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.

Roles of Fe-Histidine bonds in stability of hemoglobin: Recognition of protein flexibility by Q Sepharose.

Using various mutants, we investigated to date the roles of the Fe-histidine (F8) bonds in cooperative O2 binding of human hemoglobin (Hb) and differences in roles between α- and ß-subunits in the α2ß2 tetramer. An Hb variant with a mutation in the heme cavity exhibited an unexpected feature. When the ß mutant rHb (ßH92G), in which the proximal histidine (His F8) of the ß-subunit is replaced by glycine (Gly), was subjected to ion-exchange chromatography (Q Sepharose column) and eluted with an NaCl concentration gradient in the presence of imidazole, yielded two large peaks, whereas the corresponding α-mutant, rHb (αH87G), gave a single peak similar to Hb A. The ß-mutant rHb proteins under each peak had identical isoelectric points according to isoelectric focusing electrophoresis. Proteins under each peak were further characterized by Sephadex G-75 gel filtration, far-UV CD, 1H NMR, and resonance Raman spectroscopy. We found that rHb (ßH92G) exists as a mixture of αß-dimers and α2ß2 tetramers, and that hemes are released from ß-subunits in a fraction of the dimers. An approximate amount of released hemes were estimated to be as large as 30% with Raman relative intensities. It is stressed that Q Sepharose columns can distinguish differences in structural flexibility of proteins having identical isoelectric points by altering the exit rates from the porous beads. Thus, the role of Fe-His (F8) bonds in stabilizing the Hb tetramer first described by Barrick et al. was confirmed in this study. In addition, it was found in this study that a specific Fe-His bond in the ß-subunit minimizes globin structural flexibility.

Interrelationship among Fe-His Bond Strengths, Oxygen Affinities, and Intersubunit Hydrogen Bonding Changes upon Ligand Binding in the ß Subunit of Human Hemoglobin: The Alkaline Bohr Effect.

Regulation of the oxygen affinity of human adult hemoglobin (Hb A) at high pH, known as the alkaline Bohr effect, is essential for its physiological function. In this study, structural mechanisms of the alkaline Bohr effect and pH-dependent O2 affinity changes were investigated via 1H nuclear magnetic resonance and visible and UV resonance Raman spectra of mutant Hbs, Hb M Iwate (αH87Y) and Hb M Boston (αH58Y). It was found that even though the binding of O2 to the α subunits is forbidden in the mutant Hbs, the O2 affinity was higher at alkaline pH than at neutral pH, and concomitantly, the Fe-His stretching frequency of the ß subunits was shifted to higher values. Thus, it was confirmed for the ß subunits that the stronger the Fe-His bond, the higher the O2 affinity. It was found in this study that the quaternary structure of α(Fe3+)ß(Fe2+-CO) of the mutant Hb is closer to T than to the ordinary R at neutral pH. The retained Aspß94-Hisß146 hydrogen bond makes the extent of proton release smaller upon ligand binding from Hisß146, known as one of residues contributing to the alkaline Bohr effect. For these T structures, the Aspα94-Trpß37 hydrogen bond in the hinge region and the Tyrα42-Aspß99 hydrogen bond in the switch region of the α1-ß2 interface are maintained but elongated at alkaline pH. Thus, a decrease in tension in the Fe-His bond of the ß subunits at alkaline pH causes a substantial increase in the change in global structure upon binding of CO to the ß subunit.

Heterogeneity between Two α Subunits of α2ß2 Human Hemoglobin and O2 Binding Properties: Raman, 1H Nuclear Magnetic Resonance, and Terahertz Spectra.

