Vladimir Pelmenschikov

The HydG enzyme generates an Fe(CO)2(CN) synthon in assembly of the FeFe hydrogenase H-cluster.

Three iron-sulfur proteins–HydE, HydF, and HydG–play a key role in the synthesis of the [2Fe]H component of the catalytic H-cluster of FeFe hydrogenase. The radical S-adenosyl-l-methionine enzyme HydG lyses free tyrosine to produce p-cresol and the CO and CN− ligands of the [2Fe]H cluster. Here, we applied stopped-flow Fourier transform infrared and electron-nuclear double resonance spectroscopies to probe the formation of HydG-bound Fe-containing species bearing CO and CN− ligands with spectroscopic signatures that evolve on the 1- to 1000-second time scale. Through study of the 13C, 15N, and 57Fe isotopologs of these intermediates and products, we identify the final HydG-bound species as an organometallic Fe(CO)2(CN) synthon that is ultimately transferred to apohydrogenase to form the [2Fe]H component of the H-cluster. Vibrational spectroscopy traces the origin of carbon monoxide and cyanide ligands in the active site of di-iron hydrogenase enzymes. [Also see Perspective by Pickett] Sourcing CO and Cyanide Hydrogenase enzymes derive their activity in part from the coordination of CO and cyanide ligands to metals in their active sites. Recent work elucidated the jettisoning of a tyrosine side chain at the outset of the biosynthetic pathway toward these ligands in the di-iron class of hydrogenase. Kuchenreuther et al. (p. 424; see the Perspective by Pickett) now apply stopped-flow infrared spectroscopy to uncover the next portion of the pathway, during which the residual tyrosine fragment is further broken down into CO and CN− ligands at a single iron center in an iron sulfur cluster associated with the HydG enzyme.

Reversible [4Fe-3S] cluster morphing in an O2-tolerant [NiFe] hydrogenase

Hydrogenases catalyze the reversible oxidation of H(2) into protons and electrons and are usually readily inactivated by O(2). However, a subgroup of the [NiFe] hydrogenases, including the membrane-bound [NiFe] hydrogenase from Ralstonia eutropha, has evolved remarkable tolerance toward O(2) that enables their host organisms to utilize H(2) as an energy source at high O(2). This feature is crucially based on a unique six cysteine-coordinated [4Fe-3S] cluster located close to the catalytic center, whose properties were investigated in this study using a multidisciplinary approach. The [4Fe-3S] cluster undergoes redox-dependent reversible transformations, namely iron swapping between a sulfide and a peptide amide N. Moreover, our investigations unraveled the redox-dependent and reversible occurence of an oxygen ligand located at a different iron. This ligand is hydrogen bonded to a conserved histidine that is essential for H(2) oxidation at high O(2). We propose that these transformations, reminiscent of those of the P-cluster of nitrogenase, enable the consecutive transfer of two electrons within a physiological potential range.

Ligand-bound S = 1/2 FeMo-Cofactor of Nitrogenase: Hyperfine Interaction Analysis and Implication for the Central Ligand X Identity

Broken symmetry density functional theory (BS-DFT) has been used to address the hyperfine parameters of the single atom ligand X, proposed to be coordinated by six iron ions in the center of the paramagnetic FeMo-cofactor (FeMoco) of nitrogenase. Using the X = N alternative, we recently found that any hyperfine signal from X would be small (calculated A(iso)(X = (14)N) = 0.3 MHz) due to both structural and electronic symmetry properties of the [Mo-7Fe-9S- X] FeMoco core in its resting S = 3/2 state. Here, we extend our BS-DFT approach to the 2e(-) reduced S = 1/2 FeMoco state. Alternative substrates coordinated to this FeMoco state effectively perturb the electronic and/or structural symmetry properties of the cofactor. Using an example of an allyl alcohol (H2C=CH-CH2-OH) product ligand, we consider three different binding modes at single iron site and three different BS-DFT spin state structures and show that this binding would enhance the key hyperfine signal A(iso)(X) by at least 1 order of magnitude (3.8 < or = A(iso)(X = (14)N) < or = 14.7 MHz), and this result should not depend strongly on the exact identity of X (nitrogen, carbon, or oxygen). The interstitial atom, when the nucleus has a nonzero magnetic moment, should therefore be observable by ESR methods for some ligand-bound FeMoco states. In addition, our results illustrate structural details and likely spin-coupling patterns for models for early intermediates in the catalytic cycle.

