The metalloclusters of carbon monoxide dehydrogenase/acetyl-CoA synthase: a story in pictures

Eight Ni proteins are known and three of these, CO dehydrogenase (CODH), acetyl-CoA synthase (ACS), and hydrogenase, are Ni-Fe-S proteins. In the last three years, the long-awaited structures of CODH and ACS have been solved. The bioinorganic community was shocked, as the structures of the active sites of CODH and ACS, the C- and A-cluster, respectively, which each had been predicted to consist of a [Fe₄S₄] cluster bridged to a single Ni, revealed unexpected compositions and arrangements. Crystal structures of ACS revealed major differences in protein conformation and in A-cluster composition; for example, a [Fe₄S₄] cluster bridged to a binuclear center in which one of the metal binding sites was occupied by Ni, Cu, or Zn. Recent studies have revealed Ni-Ni to be the active state, unveiled the source of the heterogeneity that had plagued studies of CODH/ACS for decades, and produced a metal-replacement strategy to generate highly active and nearly homogeneous enzyme.Abbreviations CFeSP corrinoid iron-sulfur protein - CH₃H₄folate methyltetrahydrofolate - CODH/ACS carbon monoxide dehydrogenase/acetyl-CoA synthases - ENDOR electron nuclear double resonance - MeTr methyltransferase     

Rapid kinetic studies of acetyl-CoA synthesis: evidence supporting the catalytic intermediacy of a paramagnetic NiFeC species in the autotrophic Wood-Ljungdahl pathway

CO dehydrogenase/acetyl-CoA synthase (CODH/ACS), a key enzyme in the Wood-Ljungdahl pathway of anaerobic CO(2) fixation, is a bifunctional enzyme containing CODH, which catalyzes the reversible two-electron oxidation of CO to CO(2), and ACS, which catalyzes acetyl-CoA synthesis from CoA, CO, and a methylated corrinoid iron-sulfur protein (CFeSP). ACS contains an active site nickel iron-sulfur cluster that forms a paramagnetic adduct with CO, called the nickel iron carbon (NiFeC) species, which we have hypothesized to be a key intermediate in acetyl-CoA synthesis. This hypothesis has been controversial. Here we report the results of steady-state kinetic experiments; stopped-flow and rapid freeze-quench transient kinetic studies; and kinetic simulations that directly test this hypothesis. Our results show that formation of the NiFeC intermediate occurs at approximately the same rate as, and its decay occurs 6-fold faster than, the rate of acetyl-CoA synthesis. Kinetic simulations of the steady-state and transient kinetic results accommodate the NiFeC species in the mechanism and define the rate constants for the elementary steps in acetyl-CoA synthesis. The combined results strongly support the kinetic competence of the NiFeC species in the Wood-Ljungdahl pathway. The results also imply that the methylation of ACS occurs by attack of the Ni(1+) site in the NiFeC intermediate on the methyl group of the methylated CFeSP. Our results indicate that CO inhibits acetyl-CoA synthesis by inhibiting this methyl transfer reaction. Under noninhibitory CO concentrations (below 100 microM), formation of the NiFeC species is rate-limiting, while at higher inhibitory CO concentrations, methyl transfer to ACS becomes rate-limiting.     

Nickel-dependent oligomerization of the alpha subunit of acetyl-coenzyme a synthase/carbon monoxide dehydrogenase

