Ultrafast heme dynamics in ferrous versus ferric cytochrome c studied by time-resolved resonance Raman and transient absorption spectroscopy

Cytochrome c (Cyt c) is a heme protein involved in electron transfer and also in apoptosis. Its heme iron is bisaxially ligated to histidine and methionine side chains and both ferric and ferrous redox states are physiologically relevant, as well as a ligand exchange between internal residue and external diatomic molecule. The photodissociation of internal axial ligand was observed for several ferrous heme proteins including Cyt c, but no time-resolved studies have been reported on ferric Cyt c. To investigate how the oxidation state of the heme influences the primary photoprocesses, we performed a comprehensive comparative study on horse heart Cyt c by subpicosecond time-resolved resonance Raman and femtosecond transient absorption spectroscopy. We found that in ferric Cyt c, in contrast to ferrous Cyt c, the photodissociation of an internal ligand does not take place, and relaxation dynamics is dominated by vibrational cooling in the ground electronic state of the heme. The intermolecular vibrational energy transfer was found to proceed in a single phase with a temperature decay of approximately 7 ps in both ferric and ferrous Cyt c. For ferrous Cyt c, the instantaneous photodissociation of the methionine side chain from the heme iron is the dominant event, and its rebinding proceeds in two phases, with time constants of approximately 5 and approximately 16 ps. A mechanism of this process is discussed, and the difference in photoinduced coordination behavior between ferric and ferrous Cyt c is explained by an involvement of the excited electronic state coupled with conformational relaxation of the heme.     

CO cage recombination in hemoglobin: Picosecond photolysis and nanosecond observation

Carboxy hemoglobin in aqueous solution was photodissociated by laser pulses of 30 ps at 532 nm. Kinetic studies show that only upon complete photodissociation can the pure CO geminate binding process be revealed. The protein region of the iron cage, where the geminate ligand diffuses before reaching the heme, is smaller than a single subunit and larger than the heme pocket.     

Exciplex Formation in Lipid-bound Escherichia coli Flavohemoglobin

Flavohemoglobins have the particular capability of binding unsaturated and cyclopropanated fatty acids as free acids or phospholipids. Fatty acid binding to the ferric heme results in a weak but direct bonding interaction. Ferrous and ferric protein, in presence or absence of a bound lipid molecule, have been characterized by transient absorption spectroscopy. Measurements have been also carried out both on the ferrous deoxygenated and on the CO bound protein to investigate possible long-range interaction between the lipid acyl chain moiety and the ferrous heme. After excitation of the deoxygenated derivatives the relaxation process reveals a slow dynamics (350 ps) in lipid-bound protein but is not observed in the lipid-free protein. The latter feature and the presence of an extra contribution in the absorption spectrum, indicates that the interaction of iron heme with the acyl chain moiety occurs only in the excited electronic state and not in the ground electronic state. Data analysis highlights the formation of a charge-transfer complex in which the iron ion of the lipid-bound protein in the expanded electronic excited state, possibly represented by a high spin Fe III intermediate, is able to bind to the sixth coordination ligand placed at a distance of at 3.5 Å from the iron. A very small nanosecond geminate rebinding is observed for CO adduct in lipid-free but not in the lipid-bound protein. The presence of the lipid thus appears to inhibit the mobility of CO in the heme pocket.     

Iron hemiporphycene as a functional prosthetic group for myoglobin

The iron complex of hemiporphycene, a molecular hybrid of porphyrin with porphycene, was incorporated into the apomyoglobin pocket to examine ligand binding ability of the iron atom in the novel porphyrinoid. Apomyoglobin was successfully coupled with a stoichiometric amount of ferric hemiporphycene to afford the reconstituted myoglobin equipped with the iron coordination structure of native protein. Cyanide, imidazole, and fluoride coordinated to the ferric protein with affinities comparable with those for native myoglobin. The ferrous myoglobin was functionally active to bind O(2) and CO reversibly at pH 7.4 and 20 degrees C. The O(2) affinity is 12-fold higher than that of native myoglobin while the CO affinity is slightly lower, suggesting decreased discrimination between O(2) and CO in the heme pocket. The functional anomaly was interpreted to reflect increased sigma-bonding character in the Fe(II)-O(2) bond. In contrast with 6-coordinate native NO protein, the NO myoglobin containing ferrous hemiporphycene is in a mixed 5- and 6-coordinate state. This observation suggests that the in-plane configuration of the iron atom in hemiporphycene is destabilized by NO. Influence of the core deformation was also detected with both the infrared absorption for the ferrous CO derivative and electron paramagnetic resonance for ferric imidazole complex. Anomalies in the ferric and ferrous derivatives were ascribed to the modified iron-N(pyrrole) interactions in the asymmetric metallo core of hemiporphycene.     