Following a previous detailed investigation of the ß subunit of α2ß2 human adult hemoglobin (Hb A), this study focuses on the α subunit by using three natural valency hybrid α(Fe2+-deoxy/O2)ß(Fe3+) hemoglobin M (Hb M) in which O2 cannot bind to the ß subunit: Hb M Hyde Park (ß92His → Tyr), Hb M Saskatoon (ß63His → Tyr), and Hb M Milwaukee (ß67Val → Glu). In contrast with the ß subunit that exhibited a clear correlation between O2 affinity and Fe2+-His stretching frequencies, the Fe2+-His stretching mode of the α subunit gave two Raman bands only in the T quaternary structure. This means the presence of two tertiary structures in α subunits of the α2ß2 tetramer with T structure, and the two structures seemed to be nondynamical as judged from terahertz absorption spectra in the 5-30 cm-1 region of Hb M Milwaukee, α(Fe2+-deoxy)ß(Fe3+). This kind of heterogeneity of α subunits was noticed in the reported spectra of a metal hybrid Hb A like α(Fe2+-deoxy)ß(Co2+) and, therefore, seems to be universal among α subunits of Hb A. Unexpectedly, the two Fe-His frequencies were hardly changed with a large alteration of O2 affinity by pH change, suggesting no correlation of frequency with O2 affinity for the α subunit. Instead, a new Fe2+-His band corresponding to the R quaternary structure appeared at a higher frequency and was intensified as the O2 affinity increased. The high-frequency counterpart was also observed for a partially O2-bound form, α(Fe2+-deoxy)α(Fe2+-O2)ß(Fe3+)ß(Fe3+), of the present Hb M, consistent with our previous finding that binding of O2 to one α subunit of T structure α2ß2 tetramer changes the other α subunit to the R structure.

Infrared and Raman spectroscopic investigation of the reaction mechanism of cytochrome c oxidase.

Recent progress in studies on the proton-pumping and O2reduction mechanisms of cytochrome c oxidase (CcO) elucidated by infrared (IR) and resonance Raman (rR) spectroscopy, is reviewed. CcO is the terminal enzyme of the respiratory chain and its O2reduction reaction is coupled with H⁺ pumping activity across the inner mitochondrial membrane. The former is catalyzed by heme a3 and its mechanism has been determined using a rR technique, while the latter used the protein moiety and has been investigated with an IR technique. The number of H⁺ relative to e⁻ transferred in the reaction is 1:1, and their coupling is presumably performed by heme a and nearby residues. To perform this function, different parts of the protein need to cooperate with each other spontaneously and sequentially. It is the purpose of this article to describe the structural details on the coupling on the basis of the vibrational spectra of certain specified residues and chromophores involved in the reaction. Recent developments in time-resolved IR and Raman technology concomitant with protein manipulation methods have yielded profound insights into such structural changes. In particular, the new IR techniques that yielded the breakthrough are reviewed and assessed in detail. This article is part of a Special Issue entitled: Vibrational spectroscopies and bioenergetic systems.

Structure and properties of the catalytic site of nitric oxide reductase at ambient temperature.

Nitric oxide reductase (Nor) is the third of the four enzymes of bacterial denitrification responsible for the catalytic formation of laughing gas (N2O). Here we report the detection of the hyponitrite (HO-N=N-O(-)) species (νN-N=1332cm(-1)) in the heme b3 Fe-FeB dinuclear center of Nor from Paracoccus denitrificans. We have also applied density functional theory (DFT) to characterize the bimetallic-bridging hyponitrite species in the reduction of NO to N2O by Nor and compare the present results with those recently reported for the N-N bond formation in the ba3 and caa3 oxidoreductases from Thermus thermophilus.

Heme Orientation of Cavity Mutant Hemoglobins (His F8 → Gly) in Either α or ß Subunits: Circular Dichroism, (1) H NMR, and Resonance Raman Studies.