After activation with NiCl2, the recombinant alpha subunit of the Ni-containing alpha2beta2 acetyl-CoA synthase/carbon monoxide dehydrogenase (ACS/CODH) catalyzes the synthesis of acetyl-CoA from CO, CoA, and a methyl group donated from the corrinoid-iron-sulfur protein (CoFeSP). The alpha subunit has two conformations (open and closed), and contains a novel [Fe4S4]-[Nip Nid] active site in which the proximal Nip ion is labile. Prior to Ni activation, recombinant apo-alpha contain only an Fe4S4 cluster. Ni-activated alpha subunits exhibit catalytic, spectroscopic and heterogeneity properties typical of alpha subunits contained in ACS/CODH. Evidence presented here indicates that apo-alpha is a monomer whereas Ni-treated alpha oligomerizes, forming dimers and higher molecular weight species including tetramers. No oligomerization occurred when apo-alpha was treated with Cu(II), Zn(II), or Co(II) ions, but oligomerization occurred when apo-alpha was treated with Pt(II) and Pd(II) ions. The dimer accepted only 0.5 methyl group/alpha and exhibited, upon treatment with CO and under reducing conditions, the NiFeC EPR signal quantifying to 0.4 spin/alpha. Dimers appear to consist of two types of alpha subunits, including one responsible for catalytic activity and one that provides a structural scaffold. Higher molecular weight species may be similarly constituted. It is concluded that Ni binding to the A-cluster induces a conformational change in the alpha subunit, possibly to the open conformation, that promotes oligomerization. These interrelated events demonstrate previously unrealized connections between (a) the conformation of the alpha subunit; (b) the metal which occupies the proximal/distal sites of the A-cluster; and (c) catalytic activity.     

Tunnel mutagenesis and Ni-dependent reduction and methylation of the α subunit of acetyl coenzyme A synthase/carbon monoxide dehydrogenase

Two isolated alpha subunit mutants (A110C and A222L) of the alpha(2)beta(2) acetyl coenzyme A synthase (ACS)/carbon monoxide dehydrogenase (CODH) from Moorella thermoacetica were designed to block the CO-migrating tunnel in the alpha subunit, allowing comparison with equivalent mutants in ACS/CODH. After Ni activation, both mutants exhibited electron paramagnetic resonance spectra indicating that the A-cluster was properly assembled. ACS activities were similar to those of the wild-type recombinant Ni-activated alpha subunit, suggesting that CO diffuses directly to the A-cluster from solvent rather than through the tunnel as is observed for the "majority" activity of ACS/CODH. Thus, CO appears to migrate to the A-cluster through two pathways, one involving and one not involving the tunnel. The kinetics and extent of reduction of the Fe(4)S(4) cubane in the apo-alpha subunit and the Ni-activated alpha subunit upon exposure to titanium(III) citrate were examined using the stopped-flow method. The extent of reduction was independent of Ni, whereas the kinetics of reduction was Ni-dependent. Apo-alpha subunit reduction was monophasic while Ni-activated alpha subunit reduction was biphasic, with the more rapid phase coincident with that of apo-alpha subunit reduction. Thus, binding of Ni to the A-cluster slows the reduction kinetics of the [Fe(4)S(4)](2+) cubane. An upper limit of two electrons per alpha subunit are transferred from titanium(III) citrate to the Ni subcomponent of the A-cluster during reductive activation. These electrons are accepted quickly relative to the reduction of the [Fe(4)S(4)](2+) cubane. This reduction is probably a prerequisite for methyl group transfer. CO appears to bind to reduced nonfunctional subunits, thereby inhibiting reduction (or promoting reoxidation) of the cubane subcomponent of the A-cluster.     

Spectroscopic and computational insights into the geometric and electronic properties of the A-cluster of acetyl-coenzyme A synthase

For the last two decades, the bifunctional enzyme acetyl-coenzyme A synthase/carbon monoxide dehydrogenase (ACS/CODH) from Moorella thermoacetica has been the subject of considerable research aimed at elucidating the geometric and electronic properties of the A-cluster, which serves as the active site for ACS catalysis. While the recent success in obtaining high-resolution X-ray structures of this enzyme solved many of the mysteries regarding the number, identities, and coordination environments of the metal centers of the A-cluster, fundamental questions concerning the catalytic mechanism of this highly elaborate polynuclear active site have yet to be answered. This Commentary summarizes relevant information obtained from spectroscopic and computational studies on the oxidized, reduced, and CO-bound forms of the A-cluster and highlights some of the key issues regarding the electronic properties and reactivity of this cluster that need to be addressed in future studies.     