Assignment of the hyperfine-shifted 1H-NMR signals of the heme in the oxygen sensor FixL from Rhizobium meliloti

Background: The Rhizobial oxygen sensor FixL is a hemoprotein with kinase activity. On binding of strong-field ligands, a change of the ferrous or ferric heme iron from high to low spin reversibly inactivates the kinase. This spin-state change and other information on the heme pocket have been inferred from enzymatic assays, absorption spectra and mutagenesis studies. We set out to investigate the spin-state of the FixL heme and to identify the hyperfine-shifted heme-proton signals by NMR spectroscopy.Results: Using one-dimensional N MR we directly observed the high- and low-spin nature of the met- and cyanomet-FixL heme domain, respectively. We determined the hyperfine-shifted ¹H-NMR signals of the heme and the proximal histidine by one- and two-dimensional spectroscopy and note the absence of distal histidine signals.Conclusions: These findings support the spin-state mechanism of FixL regulation. They establish that the site of heme coordination is a histidine residue and strongly suggest that a distal histidine is absent. With a majority of the heme resonances identified, one- and two-dimensional NMR techniques can be extended to provide structural and mechanistic information about the residues that line the heme pocket.     

Dioxygenation of human serum albumin having a prosthetic heme group in a tailor-made heme pocket

Human serum albumin (HSA) is the most abundant plasma protein in our bloodstream and serves as a transporter for small hydrophobic molecules such as fatty acids, bilirubin, and steroids. Hemin dissociated from methemoglobin is also bound within a narrow D-shaped cavity in subdomain IB of HSA. In terms of the general hydrophobicity of the alpha-helical pocket, HSA potentially has features similar to the heme-binding site of myoglobin (Mb) or hemoglobin (Hb). However, the reduced ferrous HSA-heme complex is immediately oxidized by O2, because HSA lacks the proximal histidine that enables the heme group to bind O2. In this paper, we report the introduction of a proximal histidine into the subdomain IB of HSA by site-directed mutagenesis to construct a tailor-made heme pocket (I142H/Y161L), which allows a reversible O2 binding to the prosthetic heme group. Laser flash photolysis experiments revealed that this artificial hemoprotein appears to have two different geometries of the axial-imidazole coordination, and these two species (I and II) showed rather low O2 binding affinities (P1/2O2 = 18 and 134 Torr) relative to those of Mb and Hb.     

Impact of proximal and distal pocket site-directed mutations on the ferric/ferrous heme redox potential of yeast cytochrome c peroxidase

Cytochrome c peroxidase (CCP) contains a five-coordinate heme active site. The reduction potential for the ferric to ferrous couple in CCP is anomalously low and pH dependent (Eo?=?~?180?mV vs. S.H.E. at pH 7). The contribution of the protein environment to the tuning of the redox potential of this couple is evaluated using site-directed mutants of several amino acid residues in the environment of the heme. These include proximal pocket mutation of residues Asp-235, Trp-191, Phe-202, and His-175, distal pocket mutation of residues Trp-51, His-52, and Arg-48; and a heme edge mutation of Ala-147. Where unknown, the structural changes resulting from the amino acid substitution have been studied by X-ray crystallography. In most cases, ostensibly polar or charged residues are replaced by large hydrophobic groups or alternatively by Ala or Gly. These latter have been shown to generate large, solvent-filled cavities. Reduction potentials are measured as a function of pH by spectroelectrochemistry. Starting with the X-ray-derived structures of CCP and the mutants, or with predicted structures generated by molecular dynamics (MD), predictions of redox potential changes are modeled using the protein dipoles Langevin dipoles (PDLD) method. These calculations serve to model an electrostatic assessment of the redox potential change with simplified assumptions about heme iron chemistry, with the balance of the experimentally observed shifts in redox potential being thence attributed to changes in the ligand set and heme coordination chemistry, and/or other changes in the structure not directly evident in the X-ray structures (e.g., ionization states, specific roles played by solvent species, or conformationally flexible portions of the protein). Agreement between theory and experiment is good for all mutant proteins with the exception of the mutation Arg 48 to Ala, and His 52 to Ala. In the former case, the influence of phosphate buffer is adduced to account for the discrepancy, with evidence for phosphate binding in the distal pocket, and measurements made in a bis?Ctris propane/2-(N-morpholino)ethanesulfonic acid buffer system agree well with theory. For the latter case, an unknown structural element relevant to His-52 and/or solvent influence in the mutant akin to anion binding in the distal pocket (though lacking proof that it is, and in this case lacking a phosphate effect) manifests in this mutant. The use of exogenous (sixth) ligands in dissecting the contributions to control of redox potential is also explored as a pathway for model building.     