Fe–H/D stretching and bending modes in nuclear resonant vibrational, Raman and infrared spectroscopies: Comparisons of density functional theory and experiment

Infrared, Raman, and nuclear resonant vibrational (NRVS) spectroscopies have been used to address the Fe-H bonding in trans-HFe(CO) iron hydride compound, HFe(CO)(dppe)2, dppe = 1,2-bis(diphenylphosphino)ethane. H and D isotopomers of the compound, with selective substitution at the metal-coordinated hydrogen, have been considered in order to address the Fe-H/D stretching and bending modes. Experimental results are compared to the normal mode analysis by density functional theory (DFT). The results are that (i) the IR spectrum does not clearly show Fe-H stretching or bending modes; (ii) Fe-H stretching modes are clear but weak in the Raman spectrum, and Fe-H bending modes are weak; (iii) NRVS 57Fe spectroscopy resolves Fe-H bending clearly, but Fe-H or Fe-D stretching is above its experimentally resolved frequency range. DFT calculations (with no scaling of frequencies) show intensities and peak locations that allow unambiguous correlations between observed and calculated features, with frequency errors generally less than 15 cm(-1). Prospects for using these techniques to unravel vibrational modes of protein active sites are discussed.

Is There a Ni-Methyl Intermediate in the Mechanism of Methyl-Coenzyme M Reductase?

The formation of methyl-Ni(F(430)) species in methyl-coenzyme M reductase (MCR) has been investigated using the B3LYP hybrid density functional method and an active-site model built on the basis of X-ray crystal structure. CH(3)-I, CH(3)-Br, CH(3)-Cl, and CH(3)-S-CH(3) were chosen as the substrates, the last one regarded as a model of the native substrate (methyl-coenzyme M, CH(3)-SCoM). The calculations indicate that the formation of CH(3)-Ni(F(430)) in MCR is dependent on the acidity of the substrate leaving group. A CH(3)-Ni(F(430)) species has been observed with methyl halides as substrates, while the formation of CH(3)-Ni(F(430)) from the native substrate is demonstrated to be inaccessible energetically. These results agree well with the current experiments.

Class I ribonucleotide reductase revisited: The effect of removing a proton on Glu441

The substrate mechanism of class I ribonucleotide reductase has been revisited using the hybrid density functional B3LYP method. The molecular model used is based on the X‐ray structure and includes all the residues of the R1 subunit commonly considered in the RNR substrate conversion scheme: Cys439 initiating the reaction as a thiyl radical, the redox‐active cysteines Cys225 and Cys462, and the catalytically important Glu441 and Asn437. In contrast to previous theoretical studies of the overall mechanism, Glu441 is added as an anion. All relevant transition states have been optimized, including one where an electron is transferred 8 Å from the disulfide to the substrate simultaneously with a proton transfer from Glu441. The calculated barrier for this step is 19.1 kcal/mol, which can be compared to the rate‐limiting barrier indicated by experiments of about 17 kcal/mol. Even though the calculated barrier is somewhat higher than the experimental limit, the discrepancy is within the normal error bounds of B3LYP. The suggestion from the present modeling study is thus that a protonated Glu441 does not need to be present at the active site from the beginning of the catalytic cycle. However, the previously suggested mechanism with an initial protonation of Glu441 cannot be ruled out, because even with the cost added for protonation of Glu441 with a typical pKa of 4, the barrier for that mechanism is lower than the one obtained for the present mechanism. The results are compared to experimental results and suggestions.