Evidence that ferredoxin interfaces with an internal redox shuttle in Acetyl-CoA synthase during reductive activation and catalysis

Acetyl-CoA synthase (ACS), a subunit of the bifunctional CO dehydrogenase/acetyl-CoA synthase (CODH/ACS) complex of Moorella thermoacetica requires reductive activation in order to catalyze acetyl-CoA synthesis and related partial reactions, including the CO/[1-(14)C]-acetyl-CoA exchange reaction. We show that the M. thermoacetica ferredoxin(II) (Fd-II), which harbors two [4Fe-4S] clusters and is an electron acceptor for CODH, serves as a redox activator of ACS. The level of activation depends on the oxidation states of both ACS and Fd-II, which strongly suggests that Fd-II acts as a reducing agent. By the use of controlled potential enzymology, the midpoint reduction potential for the catalytic one-electron redox-active species in the CO/acetyl-CoA exchange reaction is -511 mV, which is similar to the midpoint reduction potential that was earlier measured for other reactions involving ACS. Incubation of ACS with Fd-II and CO leads to the formation of the NiFeC species, which also supports the role of Fd-II as a reductant for ACS. In addition to being a reductant, Fd-II can accept electrons from acetylated ACS, as observed by the increased intensity of the EPR spectrum of reduced Fd-II, indicating that there is a stored electron within an "electron shuttle" in the acetyl-Ni(II) form of ACS. This "shuttle" is proposed to serve as a redox mediator during activation and at different steps of the ACS catalytic cycle.     

Function of the tunnel in acetylcoenzyme A synthase/carbon monoxide dehydrogenase

Acetylcoenzyme A synthase/carbon monoxide dehydrogenase (ACS/CODH) contains two Ni–Fe–S active-site clusters (called A and C) connected by a tunnel through which CO and CO₂ migrate. Site-directed mutants A578C, L215F, and A219F were designed to block the tunnel at different points along the region between the two C-clusters. Two other mutant proteins F70W and N101Q were designed to block the region that connects the tunnel at the ββ interface with a water channel also located at that interface. Purified mutant proteins were assayed for Ni/Fe content and examined by electron paramagnetic resonance spectroscopy. Analyses indicate that same metal clusters found in wild-type (WT) ACS/CODH (i.e., the A-, B-, C-, and probably D-clusters) are properly assembled in the mutant enzymes. Stopped-flow kinetics revealed that these centers in the mutants are rapidly reducible by dithionite but are only slowly reducible by CO, suggesting an impaired ability of CO to migrate through the tunnel to the C-cluster. Relative to the WT enzyme, mutant proteins exhibited little CODH or ACS activity (using CO₂ as a substrate). Some ACS activity was observed when CO was a substrate, but not the cooperative CO inhibition effect characteristic of WT ACS/CODH. These results suggest that CO and CO₂ enter and exit the enzyme at the water channel along the ββ subunit interface. They also suggest two pathways for CO during synthesis of acetylcoenzyme A, including one in which CO enters the enzyme and migrates through the tunnel before binding at the A-cluster, and another in which CO binds the A-cluster directly from the solvent.     

Tridentate N(2)S ligand from 2,2'-dithiodibenzaldehyde and N,N-dimethylethylenediamine: Synthesis, structure, and characterization of a Ni(II) complex with relevance to Ni Superoxide Dismutase

Nickel Superoxide Dismutase (NiSOD) and the A-cluster of Carbon Monoxide Dehydrogenase/Acetyl Coenzyme A Synthase (CODH/ACS) both feature active sites with Ni coordinated by thiolate and amide donors. It is likely that the particular set of donors is important in tuning the redox potential of the Ni center(s). We report herein an expansion of our efforts involving the use of 2,2′-dithiodibenzaldehyde (DTDB) as a synthon for metal-thiolate complexes to reactions with Ni complexes of N,N-dimethylethylenediamine (dmen). In the presence of coordinating counterions, these reactions result in monomeric square-planar complexes of the tridentate N₂S donor ligand derived from the Schiff-base condensation of dmen and DTDB. In the absence of a coordinating counterion, we have isolated a Ni(II) complex with an asymmetric N₂S₂ donor set involving one amine and one imine N donor in addition to two thiolate donors. This latter complex is discussed with respect to its relevance to the active site of NiSOD.     