Native human adult hemoglobin (Hb A) has mostly normal orientation of heme, whereas recombinant Hb A (rHb A) expressed in E. coli contains both normal and reversed orientations of heme. Hb A with the normal heme exhibits positive circular dichroism (CD) bands at both the Soret and 260-nm regions, while rHb A with the reversed heme shows a negative Soret and decreased 260-nm CD bands. In order to examine involvement of the proximal histidine (His F8) of either α or ß subunits in determining the heme orientation, we prepared two cavity mutant Hbs, rHb(αH87G) and rHb(ßH92G), with substitution of glycine for His F8 in the presence of imidazole. CD spectra of both cavity mutant Hbs did not show a negative Soret band, but instead exhibited positive bands with strong intensity at the both Soret and 260-nm regions, suggesting that the reversed heme scarcely exists in the cavity mutant Hbs. We confirmed by (1) H NMR and resonance Raman (RR) spectroscopies that the cavity mutant Hbs have mainly the normal heme orientation in both the mutated and native subunits. These results indicate that the heme Fe-His F8 linkage in both α and ß subunits influences the heme orientation, and that the heme orientation of one type of subunit is related to the heme orientation of the complementary subunits to be the same. The present study showed that CD and RR spectroscopies also provided powerful tools for the examination of the heme rotational disorder of Hb A, in addition to the usual (1) H NMR technique. Chirality 28:585-592, 2016. © 2016 Wiley Periodicals, Inc.

Nitric oxide activation by caa3 oxidoreductase from Thermus thermophilus.

Visible and UV-resonance Raman spectroscopy was employed to investigate the reaction of NO with cytochrome caa3 from Thermus thermophilus. We show the formation of the hyponitrite (HO-N=N-O)(-) bound to the heme a3 species (νN=N = 1330 cm(-1)) forming a high spin complex in the oxidized heme a3 Fe/CuB binuclear center of caa3-oxidoreductase. In the absence of heme a3 Fe(2+)-NO formation, the electron required for the formation of the N=N bond originates from the autoreduction of CuB by NO, producing nitrite. With the identification of the hyponitrite intermediate the hypothesis of a common phylogeny of aerobic respiration and bacterial denitrification is fully supported and the mechanism for the 2e(-)/2H(+) reduction of NO to N2O can be described with more certainty.

The protein effect in the structure of two ferryl-oxo intermediates at the same oxidation level in the heme copper binuclear center of cytochrome c oxidase.

Identification of the intermediates and determination of their structures in the reduction of dioxygen to water by cytochrome c oxidase (CcO) are particularly important to understanding both O2 activation and proton pumping by the enzyme. In this work, we report the products of the rapid reaction of O2 with the mixed valence form (CuA(2+), heme a(3+), heme a3(2+)-CuB(1+)) of the enzyme. The resonance Raman results show the formation of two ferryl-oxo species with characteristic Fe(IV)=O stretching modes at 790 and 804 cm(-1) at the peroxy oxidation level (PM). Density functional theory calculations show that the protein environment of the proximal H-bonded His-411 determines the strength of the distal Fe(IV)=O bond. In contrast to previous proposals, the PM intermediate is also formed in the reaction of Y167F with O2. These results suggest that in the fully reduced enzyme, the proton pumping ν(Fe(IV)=O) = 804 cm(-1) to ν(Fe(IV)=O) = 790 cm(-1) transition (P→F, where P is peroxy and F is ferryl) is triggered not only by electron transfer from heme a to heme a3 but also by the formation of the H-bonded form of the His-411-Fe(IV)=O conformer in the proximal site of heme a3. The implications of these results with respect to the role of an O=Fe(IV)-His-411-H-bonded form to the ring A propionate of heme a3-Asp-399-H2O site and, thus, to the exit/output proton channel (H2O) pool during the proton pumping P→F transition are discussed. We propose that the environment proximal to the heme a3 controls the spectroscopic properties of the ferryl intermediates in cytochrome oxidases.

Site-specific protein dynamics in communication pathway from sensor to signaling domain of oxygen sensor protein, HemAT-Bs: Time-resolved Ultraviolet Resonance Raman Study.