Characterization of conformational changes and noncovalent complexes of myoglobin by electrospray ionization mass spectrometry,circular dichroism and fluorescence spectroscopy

Electrospray ionization mass spectrometry (ESI‐MS) was employed to monitor the heme release and the conformational changes of myoglobin (Mb) under different solvent conditions, and to observe ligand bindings of Mb. ESI‐MS, complemented by circular dichroism and fluorescence spectroscopy, was used to study the mechanism of acid‐ and organic solvent‐induced denaturation by probing the changes in the secondary and the tertiary structure of Mb. The results obtained show that complete disruption of the heme–protein interactions occurs when Mb is subjected to one of the following solution conditions: pH 3.2–3.6, or solution containing 20–30% acetonitrile or 40–50% methanol. Outside these ranges, Mb is present entirely in its native state (binding with a heme group) or as apomyoglobin (i.e. without the heme). Spectroscopic data demonstrate that the denaturation mechanism of Mb induced by acid may be significantly different from that by the organic solvent. Low pH reduces helices in Mb, whereas certain organic content level in solution results in the loss of the tertiary structure. ESI‐MS conditions were established to observe the H₂O‐ and CO‐bound Mb complexes, respectively. H₂O binding to metmyoglobin (17 585 Da), where the heme iron is in the ferric oxidation state, is observed in ESI‐MS. CO binding to Mb (17 595 Da), on the other hand, can be only observed after the heme iron is reduced to the ferrous form. Therefore, ESI‐MS combined with spectroscopic techniques provides a useful means for probing the formation of ligand‐binding complexes and characterizing protein conformational changes. Copyright © 2010 John Wiley & Sons, Ltd.     

Nonequilibrium dynamics simulations of nitric oxide release: comparative study of nitrophorin and myoglobin

Nitrophorin 4 (NP4) is a heme protein that reversibly binds nitric oxide (NO), with release rates modulated by pH change. High-resolution structures of NP4 revealed that pH changes and NO binding induce a large conformational rearrangement in two loops that serve to protect the heme-bound NO molecule from solvent. We used extended (110 ns) molecular dynamics simulations of NP4 at pH 5 and pH 7, modeled by selective deprotonation of acidic groups. Conformational and dynamic changes were observed, consistent with those found in the crystal. Further, major solvent movement and NO escape were observed at pH 7, while the ligand remained in the heme binding pocket at pH 5. As a control, we also performed molecular dynamics (MD) simulations of sperm whale myoglobin, where NO migration into the interior cavities of the protein was observed, consistent with previous reports. We constructed a kinetic model of ligand escape to quantitatively relate the microscopic rate constants to the observed rates, and tested the predictions against the experimental data. The results suggest that release rates of diatomic molecules from heme proteins can be varied by several orders of magnitude through modest adjustments in geminate rebinding and gating behavior.     