Xenon in and at the end of the tunnel of bifunctional carbon monoxide dehydrogenase/acetyl-CoA synthase

A fascinating feature of some bifunctional enzymes is the presence of an internal channel or tunnel to connect the multiple active sites. A channel can allow for a reaction intermediate generated at one active site to be used as a substrate at a second active site, without the need for the intermediate to leave the safety of the protein matrix. One such bifunctional enzyme is carbon monoxide dehydrogenase/acetyl-CoA synthase from Moorella thermoacetica (mtCODH/ACS). A key player in the global carbon cycle, CODH/ACS uses a Ni-Fe-S center called the C-cluster to reduce carbon dioxide to carbon monoxide and uses a second Ni-Fe-S center, called the A-cluster, to assemble acetyl-CoA from a methyl group, coenzyme A, and C-cluster-generated CO. mtCODH/ACS has been proposed to contain one of the longest enzyme channels (138 A long) to allow for intermolecular CO transport. Here, we report a 2.5 A resolution structure of xenon-pressurized mtCODH/ACS and examine the nature of gaseous cavities within this enzyme. We find that the cavity calculation program CAVENV accurately predicts the channels connecting the C- and A-clusters, with 17 of 19 xenon binding sites within the predicted regions. Using this X-ray data, we analyze the amino acid composition surrounding the 19 Xe sites and consider how the protein fold is utilized to carve out such an impressive interior passageway. Finally, structural comparisons of Xe-pressurized mtCODH/ACS with related enzyme structures allow us to study channel design principles, as well as consider the conformational flexibility of an enzyme that contains a cavity through its center.     

A novel binuclear [CuSMo] cluster at the active site of carbon monoxide dehydrogenase: characterization by X-ray absorption spectroscopy

The structurally characterized molybdoenzyme carbon monoxide dehydrogenase (CODH) catalyzes the oxidation of CO to CO2 in the aerobic bacterium Oligotropha carboxidovorans. The active site of the enzyme was studied by Mo- and Cu-K-edge X-ray absorption spectroscopy. This revealed a bimetallic [Cu(I)SMo(VI)(double bond O)2] cluster in oxidized CODH which was converted into a [Cu(I)SMo(IV)(double bond O)OH2] cluster upon reduction. The Cu...Mo distance is 3.70 A in the oxidized form and is increased to 4.23 A upon reduction. The bacteria contain CODH species with the complete and functional bimetallic cluster along with enzyme species deficient in Cu and/or bridging S. The latter are precursors in the posttranslational biosynthesis of the metal cluster. Cu-deficient CODH is the most prominent precursor and contains a [HSMo(double bond O)OH2] cluster. Se-K-edge X-ray absorption spectroscopy demonstrates that Se is coordinated by two C atoms at 1.94-1.95 A distance. This is interpreted as a replacement of the S in methionine residues. In contrast to a previous report [Dobbek, H., Gremer, L., Meyer, O., and Huber, R. (1999) Proc. Natl. Acad. Sci. U.S.A. 96, 8884-8889] Se was not identified in the active site of CODH.     

Converting the NiFeS carbon monoxide dehydrogenase to a hydrogenase and a hydroxylamine reductase

Substitution of one amino acid for another at the active site of an enzyme usually diminishes or eliminates the activity of the enzyme. In some cases, however, the specificity of the enzyme is changed. In this study, we report that the changing of a metal ligand at the active site of the NiFeS-containing carbon monoxide dehydrogenase (CODH) converts the enzyme to a hydrogenase or a hydroxylamine reductase. CODH with alanine substituted for Cys(531) exhibits substantial uptake hydrogenase activity, and this activity is enhanced by treatment with CO. CODH with valine substituted for His(265) exhibits hydroxylamine reductase activity. Both Cys(531) and His(265) are ligands to the active-site cluster of CODH. Further, CODH with Fe substituted for Ni at the active site acquires hydroxylamine reductase activity.     