HemAT-Bs is a heme-based signal transducer protein responsible for aerotaxis. Time-resolved ultraviolet resonance Raman (UVRR) studies of wild-type and Y70F mutant of the full-length HemAT-Bs and the truncated sensor domain were performed to determine the site-specific protein dynamics following carbon monoxide (CO) photodissociation. The UVRR spectra indicated two phases of intensity changes for Trp, Tyr, and Phe bands of both full-length and sensor domain proteins. The W16 and W3 Raman bands of Trp, the F8a band of Phe, and the Y8a band of Tyr increased in intensity at hundreds of nanoseconds after CO photodissociation, and this was followed by recovery in ∼50 µs. These changes were assigned to Trp-132 (G-helix), Tyr-70 (B-helix), and Phe-69 (B-helix) and/or Phe-137 (G-helix), suggesting that the change in the heme structure drives the displacement of B- and G-helices. The UVRR difference spectra of the sensor domain displayed a positive peak for amide I in hundreds of nanoseconds after photolysis, which was followed by recovery in ∼50 µs. This difference band was absent in the spectra of the full-length protein, suggesting that the isolated sensor domain undergoes conformational changes of the protein backbone upon CO photolysis and that the changes are restrained by the signaling domain. The time-resolved difference spectrum at 200 µs exhibited a pattern similar to that of the static (reduced - CO) difference spectrum, although the peak intensities were much weaker. Thus, the rearrangements of the protein moiety toward the equilibrium ligand-free structure occur in a time range of hundreds of microseconds.

Near-UV circular dichroism and UV resonance Raman spectra of individual tryptophan residues in human hemoglobin and their changes upon the quaternary structure transition.

The aromatic residues such as tryptophan (Trp) and tyrosine (Tyr) in human adult hemoglobin (Hb A) are known to contribute to near-UV circular dichroism (CD) and UV resonance Raman (RR) spectral changes upon the R → T quaternary structure transition. In Hb A, there are three Trp residues per αß dimer: at α14, ß15, and ß37. To evaluate their individual contributions to the R → T spectral changes, we produced three mutant hemoglobins in E. coli; rHb (α14Trp→Leu), rHb (ß15Trp→Leu), and rHb (ß37Trp→His). Near-UV CD and UVRR spectra of these mutant Hbs were compared with those of Hb A under solvent conditions where mutant rHbs exhibited significant cooperativity in oxygen binding. Near-UV CD and UVRR spectra for individual Trp residues were extracted by the difference calculations between Hb A and the mutants. α14 and ß15Trp exhibited negative CD bands in both oxy- and deoxy-Hb A, whereas ß37Trp showed positive CD bands in oxy-Hb A but decreased intensity in deoxy-form. These differences in CD spectra among the three Trp residues in Hb A were ascribed to surrounding hydrophobicity by examining the spectral changes of a model compound of Trp, N-acetyl-l-Trp ethyl ester, in various solvents. Intensity enhancement of Trp UVRR bands upon the R → T transition was ascribed mostly to the hydrogen-bond formation of ß37Trp in deoxy-Hb A because similar UVRR spectral changes were detected with N-acetyl-l-Trp ethyl ester upon addition of a hydrogen-bond acceptor.

Structural origin of cooperativity in human hemoglobin: a view from different roles of α and ß subunits in the α2ß2 tetramer.

This mini-review, mainly based on our resonance Raman studies on the structural origin of cooperative O2 binding in human adult hemoglobin (HbA), aims to answering why HbA is a tetramer consisting of two α and two ß subunits. Here, we focus on the Fe-His bond, the sole coordination bond connecting heme to a globin. The Fe-His stretching frequencies reflect the O2 affinity and also the magnitude of strain imposed through globin by inter-subunit interactions, which is the origin of cooperativity. Cooperativity was first explained by Monod, Wyman, and Changeux, referred to as the MWC theory, but later explained by the two tertiary states (TTS) theory. Here, we related the higher-order structures of globin observed mainly by vibrational spectroscopy to the MWC theory. It became clear from the recent spectroscopic studies, X-ray crystallographic analysis, and mutagenesis experiments that the Fe-His bonds exhibit different roles between the α and ß subunits. The absence of the Fe-His bond in the α subunit in some mutant and artificial Hbs inhibits T to R quaternary structural change upon O2 binding. However, its absence from the ß subunit in mutant and artificial Hbs simply enhances the O2 affinity of the α subunit. Accordingly, the inter-subunit interactions between α and ß subunits are nonsymmetric but substantial for HbA to perform cooperative O2 binding.