Photodissociation of heme distal methionine in ferrous cytochrome C revealed by subpicosecond time-resolved resonance Raman spectroscopy

Cytochrome c (cyt c) is an electron-transfer heme protein that also binds nitric oxide (NO). In resting cyt c, two endogenous ligands of the heme iron are histidine-18 (His) and methionine-80 (Met) side chains, and NO binding requires the cleavage of one of the axial bonds. Previous femtosecond transient absorption studies suggested the photolysis of either Fe-His or Fe-Met bonds. We aimed at unequivocally identifying the internal side chain that is photodissociated in ferrous cyt c and at monitoring heme structural dynamics, by means of time-resolved resonance Raman (TR3) spectroscopy with approximately 0.6 ps time resolution. The Fe-His stretching mode at 216 cm-1 has been observed in photoproduct TR3 spectra for the first time for a c-type heme. The same transient mode was observed for a model ferrous cyt c N-fragment (residues 1-56) ligated with two His in the resting state. Our TR3 data reveal that upon ferrous cyt c photoexcitation, (i) distal Met side chain is instantly released, producing a five-coordinated domed heme structure, (ii) proximal His side chain, coupled to the heme, exhibits distortion due to strain exerted by the protein, and (iii) alteration in heme-cysteine coupling takes place along with the relaxation of the protein-induced deformations of the heme macrocycle.     

Study on the Gas Phase Stability of Heme-binding Pocket in Cytochrome Tb_5 and Its Mutants by Electrospray Mass Spectrometry

Ｃｙｔｏｃｈｒｏｍｅｂ5(Ｃｙｔｂ5)ｉｓｆｏｕｎｄｂｏｔｈａｓａｃｏｍｐｏ ｎｅｎｔｏｆｔｈｅｍｉｃｒｏｓｏｍａｌｍｅｍｂｒａｎｅｓａｎｄａｓａｓｏｌｕｂｌｅｆｏｒｍｉｎｅｒｙｔｈｒｏｃｙｔｅｓ .Ｉｔｐｌａｙｓａｎｉｍｐｏｒｔａｎｔｒｏｌｅｉｎｂｉｏｌｏｇｉｃａｌｓｙｓｔｅｍｓ ,ｉｎｗｈｉｃｈＣｙｔｂ5ｆｕｎｃｔｉｏｎｓａｓａｎｅｌｅｃｔｒｏｎｃａｒｒｉｅｒ,ｐａｒｔｉｃｉｐａｔｉｎｇｉｎａｓｅｒｉｅｓｏｆｅｌｅｃｔｒｏｎ ｔｒａｎｓｆｅｒｐｒｏｃｅｓｓｅｓ ,ｉｎ ｃｌｕｄｉｎｇｒｅｄｕｃｔｉｏｎｏｆ…     

Efficient photodissociation of O2 from synthetic heme and heme/M (M = Fe, Cu) complexes

Single wavelength excitation (lambdaex = 355 or 532 nm) of low-temperature stabilized (198 K) synthetic heme-dioxygen and heme-dioxygen/M complexes, where M = copper or iron in a non-heme environment, results in the dissociation of dioxygen as indicated by the generation of the ferrous heme (Soret band, 427 nm) and the bleaching of the ferric-superoxide (FeIII(O2-)) 410-nm Soret band in the transient absorption difference spectrum. Dioxygen rebinds to the four heme complexes studied with comparable rate constants ( approximately 6-9 x 105 M-1 s-1). However, the quantum yield for complete dissociation of O2 from our simplest heme-O2 complex (F8)FeIII(O2-) (phi = 0.60) is higher than the other complexes measured (phi = approximately 0.2-0.3) as well as that for oxy-myoglobin (phi = 0.3).     