Spectroscopic studies of nickel-deficient carbon monoxide dehydrogenase from Rhodospirillum rubrum: nature of the iron-sulfur clusters

Carbon monoxide dehydrogenase (CODH) from Rhodospirillum rubrum utilizes three types of Fe-S clusters to catalyze the reversible oxidation of CO to CO(2): a novel [Ni4Fe5S] active site (C cluster) and two distinct [4Fe4S] electron-transfer sites (B and D clusters). While recent X-ray data show the geometric arrangement of the five metal centers at the C cluster, electronic structures of the various [Ni4Fe5S] oxidation states remain ambiguous. These studies report magnetic circular dichroism (MCD), variable temperature, variable field MCD (VTVH MCD), and resonance Raman (rR) spectroscopic properties of the Fe-S clusters contained in Ni-deficient CODH. Essentially homogeneous sample preparations aided in the resolution of the reduced [4Fe4S](1+) (S = (1)/(2)) B cluster and the reduced Ni-deficient C cluster (denoted C, S > (1)/(2)) by MCD. The three Fe atoms derived from the [Ni3Fe4S] cubane component appear to dominate the reduced C cluster MCD spectrum, while the presence of a fourth Fe center can be inferred from the ground state spin. The same underlying MCD features present in Ni-deficient CODH spectra are also observed for Ni-containing CODH, suggesting that both proteins contain the same C cluster Fe-S component. Overlooked in all spectroscopic studies to date, the D cluster was confirmed by rR to be a typical [4Fe4S] site with cysteinyl coordination. Together, MCD and rR data show that the D cluster remains in the oxidized [4Fe4S](2+) (S = 0) state at potentials > or = -530 mV (versus SHE), thus exhibiting an unusually low redox potential for a standard [4Fe4S](2+/1+) electron-transfer site.     

The effect of intracellular molybdenum in Hydrogenophaga pseudoflava on the crystallographic structure of the seleno-molybdo-iron-sulfur flavoenzyme carbon monoxide dehydrogenase

Crystal structures of carbon monoxide dehydrogenase (CODH), a seleno-molybdo-iron-sulfur flavoprotein from the aerobic carbon monoxide utilizing carboxidotrophic eubacterium Hydrogenophaga pseudoflava, have been determined from the enzyme synthesized at high (Mo(plus) CODH) and low intracellular molybdenum content (Mo(minus) CODH) at 2.25 A and 2.35 A resolution, respectively. The structures were solved by Patterson search methods utilizing the enzyme from Oligotropha carboxidovorans as the initial model. The CODHs from both sources are structurally very much conserved and show the same overall fold, architecture and arrangements of the molybdopterin-cytosine dinucleotide-type of molybdenum cofactor, the type I and type II [2Fe-2S] clusters and the flavin-adenine dinucleotide. Unlike the CODH from O. carboxidovorans, the enzyme from H. pseudoflava reveals a unique post-translationally modified C(gamma)-hydroxy-Arg384 residue which precedes the catalytically essential S-selanyl-Cys385 in the active-site loop. In addition, the Trp193 which shields the isoalloxazine ring of the flavin-adenine dinucleotide in the M subunit of the H. pseudoflava CODH is a Tyr193 in the O. carboxidovorans CODH. The hydrogen bonding interaction pattern of the molybdenum cofactor involves 27 hydrogen bonds with the surrounding protein. Of these, eight are with the cytosine moiety, eight with the pyrophosphate, six with the pyranopterin, and five with the ligands of the Mo ion. The structure of the catalytically inactive Mo(minus) CODH indicates that an intracellular Mo-deficiency affects exclusively the active site of the enzyme as an incomplete non-functional molybdenum cofactor was synthesized. The 5'-CDP residue was present in Mo(minus) CODH, whereas the Mo-pyranopterin moiety was absent. In Mo(plus) CODH the selenium faces the Mo ion and flips away from the Mo site in Mo(minus) CODH. The different side-chain conformations of the active-site residues S-selanyl-Cys385 and Glu757 in Mo(plus) and Mo(minus) CODH indicate a side-chain flexibility and a function of the Mo ion in the proper orientation of both residues.     

