The iron-sulfur center of biotin synthase: site-directed mutants

Discovery of a Biotin Synthase That Utilizes an Auxiliary 4Fe-5S Cluster for Sulfur Insertion

Biotin synthase (BioB) is a member of the Radical SAM superfamily of enzymes that catalyzes the terminal step of biotin (vitamin B7) biosynthesis, in which it inserts a sulfur atom in desthiobiotin to form a thiolane ring. How BioB accomplishes this difficult reaction has been the subject of much controversy, mainly around the source of the sulfur atom. However, it is now widely accepted that the sulfur atom inserted to form biotin stems from the sacrifice of the auxiliary 2Fe-2S cluster of BioB. Here, we bioinformatically explore the diversity of BioBs available in sequence databases and find an unexpected variation in the coordination of the auxiliary iron-sulfur cluster. After in vitro characterization, including the determination of biotin formation and representative crystal structures, we report a new type of BioB utilized by virtually all obligate anaerobic organisms. Instead of a 2Fe-2S cluster, this novel type of BioB utilizes an auxiliary 4Fe-5S cluster. Interestingly, this auxiliary 4Fe-5S cluster contains a ligated sulfide that we propose is used for biotin formation. We have termed this novel type of BioB, Type II BioB, with the E. coli 2Fe-2S cluster sacrificial BioB representing Type I. This surprisingly ubiquitous Type II BioB has implications for our understanding of the function and evolution of Fe-S clusters in enzyme catalysis, highlighting the difference in strategies between the anaerobic and aerobic world.

Iron-sulfur biology invades tRNA modification: the case of U34 sulfuration

Sulfuration of uridine 34 in the anticodon of tRNAs is conserved in the three domains of life, guaranteeing fidelity of protein translation. In eubacteria, it is catalyzed by MnmA-type enzymes, which were previously concluded not to depend on an iron-sulfur [Fe-S] cluster. However, we report here spectroscopic and iron/sulfur analysis, as well as in vitro catalytic assays and site-directed mutagenesis studies unambiguously showing that MnmA from Escherichia coli can bind a [4Fe-4S] cluster, which is essential for sulfuration of U34-tRNA. We propose that the cluster serves to bind and activate hydrosulfide for nucleophilic attack on the adenylated nucleoside. Intriguingly, we found that E. coli cells retain s2U34 biosynthesis in the ΔiscUA ΔsufABCDSE strain, lacking functional ISC and SUF [Fe-S] cluster assembly machineries, thus suggesting an original and yet undescribed way of maturation of MnmA. Moreover, we report genetic analysis showing the importance of MnmA for sustaining oxidative stress.

Ubiquinone Biosynthesis over the Entire O2 Range: Characterization of a Conserved O2-Independent Pathway

In order to colonize environments with large O₂ gradients or fluctuating O₂ levels, bacteria have developed metabolic responses that remain incompletely understood. Such adaptations have been recently linked to antibiotic resistance, virulence, and the capacity to develop in complex ecosystems like the microbiota. Here, we identify a novel pathway for the biosynthesis of ubiquinone, a molecule with a key role in cellular bioenergetics. We link three uncharacterized genes of Escherichia coli to this pathway and show that the pathway functions independently from O₂. In contrast, the long-described pathway for ubiquinone biosynthesis requires O₂ as a substrate. In fact, we find that many proteobacteria are equipped with the O₂-dependent and O₂-independent pathways, supporting that they are able to synthesize ubiquinone over the entire O₂ range. Overall, we propose that the novel O₂-independent pathway is part of the metabolic plasticity developed by proteobacteria to face various environmental O₂ levels.

Most bacteria can generate ATP by respiratory metabolism, in which electrons are shuttled from reduced substrates to terminal electron acceptors, via quinone molecules like ubiquinone. Dioxygen (O₂) is the terminal electron acceptor of aerobic respiration and serves as a co-substrate in the biosynthesis of ubiquinone. Here, we characterize a novel, O₂-independent pathway for the biosynthesis of ubiquinone. This pathway relies on three proteins, UbiT (YhbT), UbiU (YhbU), and UbiV (YhbV). UbiT contains an SCP2 lipid-binding domain and is likely an accessory factor of the biosynthetic pathway, while UbiU and UbiV (UbiU-UbiV) are involved in hydroxylation reactions and represent a novel class of O₂-independent hydroxylases. We demonstrate that UbiU-UbiV form a heterodimer, wherein each protein binds a 4Fe-4S cluster via conserved cysteines that are essential for activity. The UbiT, -U, and -V proteins are found in alpha-, beta-, and gammaproteobacterial clades, including several human pathogens, supporting the widespread distribution of a previously unrecognized capacity to synthesize ubiquinone in the absence of O₂. Together, the O₂-dependent and O₂-independent ubiquinone biosynthesis pathways contribute to optimizing bacterial metabolism over the entire O₂ range.

Discovery and characterization of a prevalent human gut bacterial enzyme sufficient for the inactivation of a family of plant toxins

Although the human gut microbiome plays a prominent role in xenobiotic transformation, most of the genes and enzymes responsible for this metabolism are unknown. Recently, we linked the two-gene 'cardiac glycoside reductase' (cgr) operon encoded by the gut Actinobacterium Eggerthella lenta to inactivation of the cardiac medication and plant natural product digoxin. Here, we compared the genomes of 25 E. lenta strains and close relatives, revealing an expanded 8-gene cgr-associated gene cluster present in all digoxin metabolizers and absent in non-metabolizers. Using heterologous expression and in vitro biochemical characterization, we discovered that a single flavin- and [4Fe-4S] cluster-dependent reductase, Cgr2, is sufficient for digoxin inactivation. Unexpectedly, Cgr2 displayed strict specificity for digoxin and other cardenolides. Quantification of cgr2 in gut microbiomes revealed that this gene is widespread and conserved in the human population. Together, these results demonstrate that human-associated gut bacteria maintain specialized enzymes that protect against ingested plant toxins.