A new way to understand quaternary structure changes of hemoglobin upon ligand binding on the basis of UV-resonance Raman evaluation of intersubunit interactions.

The single residue vibrational spectra of tryptophan (Trp) and tyrosine (Tyr) residues in human adult hemoglobin (HbA), which play important roles in cooperative oxygen binding, were determined for the deoxy and CO-bound forms by applying UV resonance Raman spectroscopy to various variant Hbs. It was found that Trpß37, Tyrα42, Tyrα140, and Tyrß145 at the α(1)-ß(2) subunit interface underwent transitions between two contact states (named as T and R) upon ligand binding, while Trpα14, Trpß15, and Tyrß35 displayed little changes. The corresponding spectral changes were identified only for the α(2)ß(2) tetramer, but not the isolated α and ß chains in the oligomeric forms, and therefore were exclusively attributed to a quaternary structure change. Ligand binding as well as allosteric effectors and pH altered only the number of the T-contacted Tyr and Trp residues without varying the two contact states themselves. A new method to semiquantitatively evaluate the amount of T-contacted Tyr and Trp residues in a given liganded form is here proposed, and with it a quaternary structure was determined for various symmetrically half-liganded forms obtained with ligand-hybrid, metal-hybrid, and valency-hybrid Hbs. It was found that ligand binding to the α or ß subunits yielded different subunit contacts and that the contact changes of the Trp and Tyr residues were not always concerted. The contact changes at the α(1)-ß(2) (α(2)-ß(1)) interface are correlated with the proximal strain exerted on the Fe-His(F8) bond, which is noted to be much larger in the α than ß subunits in the α(2)ß(2) tetramer.

Differences in the molecular structure of beta(2)-microglobulin between two morphologically different amyloid fibrils.

Differences in the molecular structures of beta(2)-microglobulin between the two morphologically different amyloid fibrils having a needlelike [long-straight (LS)] and flexible [wormlike (WL)] character were investigated by infrared, Raman, and vacuum-ultraviolet circular dichroism spectroscopy. It turned out that although the beta-sheet content was comparable between the two kinds of fibrils (53 +/- 6% for the LS fibril and 47 +/- 6% for the WL fibril), the protonation states of the carboxyl side chains were distinctly different; the deprotonated (COO(-)) and protonated (COOH) forms were dominant in the LS and WL fibrils at pH 2.5, respectively, meaning that the pK(a) is specifically lowered in the LS fibril. Such a difference was not observed for the fibrils of the core fragments. Since site-specific interactions generally cause variation in the pK(a) of carboxyl side chains in proteins, these results suggest that "hook"-like interactions generated by hydrogen bonding and the formation of a salt bridge are present in the LS fibril, providing enthalpic stabilization. Presumably, the carboxyl groups fix the spatial arrangement of beta-strands and beta-sheets, bringing about the needlelike morphology. The absence of this regulation would result in the flexible morphology of the WL fibril, providing entropic stabilization.

Binding of YC-1/BAY 41-2272 to soluble guanylate cyclase: A new perspective to the mechanism of activation.