Redox, haem and CO in enzymatic catalysis and regulation

The present paper describes general principles of redox catalysis and redox regulation in two diverse systems. The first is microbial metabolism of CO by the Wood-Ljungdahl pathway, which involves the conversion of CO or H2/CO2 into acetyl-CoA, which then serves as a source of ATP and cell carbon. The focus is on two enzymes that make and utilize CO, CODH (carbon monoxide dehydrogenase) and ACS (acetyl-CoA synthase). In this pathway, CODH converts CO2 into CO and ACS generates acetyl-CoA in a reaction involving Ni·CO, methyl-Ni and acetyl-Ni as catalytic intermediates. A 70 ? (1 ?=0.1?nm) channel guides CO, generated at the active site of CODH, to a CO 'cage' near the ACS active site to sequester this reactive species and assure its rapid availability to participate in a kinetically coupled reaction with an unstable Ni(I) state that was recently trapped by photolytic, rapid kinetic and spectroscopic studies. The present paper also describes studies of two haem-regulated systems that involve a principle of metabolic regulation interlinking redox, haem and CO. Recent studies with HO2 (haem oxygenase-2), a K+ ion channel (the BK channel) and a nuclear receptor (Rev-Erb) demonstrate that this mode of regulation involves a thiol-disulfide redox switch that regulates haem binding and that gas signalling molecules (CO and NO) modulate the effect of haem.     

Low spin quantitation of NiFeC EPR signal from carbon monoxide dehydrogenase is not due to damage incurred during protein purification

Evidence is presented that the O₂-sensitive, nickel- and iron-containing enzyme carbon monoxide dehydrogenase from Clostridium thermoaceticum was purified without significantly inactivating either its CO oxidation or CO/acetyl-CoA exchange activities. All CO oxidation activity from the crude extract was recovered in the purified enzyme (and side fractions). The exchange activity could not be quantified similarly, because the crude extract and early purification step fractions exhibited little or no exchange activity. Later purification fractions exhibited much more exchange activity, suggesting that an inhibitor was present in the impure fractions. The NiFeC EPR signal intensity was used as an indicator of the enzyme's capacity to catalyze exchange. This signal was extremely sensitive to oxygen; exposure to as little as 0.5 equiv/mol enzyme dimer resulted in substantial loss of intensity. The NiFeC intensities at each step in the purification were virtually invariant, indicating that the enzyme had not been exposed to oxygen and had not been inactivated towards catalyzing exchange. The ability to purify carbon monoxide dehydrogenase (CODH) without inactivating nearly any of the molecules suggests that it is quite stable under anaerobic conditions. The purified enzyme, which could not have lost functional metal ions during purification, contained 1.9 Ni and 11.3 Fe, similar to previous reports. The NiFeC EPR signal intensity from each purification fraction (0.2 spins/mol enzyme dimer) was as low as from previous preparations, indicating that its low spin quantitation is not the result of damage incurred during purification. If the low intensity arises from heterogeneity as proposed earlier, the heterogeneity must originate prior to purification.     

