthetic cyanobacterium Oscillatoria acuminata (OaPAC) is a small homodimer eminently suitable for this task, requiring only a simple flavin chromophore within a blue light using flavin (BLUF) domain. These domains, one of the most studied types of biological photoreceptor, respond to blue light and either regulate the activity of an attached enzyme domain or change its affinity for a repressor protein. BLUF domains were discovered through studies of photo-induced movements of Euglena gracilis, a unicellular flagellate, and gene expression in the purple bacterium Rhodobacter sphaeroides, but the precise details of light activation remain unknown. Here, we describe crystal structures and the light regulation mechanism of the previously undescribed OaPAC, showing a central coiled coil transmits changes from the light-sensing domains to the active sites with minimal structural rearrangement. Site-directed mutants show residues essential for signal transduction over 45 Å across the protein. The use of the protein in living human cells is demonstrated with cAMP-dependent luciferase, showing a rapid and stable response to light over many hours and activation cycles. The structures determined in this study will assist future efforts to create artificial light-regulated control modules as part of a general optogenetic toolkit.

Delineation of solution burst-phase protein folding events by encapsulating the proteins in silica gels.

Many studies have shown that during the early stages of the folding of a protein, chain collapse and secondary structure formation lead to a partially folded intermediate. Thus, direct observation of these early folding events is crucial if we are to understand protein-folding mechanisms. Notably, these events usually manifest as the initial unresolvable signals, denoted the burst phase, when monitored during conventional mixing experiments. However, folding events can be substantially slowed by first trapping a protein within a silica gel with a large water content, in which the trapped native state retains its solution conformation. In this study, we monitored the early folding events involving secondary structure formation of five globular proteins, horse heart cytochrome c, equine ß-lactoglobulin, human tear lipocalin, bovine α-lactalbumin, and hen egg lysozyme, in silica gels containing 80% (w/w) water by CD spectroscopy. The folding rates decreased for each of the proteins, which allowed for direct observation of the initial folding transitions, equivalent to the solution burst phase. The formation of each initial intermediate state exhibited single exponential kinetics and Arrhenius activation energies of 14-31 kJ/mol.

Capturing the hemoglobin allosteric transition in a single crystal form.

Allostery in many oligomeric proteins has been postulated to occur via a ligand-binding-driven conformational transition from the tense (T) to relaxed (R) state, largely on the basis of the knowledge of the structure and function of hemoglobin, the most thoroughly studied of all allosteric proteins. However, a growing body of evidence suggests that hemoglobin possesses a variety of intermediates between the two end states. As such intermediate forms coexist with the end states in dynamic equilibrium and cannot be individually characterized by conventional techniques, very little is known about their properties and functions. Here we present complete structural and functional snapshots of nine equilibrium conformers of human hemoglobin in the half-liganded and fully liganded states by using a novel combination of X-ray diffraction analysis and microspectrophotometric O2 equilibrium measurements on three isomorphous crystals, each capturing three distinct equilibrium conformers. Notably, the conformational set of this crystal form varies according to shifts in the allosteric equilibrium, reflecting the differences in hemoglobin ligation state and crystallization solution conditions. We find that nine snapshot structures cover the complete conformational space of hemoglobin, ranging from T to R2 (the second relaxed quaternary structure) through R, with various relaxed intermediate forms between R and R2. Moreover, we find a previously unidentified intermediate conformer, between T and R, with an intermediate O2 affinity, sought by many research groups over a period of decades. These findings reveal a comprehensive picture of the equilibrium conformers and transition pathway for human hemoglobin.

Intersubunit communication via changes in hemoglobin quaternary structures revealed by time-resolved resonance Raman spectroscopy: direct observation of the Perutz mechanism.

Time-resolved resonance Raman spectroscopy was used to investigate intersubunit communication of hemoglobin using hybrid hemoglobin in which nickel was substituted for the heme iron in the ß subunits. Changes in the resonance Raman spectra of the α heme and the ß Ni-heme groups in the hybrid hemoglobin were observed upon CO photolysis in the α subunit using a probe pulse of 436 and 418 nm, respectively. Temporal evolution of the frequencies of the ν(Fe-His) and the γ7 band of α heme was similar to that of unsubstituted hemoglobin, suggesting that substitution with Ni-heme did not perturb the allosteric dynamics of the hemoglobin. In the ß subunits, no structural change in the Ni-heme was observed until 1 µs. In the microsecond regime, temporal evolution of the frequencies of the ν(Ni-His) and the γ7 band of ß Ni-heme was observed concomitant with an R → T quaternary change at about 20 µs. The changes in the ν(Fe-His) and ν(Ni-His) frequencies of the α and ß subunits with the common time constant of ∼20 µs indicated that the proximal tension imposed on the bond between the heme and the proximal histidine strengthened upon the quaternary changes in both the α and the ß subunits concertedly. This observation is consistent with the Perutz mechanism for allosteric control of oxygen binding in hemoglobin and, thus, is the first real-time observation of the mechanism. Protein dynamics and allostery based on the observed time-resolved spectra also are discussed.

Homopiperazine derivatives as a novel class of proteasome inhibitors with a unique mode of proteasome binding.

The proteasome is a proteolytic machinery that executes the degradation of polyubiquitinated proteins to maintain cellular homeostasis. Proteasome inhibition is a unique and effective way to kill cancer cells because they are sensitive to proteotoxic stress. Indeed, the proteasome inhibitor bortezomib is now indispensable for the treatment of multiple myeloma and other intractable malignancies, but is associated with patient inconvenience due to intravenous injection and emerging drug resistance. To resolve these problems, we attempted to develop orally bioavailable proteasome inhibitors with distinct mechanisms of action and identified homopiperazine derivatives (HPDs) as promising candidates. Biochemical and crystallographic studies revealed that some HPDs inhibit all three catalytic subunits (ß 1, ß 2 and ß 5) of the proteasome by direct binding, whereas bortezomib and other proteasome inhibitors mainly act on the ß5 subunit. Proteasome-inhibitory HPDs exhibited cytotoxic effects on cell lines from various hematological malignancies including myeloma. Furthermore, K-7174, one of the HPDs, was able to inhibit the growth of bortezomib-resistant myeloma cells carrying a ß5-subunit mutation. Finally, K-7174 had additive effects with bortezomib on proteasome inhibition and apoptosis induction in myeloma cells. Taken together, HPDs could be a new class of proteasome inhibitors, which compensate for the weak points of conventional ones and overcome the resistance to bortezomib.

Symmetry distortion in the human hemoglobin tetramer induced by asymmetric ligation.

To investigate the conformational changes in human tetrameric (αß)(2) hemoglobin upon binding of the first two ligands, we have measured the kinetics of reactions between 4,4'-dithiodipyridine and ß93Cys sulfhydryl groups of four diliganded hemoglobins by using CO-bound Fe(II)-Ni(II) hybrids with and without ß-ß cross-linking. The data show that all the diliganded intermediates have high sulfhydryl reactivities, which are greater than or equal to that for the fully-liganded end state, especially when containing liganded α subunit(s). The results also reveal that both the asymmetrically (α1ß1 and α1ß2) diliganded species show similar high rates of sulfhydryl reactivity and biphasic kinetics, suggesting a new conformation but only slight functional distortion caused by asymmetric ligation.