Soluble guanylate cyclase (sGC), a heterodimeric heme protein, catalyses the conversion of GTP in to cyclic GMP, which acts as a second messenger in cellular signaling. Nitric oxide activates this enzyme several hundred folds over its basal level. Carbon monoxide, along with some activator molecules like YC-1 and BAY, also synergistically activate sGC. Mechanism of this synergistic activation is a matter of debate. Here we review the existing literature to identify the possible binding site for YC-1 and BAY on bovine lung sGC and its mechanism of activation. These two exogenous compounds bind sGC on alpha subunit inside a pocket and thus exert allosteric effect via subunit interface, which is relayed to the catalytic site. We used docking studies to further validate this hypothesis. We propose that the binding of YC-1/BAY inside the sensory domain of the alpha subunit modulates the interactions on the subunit interface resulting in rearrangements in the catalytic site into active conformation and this partly induces the cleavage of Fe-His bond.

Differences in coordination states of substituted tyrosine residues and quaternary structures among hemoglobin M probed by resonance Raman spectroscopy.

Among the four types of hemoglobin (Hb) M with a substitution of a tyrosine (Tyr) for either the proximal (F8) or distal (E7) histidine in the alpha or beta subunits, only Hb M Saskatoon (betaE7Tyr) assumes a hexacoordinate structure and its abnormal subunits can be reduced readily by methemoglobin (metHb) reductase. This is distinct from the other three M Hbs. To gain new insight into the cause of the difference, we examined the ionization states of E7 and F8 Tyrs by UV resonance Raman (RR) spectroscopy and Fe-O(Tyr) bonding by visible RR spectroscopy. Hb M Iwate (alphaF8Tyr), Hb M Boston (alphaE7Tyr), and Hb M Hyde Park (betaF8Tyr) exhibited two extra UV RR bands at 1,603 cm(-1) (Y8a') and 1,167 cm(-1) (Y9a') arising from deprotonated (ionized) Tyr, but Hb M Saskatoon displayed the UV RR bands of protonated (unionized) Tyr at 1,620 and 1,175 cm(-1) in addition to those of deprotonated Tyr. Evidence for the bonding of both ionization states of Tyr to the heme in Hb M Saskatoon was provided by visible RR spectroscopy. These results indicate that betaE7Tyr of Hb M Saskatoon is in equilibrium between protonated and deprotonated forms, which is responsible for facile reducibility. Comparison of the UV RR spectral features of metHb M with that of metHb A has revealed that metHb M Saskatoon and metHb M Hyde Park are in the R (relaxed) structure, similar to that of metHb A, whereas metHb M Iwate, metHb M Boston and metHb M Milwaukee are in the T (tense) quaternary structure.

Oxidation reactivity of bis(mu-oxo) dinickel(III) complexes: arene hydroxylation of the supporting ligand.

In the nick(el) of time: Bis(mu-oxo) dinickel(III) complexes 2 (see scheme), generated in the reaction of 1 with H(2)O(2), are capable of hydroxylating the xylyl linker of the supporting ligand to give 3. Kinetic studies reveal that hydroxylation proceeds by electrophilic aromatic substitution. The lower reactivity than the corresponding mu-eta(2):eta(2)-peroxo dicopper(II) complexes can be attributed to unfavorable entropy effects.

Axial ligand effects on the geometric and electronic structures of nonheme oxoiron(IV) complexes.