Two membrane-associated NiFeS-carbon monoxide dehydrogenases from the anaerobic carbon-monoxide-utilizing eubacterium Carboxydothermus hydrogenoformans

Two monofunctional NiFeS carbon monoxide (CO) dehydrogenases, designated CODH I and CODH II, were purified to homogeneity from the anaerobic CO-utilizing eubacterium Carboxydothermus hydrogenoformans. Both enzymes differ in their subunit molecular masses, N-terminal sequences, peptide maps, and immunological reactivities. Immunogold labeling of ultrathin sections revealed both CODHs in association with the inner aspect of the cytoplasmic membrane. Both enzymes catalyze the reaction CO + H(2)O --> CO(2) + 2 e(-) + 2 H(+). Oxidized viologen dyes are effective electron acceptors. The specific enzyme activities were 15,756 (CODH I) and 13,828 (CODH II) micromol of CO oxidized min(-1) mg(-1) of protein (methyl viologen, pH 8.0, 70 degrees C). The two enzymes oxidize CO very efficiently, as indicated by k(cat)/K(m) values at 70 degrees C of 1.3. 10(9) M(-1) CO s(-1) (CODH I) and 1.7. 10(9) M(-1) CO s(-1) (CODH II). The apparent K(m) values at pH 8.0 and 70 degrees C are 30 and 18 microM CO for CODH I and CODH II, respectively. Acetyl coenzyme A synthase activity is not associated with the enzymes. CODH I (125 kDa, 62.5-kDa subunit) and CODH II (129 kDa, 64.5-kDa subunit) are homodimers containing 1.3 to 1.4 and 1.7 atoms of Ni, 20 to 22 and 20 to 24 atoms of Fe, and 22 and 19 atoms of acid-labile sulfur, respectively. Electron paramagnetic resonance (EPR) spectroscopy revealed signals indicative of [4Fe-4S] clusters. Ni was EPR silent under any conditions tested. It is proposed that CODH I is involved in energy generation and that CODH II serves in anabolic functions.     

New insights into the mechanism of nickel insertion into carbon monoxide dehydrogenase: analysis of Rhodospirillum rubrum carbon monoxide dehydrogenase variants with substituted ligands to the [Fe3S4] portion of the active-site C-cluster

Carbon monoxide dehydrogenase (CODH) from Rhodospirillum rubrum catalyzes the oxidation of CO to CO₂. A unique [NiFe₄S₄] cluster, known as the C-cluster, constitutes the active site of the enzyme. When grown in Ni-deficient medium R. rubrum accumulates a Ni-deficient apo form of CODH that is readily activated by Ni. It has been previously shown that activation of apo-CODH by Ni is a two-step process involving the rapid formation of an inactive apo-CODH•Ni complex prior to conversion to the active holo-CODH. We have generated CODH variants with substitutions in cysteine residues involved in the coordination of the [Fe₃S₄] portion of the C-cluster. Analysis of the variants suggests that the cysteine residues at positions 338, 451, and 481 are important for CO oxidation activity catalyzed by CODH but not for Ni binding to the C-cluster. C451S CODH is the only new variant that retains residual CO oxidation activity. Comparison of the kinetics and pH dependence of Ni activation of the apo forms of wild-type, C451S, and C531A CODH allowed us to develop a model for Ni insertion into the C-cluster of CODH in which Ni reversibly binds to the C-cluster and subsequently coordinates Cys531 in the rate-determining step.     