How do azoles inhibit cytochrome P450 enzymes? A density functional study

To examine how azole inhibitors interact with the heme active site of the cytochrome P450 enzymes, we have performed a series of density functional theory studies on azole binding. These are the first density functional studies on azole interactions with a heme center and give fundamental insight into how azoles inhibit the catalytic function of P450 enzymes. Since azoles come in many varieties, we tested three typical azole motifs representing a broad range of azole and azole-type inhibitors: methylimidazolate, methyltriazolate, and pyridine. These structural motifs represent typical azoles, such as econazole, fluconazole, and metyrapone. The calculations show that azole binding is a stepwise mechanism whereby first the water molecule from the resting state of P450 is released from the sixth binding site of the heme to create a pentacoordinated active site followed by coordination of the azole nitrogen to the heme iron. This process leads to the breaking of a hydrogen bond between the resting state water molecule and the approaching inhibitor molecule. Although, formally, the water molecule is released in the first step of the reaction mechanism and a pentacoordinated heme is created, this does not lead to an observed spin state crossing. Thus, we show that release of a water molecule from the resting state of P450 enzymes to create a pentacoordinated heme will lead to a doublet to quartet spin state crossing at an Fe-OH(2) distance of approximately 3.0 A, while the azole substitution process takes place at shorter distances. Azoles bind heme with significantly stronger binding energies than a water molecule, so that these inhibitors block the catalytic cycle of the enzyme and prevent oxygen binding and the catalysis of substrate oxidation. Perturbations within the active site (e.g., a polarized environment) have little effect on the relative energies of azole binding. Studies with an extra hydrogen-bonded ethanol molecule in the model, mimicking the active site of the CYP121 P450, show that the resting state and azole binding structures are close in energy, which may lead to chemical equilibrium between the two structures, as indeed observed with recent protein structural studies that have demonstrated two distinct azole binding mechanisms to P450 heme.     

鼠脑红蛋白突变体F106L与氰根的结合作用

构建了鼠脑红蛋白(Mouse neuroglobin)的突变体F106L, 以探求近端残基对脑红蛋白血红素口袋结构的贡献. 通过溶液核磁共振方法研究了外来配体氰根离子与NgbF106L蛋白的结合作用, 结果显示, 此结合存在动力学过程, 并且NgbF106LCN 突变蛋白氰根络合物可以可逆地释放氰根离子, 并使原来的第6配体His64(E7)又结合回到血红素铁上. 研究结果揭示, G5(Phe106)残基对脑红蛋白血红素构象而言较为保守; QM/MM结构优化结果表明, 位于G5 和FG5的近端残基对蛋白结构稳定性具有重要作用, 并可调控外来配体与蛋白作用的配位平衡与热动力学性质.     

Significance of the molecular shape of iron corrphycene in a protein pocket

The iron complex of a new type of corrphycene bearing two ethoxycarbonyl (-CO2C2H5) groups on the bipyrrole moiety was introduced into apomyoglobin. The reconstituted ferric myoglobin has a coordinating water molecule that deprotonates to hydroxide with a pK(a) value of 7.3 and exhibits 3-10-fold higher affinities for anionic ligands when compared with a counterpart myoglobin with the same substituents on the dipyrroethene moiety. In the ferrous state, the oxygen affinity of the new myoglobin was decreased to 1/410 of the native protein. The anomalies in the ligand binding, notably dependent on the side-chain location, were interpreted in terms of a characteristic core shape of corrphycene that produces the longer and shorter Fe-N(pyrrole) bonds. The spin-state equilibrium analysis of the ferric azide myoglobin containing the new iron corrphycene supported the nonequivalence of the Fe-N(pyrrole) bonds. These results demonstrate that the trapezoidal molecular shape of corrphycene exerts functional significance when the iron complex is placed in a protein pocket.     

Structural and dynamical basis of broad substrate specificity, catalytic mechanism, and inhibition of cytochrome P450 3A4

Cytochrome P450 (CYP) 3A4 is responsible for the oxidative degradation of more than 50% of clinically used drugs. By means of molecular dynamics simulations with the newly developed force field parameters for the heme-thiolate group and its dioxygen adduct, we examine the differences in structural and dynamic properties between CYP3A4 in the resting form and its complexes with the substrate progesterone and the inhibitor metyrapone. The results indicate that the broad substrate specificity of CYP3A4 stems from the malleability of a loop (residues 211-218) that resides in the vicinity of the channel connecting the active site and bulk solvent. However, the high-amplitude motion of the flexible loop is found to be damped out upon binding of the inhibitor or the substrate in the active site. In the resting form of CYP3A4, a structural water molecule is bound to the sixth coordination position of the heme iron, stabilizing the octahedral coordination geometry. In addition to the direct coordination of metyrapone to the heme iron, the hydrogen bond interaction between the inhibitor carbonyl group and the side chain of Ser119 also contributes significantly to stabilizing the CYP3A4-metyrapone complex. On the other hand, progesterone is stabilized in the active site by the formation of two hydrogen bonds with Ser119 and Arg106, as well as by the van der Waals interactions with the heme and hydrophobic residues. The structural and dynamic features of the CYP3A4-progesterone complex indicate that the oxidative degradation of progesterone occurs through hydroxylation at the C16 position by the reactive oxygen coordinated to the heme iron.     