A series of complexes [Fe(IV)(O)(TMC)(X)](+) (where X = OH(-), CF3CO2(-), N3(-), NCS(-), NCO(-), and CN(-)) were obtained by treatment of the well-characterized nonheme oxoiron(IV) complex [Fe(IV)(O)(TMC)(NCMe)](2+) (TMC = tetramethylcyclam) with the appropriate NR4X salts. Because of the topology of the TMC macrocycle, the [Fe(IV)(O)(TMC)(X)](+) series represents an extensive collection of S = 1 oxoiron(IV) complexes that only differ with respect to the ligand trans to the oxo unit. Electronic absorption, Fe K-edge X-ray absorption, resonance Raman, and Mossbauer data collected for these complexes conclusively demonstrate that the characteristic spectroscopic features of the S = 1 Fe(IV)=O unit, namely, (i) the near-IR absorption properties, (ii) X-ray absorption pre-edge intensities, and (iii) quadrupole splitting parameters, are strongly dependent on the identity of the trans ligand. However, on the basis of extended X-ray absorption fine structure data, most [Fe(IV)(O)(TMC)(X)](+) species have Fe=O bond lengths similar to that of [Fe(IV)(O)(TMC)(NCMe)](2+) (1.66 +/- 0.02 A). The mechanisms by which the trans ligands perturb the Fe(IV)=O unit were probed using density functional theory (DFT) computations, yielding geometric and electronic structures in good agreement with our experimental data. These calculations revealed that the trans ligands modulate the energies of the Fe=O sigma- and pi-antibonding molecular orbitals, causing the observed spectroscopic changes. Time-dependent DFT methods were used to aid in the assignment of the intense near-UV absorption bands found for the oxoiron(IV) complexes with trans N3(-), NCS(-), and NCO(-) ligands as X(-)-to-Fe(IV)=O charge-transfer transitions, thereby rationalizing the resonance enhancement of the nu(Fe=O) mode upon excitation of these chromophores.

Construction of a subnanosecond time-resolved, high-resolution ultraviolet resonance Raman measurement system and its application to reveal the dynamic structures of proteins.

A subnanosecond time-resolved ultraviolet (UV) resonance Raman system has been developed to study protein structural dynamics. The system is based on a 1 kHz Nd:YLF-pumped Ti:Sapphire regenerative amplifier with harmonic generation that can deliver visible (412, 440, 458, and 488 nm) and UV (206, 220, 229, and 244 nm) pulses. A subnanosecond (0.2 ns) tunable near-infrared pulse from a custom-made Ti:Sapphire oscillator is used to seed the regenerative amplifier. A narrow linewidth of the subnanosecond pulse offers the advantage of high resolution of UV resonance Raman spectra, which is critical to obtain site-specific information on protein structures. By combination with a 1 m single spectrograph equipped with a 3600 grooves/mm holographic grating and a custom-made prism prefilter, the present system achieves excellent spectral (<10 cm(-1)) and frequency (approximately 1 cm(-1)) resolutions with a relatively high temporal resolution (<0.5 ns). We also report the application of this system to two heme proteins, hemoglobin A and CooA, with the 440 nm pump and 220 nm probe wavelengths. For hemoglobin A, a structural change during the transition to the earliest intermediate upon CO photodissociation is successfully observed, specifically, nanosecond cleavage of the A-E interhelical hydrogen bonds within each subunit at Trpalpha14 and Trpbeta15 residues. For CooA, on the other hand, rapid structural distortion (<0.5 ns) by CO photodissociation and nanosecond structural relaxation following CO geminate recombination are observed through the Raman bands of Phe and Trp residues located near the heme. These results demonstrate the high potential of this instrument to detect local protein motions subsequent to photoreactions in their active sites.

A role of heme side-chains of human hemoglobin in its function revealed by circular dichroism and resonance Raman spectroscopy.

Structural changes of heme side-chains of human adult hemoglobin (Hb A) upon ligand (O2 or CO) dissociation have been studied by circular dichroism (CD) and resonance Raman (RR) spectroscopies. We point out the occurrence of appreciable deformation of heme side-chains like vinyl and propionate groups prior to the out-of-plane displacement of heme iron. Referring to the recent fine resolved crystal structure of Hb A, the deformations of heme side-chains take place only in the ß subunits. However, these changes are not observed in the isolated ß chain (ß4 homotetramer) and, therefore, are associated with the α-ß inter-subunit interactions. For the communications between α and ß subunits in Hb A regarding signals of ligand dissociation, possible routes are proposed on the basis of the time-resolved absorption, CD, MCD (magnetic CD), and RR spectroscopies. Our finding of the movements of heme side-chains would serve as one of the clues to solve the cooperative O2 binding mechanism of Hb A.