Characterization of the cofactor composition of Escherichia coli biotin synthase

The cofactor content of in vivo, as-isolated, and reconstituted forms of recombinant Escherichia coli biotin synthase (BioB) has been investigated using the combination of UV-visible absorption, resonance Raman, and M?ssbauer spectroscopies along with parallel analytical and activity assays. In contrast to the recent report that E. coli BioB is a pyridoxal phosphate (PLP)-dependent enzyme with intrinsic cysteine desulfurase activity (Ollagnier-deChoudens, S., Mulliez, E., Hewitson, K. S., and Fontecave, M. (2002) Biochemistry 41, 9145-9152), no evidence for PLP binding or for PLP-induced cysteine desulfurase or biotin synthase activity was observed with any of the forms of BioB investigated in this work. The results confirm that BioB contains two distinct Fe-S cluster binding sites. One site accommodates a [2Fe-2S](2+) cluster with partial noncysteinyl ligation that can only be reconstituted in vitro in the presence of O(2). The other site accommodates a [4Fe-4S](2+,+) cluster that binds S-adenosylmethionine (SAM) at a unique Fe site of the [4Fe-4S](2+) cluster and undergoes O(2)-induced degradation via a distinct type of [2Fe-2S](2+) cluster intermediate. In vivo M?ssbauer studies show that recombinant BioB in anaerobically grown cells is expressed exclusively in an inactive form containing only the as-isolated [2Fe-2S](2+) cluster and demonstrate that the [2Fe-2S](2+) cluster is not a consequence of overexpressing the recombinant enzyme under aerobic growth conditions. Overall the results clarify the confusion in the literature concerning the Fe-S cluster composition and the in vitro reconstitution and O(2)-induced cluster transformations that are possible for recombinant BioB. In addition, they provide a firm foundation for assessing cluster transformations that occur during turnover and the catalytic competence of the [2Fe-2S](2+) cluster as the immediate S-donor for biotin biosynthesis.     

The anaerobic ribonucleotide reductase from Escherichia coli. The small protein is an activating enzyme containing a [4fe-4s](2+) center.

For deoxyribonucleotide synthesis during anaerobic growth, Escherichia coli cells depend on an oxygen-sensitive class III ribonucleotide reductase. The enzyme system consists of two proteins: protein alpha, on which ribonucleotides bind and are reduced, and protein beta, of which the function is to introduce a catalytically essential glycyl radical on protein alpha. Protein beta can assemble one [4Fe-4S] center per polypeptide enjoying both the [4Fe-4S](2+) and [4Fe-4S](1+) redox state, as shown by iron and sulfide analysis, M?ssbauer spectroscopy (delta = 0.43 mm.s(-1), DeltaE(Q) = 1.0 mm.s(-1), [4Fe-4S](2+)), and EPR spectroscopy (g = 2. 03 and 1.93, [4Fe-4S](1+)). This iron center is sensitive to oxygen and can decompose into stable [2Fe-2S](2+) centers during exposure to air. This degraded form is nevertheless active, albeit to a lesser extent because of the conversion of the cluster into [4Fe-4S] forms during the strongly reductive conditions of the assay. Furthermore, protein beta has the potential to activate several molecules of protein alpha, suggesting that protein beta is an activating enzyme rather than a component of an alpha(2)beta(2) complex as previously claimed.     

Acetyl-coenzyme A synthase: the case for a Ni<Subscript>p</Subscript><Superscript>0</Superscript>-based mechanism of catalysis

Acetyl-CoA synthase (also known as carbon monoxide dehydrogenase) is a bifunctional Ni-Fe-S-containing enzyme that catalyzes the reversible reduction of CO₂ to CO and the synthesis of acetyl-coenzyme A from CO, CoA, and a methyl group donated by a corrinoid iron-sulfur protein. The active site for the latter reaction, called the A-cluster, consists of an Fe₄S₄ cubane bridged to the proximal Ni site (Ni_p), which is bridged in turn to the so-called distal Ni site. In this review, evidence is presented that Ni_p achieves a zero-valent state at low potentials and during catalysis. Ni_p appears to be the metal to which CO and methyl groups bind and then react to form an acetyl-Ni_p intermediate. Methyl group binding requires reductive activation, where two electrons reduce some site on the A-cluster. The coordination environment of the distal Ni suggests that it could not be stabilized in redox states lower than 2+. The rate at which the [Fe₄S₄]²⁺ cubane is reduced is far slower than that at which reductive activation occurs, suggesting that the cubane is not the site of reduction. An intriguing possibility is that Ni_p²⁺ might be reduced to the zero-valent state. Reinforcing this idea are Ni-organometallic complexes in which the Ni exhibits analogous reactivity properties when reduced to the zero-valent state. A zero-valent Ni stabilized exclusively with biological ligands would be remarkable and unprecedented in biology.Electronic Supplementary Material Supplementary Material is available in the online version of this article at