Novel Conformational Transitions of Human Cytochrome P450 2C8 during Thermal and Acid-induced Unfolding

Transitions among various heme coordination/spin states, heme environments and protein conformations of human cytochrome P450 2C8 were investigated under different denaturing conditions by means of electronic absorption and circular dichroism spectroscopies. It is the first report of it's kind. Our results indicated that the thermal and acid‐induced denaturation could convert P450 2C8 to various P420 forms. In the thermal unfolding process, the ferric P420 thermal form emerged with weakened Fe‐S (thiolate) bond. An absorption band at ca. 425 nm of the ferrous P420 2C8 thermal form was observed, suggesting that the axial Cys435 was protonated or displaced by other ligand. Moreover, the new coordination bond was stabilized when the temperature was cooled down. When binding with CO, the ferrous P420 2C8 thermal form had the protonated thiol of Cys435 as the axial ligand. X‐ray structure of P450 2C8 suggested that the specific structure of the β‐bulge where the axial cysteine ligand located might be the reason of the formation of these P420 2C8 thermal forms. In the acid‐induced unfolding studies, we found that at pH 3.0 the heme could be irreversibly released from the heme pocket of ferric and ferrous P450 2C8. Interestingly, the released heme could form a new coordination bond with an unidentified ligand at the surface of partially unfolded protein when binding with CO at reduced state.     

两聚物(C6H5F)+2的光解离光谱

使用质量选择的团簇离子光解离光谱技术,ＫａｚｎｈｉｋｏＯｈａｓｈｉ等人研究了两聚物离子苯的电子态谱[1],在可见到近红外波段,光谱分为两种类型:一种是局域激发带,它是出自于两聚体(Ｘ) 2中单体离子Ｘ 的局域电子激发跃迁;另一种则是电荷共振带.在两聚体(Ｘ) 2中,电荷...     

Ab initio Quantum Mechanics/Molecular Mechanics Molecular Dynamics Simulation of CO in the Heme Distal Pocket of Myoglobin

Myoglobin has important biological functions in storing and transporting small diatomic molecules in human body. Two possible orientations of carbon monoxide (CO) in the heme distal pocket (named as B₁ and B₂ states) of myoglobin have been experimentally indicated. In this study, ab initio quantum mechanics/molecular mechanics (QM/MM) molecular dynamics simulation of CO in myoglobin was carried out to investigate the two possible B states. Our results demonstrate that the B₁ and B₂ states correspond to Fe…CO (with carbon atom closer to iron center of heme) and Fe…OC (with oxygen atom closer to Fe), by comparing with the experimental infrared spectrum. QM electrostatic polarization effect on CO brought from the protein and solvent environment is the main driving force, which anchors CO in two distinctive orientations and hinders its rotation. The calculated vibrational frequency shift between the state B₁ and B₂ is 13.1 cm^-1, which is in good agreement with experimental value of 11.5 cm^-1. This study also shows that the electric field produced by the solvent plays an important role in assisting protein functions by exerting directional electric field at the active site of the protein. From residue-based electric field decomposition, several residues were found to have most contributions to the total electric field at the CO center, including a few charged residues and three adjacent uncharged polar residues (namely, HIS64, ILE107, and PHE43). This study provides new physical insights on rational design of enzyme with higher electric field at the active site.     

Influences of the Hydrophobicity of the Heme－binding Pocket on the Properties and Functions of Cytochrome b5 Mutants

The mutation sites of the four mutants F35Y, P40V, V45E and V45Y of cytochrome b5 are located at the edge of the heme-binding pocket. The solvent accessible areas of the “pocket inte-rior“ of the four mutants and the wild-type cytochrome b5 have been calculated based on their crystal structures at high resolu-tion. The change in the hydrophobicity of the heme-binding pocket resulting from the mutation can be quantitatively de-scribed using the difference of the solvent accessible area of the “pocket interior“ of each mutant from that of the wild-type cy-tochrome b5. The influences of the hydrophobicity of the heme-binding pocket on the protein stability and redox potential are discussed.