Structural Characterization of CO-Inhibited Mo-Nitrogenase by Combined Application of Nuclear Resonance Vibrational Spectroscopy, Extended X-ray Absorption Fine Structure, and Density Functional Theory: New Insights into the Effects of CO Binding and the Role of the Interstitial Atom

The properties of CO-inhibited Azotobacter vinelandii (Av) Mo-nitrogenase (N2ase) have been examined by the combined application of nuclear resonance vibrational spectroscopy (NRVS), extended X-ray absorption fine structure (EXAFS), and density functional theory (DFT). Dramatic changes in the NRVS are seen under high-CO conditions, especially in a 188 cm–1 mode associated with symmetric breathing of the central cage of the FeMo-cofactor. Similar changes are reproduced with the α-H195Q N2ase variant. In the frequency region above 450 cm–1, additional features are seen that are assigned to Fe-CO bending and stretching modes (confirmed by 13CO isotope shifts). The EXAFS for wild-type N2ase shows evidence for a significant cluster distortion under high-CO conditions, most dramatically in the splitting of the interaction between Mo and the shell of Fe atoms originally at 5.08 Å in the resting enzyme. A DFT model with both a terminal −CO and a partially reduced −CHO ligand bound to adjacent Fe sites is consistent with both earlier FT-IR experiments, and the present EXAFS and NRVS observations for the wild-type enzyme. Another DFT model with two terminal CO ligands on the adjacent Fe atoms yields Fe-CO bands consistent with the α-H195Q variant NRVS. The calculations also shed light on the vibrational “shake” modes of the interstitial atom inside the central cage, and their interaction with the Fe-CO modes. Implications for the CO and N2 reactivity of N2ase are discussed.

Resonance Raman Spectroscopic Analysis of the [NiFe] Active Site and the Proximal [4Fe-3S] Cluster of an O2-Tolerant Membrane-Bound Hydrogenase in the Crystalline State.

We have applied resonance Raman (RR) spectroscopy on single protein crystals of the O2-tolerant membrane-bound [NiFe] hydrogenase (MBH from Ralstonia eutropha) which catalyzes the splitting of H2 into protons and electrons. RR spectra taken from 65 MBH samples in different redox states were analyzed in terms of the respective component spectra of the active site and the unprecedented proximal [4Fe-3S] cluster using a combination of statistical methods and global fitting procedures. These component spectra of the individual cofactors were compared with calculated spectra obtained by quantum mechanics/molecular mechanics (QM/MM) methods. Thus, the recently discovered hydroxyl-coordination of one iron in the [4Fe-3S] cluster was confirmed. Infrared (IR) microscopy of oxidized MBH crystals revealed the [NiFe] active site to be in the Nir-B [Ni(III)] and Nir-S [Ni(II)] states, whereas RR measurements of these crystals uncovered the Nia-S [Ni(II)] state as the main spectral component, suggesting its in situ formation via photodissociation of the assumed bridging hydroxyl or water ligand. On the basis of QM/MM calculations, individual band frequencies could be correlated with structural parameters for the Nia-S state as well as for the Ni-L state, which is formed upon photodissociation of the bridging hydride of H2-reduced active site states.

Docking and Migration of Carbon Monoxide in Nitrogenase: The Case for Gated Pockets from Infrared Spectroscopy and Molecular Dynamics

Evidence of a CO docking site near the FeMo cofactor in nitrogenase has been obtained by Fourier transform infrared spectroscopy-monitored low-temperature photolysis. We investigated the possible migration paths for CO from this docking site using molecular dynamics calculations. The simulations support the notion of a gas channel with multiple internal pockets from the active site to the protein exterior. Travel between pockets is gated by the motion of protein residues. Implications for the mechanism of nitrogenase reactions with CO and N2 are discussed.

Reaction Coordinate Leading to H2 Production in [FeFe]-Hydrogenase Identified by Nuclear Resonance Vibrational Spectroscopy and Density Functional Theory

[FeFe]-hydrogenases are metalloenzymes that reversibly reduce protons to molecular hydrogen at exceptionally high rates. We have characterized the catalytically competent hydride state (Hhyd) in the [FeFe]-hydrogenases from both Chlamydomonas reinhardtii and Desulfovibrio desulfuricans using 57Fe nuclear resonance vibrational spectroscopy (NRVS) and density functional theory (DFT). H/D exchange identified two Fe-H bending modes originating from the binuclear iron cofactor. DFT calculations show that these spectral features result from an iron-bound terminal hydride, and the Fe-H vibrational frequencies being highly dependent on interactions between the amine base of the catalytic cofactor with both hydride and the conserved cysteine terminating the proton transfer chain to the active site. The results indicate that Hhyd is the catalytic state one step prior to H2 formation. The observed vibrational spectrum, therefore, provides mechanistic insight into the reaction coordinate for H2 bond formation by [FeFe]-hydrogenases.