The Role of Biotin in Bacterial Physiology and Virulence: a Novel Antibiotic Target for Mycobacterium tuberculosis

Biotin is an essential cofactor for enzymes present in key metabolic pathways such as fatty acid biosynthesis, replenishment of the tricarboxylic acid cycle, and amino acid metabolism. Biotin is synthesized de novo in microorganisms, plants, and fungi, but this metabolic activity is absent in mammals, making biotin biosynthesis an attractive target for antibiotic discovery. In particular, biotin biosynthesis plays important metabolic roles as the sole source of biotin in all stages of the Mycobacterium tuberculosis life cycle due to the lack of a transporter for scavenging exogenous biotin. Biotin is intimately associated with lipid synthesis where the products form key components of the mycobacterial cell membrane that are critical for bacterial survival and pathogenesis. In this review we discuss the central role of biotin in bacterial physiology and highlight studies that demonstrate the importance of its biosynthesis for virulence. The structural biology of the known biotin synthetic enzymes is described alongside studies using structure-guided design, phenotypic screening, and fragment-based approaches to drug discovery as routes to new antituberculosis agents.

Biotin and Lipoic Acid: Synthesis, Attachment, and Regulation

Two vitamins, biotin and lipoic acid, are essential in all three domains of life. Both coenzymes function only when covalently attached to key metabolic enzymes. There they act as "swinging arms" that shuttle intermediates between two active sites (= covalent substrate channeling) of key metabolic enzymes. Although biotin was discovered over 100 years ago and lipoic acid 60 years ago, it was not known how either coenzyme is made until recently. In Escherichia coli the synthetic pathways for both coenzymes have now been worked out for the first time. The late steps of biotin synthesis, those involved in assembling the fused rings, were well described biochemically years ago, although recent progress has been made on the BioB reaction, the last step of the pathway in which the biotin sulfur moiety is inserted. In contrast, the early steps of biotin synthesis, assembly of the fatty acid-like "arm" of biotin were unknown. It has now been demonstrated that the arm is made by using disguised substrates to gain entry into the fatty acid synthesis pathway followed by removal of the disguise when the proper chain length is attained. The BioC methyltransferase is responsible for introducing the disguise, and the BioH esterase is responsible for its removal. In contrast to biotin, which is attached to its cognate proteins as a finished molecule, lipoic acid is assembled on its cognate proteins. An octanoyl moiety is transferred from the octanoyl acyl carrier protein of fatty acid synthesis to a specific lysine residue of a cognate protein by the LipB octanoyltransferase followed by sulfur insertion at carbons C-6 and C-8 by the LipA lipoyl synthetase. Assembly on the cognate proteins regulates the amount of lipoic acid synthesized, and, thus, there is no transcriptional control of the synthetic genes. In contrast, transcriptional control of the biotin synthetic genes is wielded by a remarkably sophisticated, yet simple, system, exerted through BirA, a dual-function protein that both represses biotin operon transcription and ligates biotin to its cognate proteins.

Biotin and Lipoic Acid: Synthesis, Attachment, and Regulation

Two vitamins, biotin and lipoic acid, are essential in all three domains of life. Both coenzymes function only when covalently attached to key metabolic enzymes. There they act as "swinging arms" that shuttle intermediates between two active sites (= covalent substrate channeling) of key metabolic enzymes. Although biotin was discovered over 100 years ago and lipoic acid was discovered 60 years ago, it was not known how either coenzyme is made until recently. In Escherichia coli the synthetic pathways for both coenzymes have now been worked out for the first time. The late steps of biotin synthesis, those involved in assembling the fused rings, were well described biochemically years ago, although recent progress has been made on the BioB reaction, the last step of the pathway, in which the biotin sulfur moiety is inserted. In contrast, the early steps of biotin synthesis, assembly of the fatty acid-like "arm" of biotin, were unknown. It has now been demonstrated that the arm is made by using disguised substrates to gain entry into the fatty acid synthesis pathway followed by removal of the disguise when the proper chain length is attained. The BioC methyltransferase is responsible for introducing the disguise and the BioH esterase for its removal. In contrast to biotin, which is attached to its cognate proteins as a finished molecule, lipoic acid is assembled on its cognate proteins. An octanoyl moiety is transferred from the octanoyl-ACP of fatty acid synthesis to a specific lysine residue of a cognate protein by the LipB octanoyl transferase, followed by sulfur insertion at carbons C6 and C8 by the LipA lipoyl synthetase. Assembly on the cognate proteins regulates the amount of lipoic acid synthesized, and thus there is no transcriptional control of the synthetic genes. In contrast, transcriptional control of the biotin synthetic genes is wielded by a remarkably sophisticated, yet simple, system exerted through BirA, a dual-function protein that both represses biotin operon transcription and ligates biotin to its cognate protein.

Substrate-induced radical formation in 4-hydroxybutyryl coenzyme A dehydratase from Clostridium aminobutyricum

4-Hydroxybutyryl-coenzyme A (CoA) dehydratase (4HBD) from Clostridium aminobutyricum catalyzes the reversible dehydration of 4-hydroxybutyryl-CoA to crotonyl-CoA and the irreversible isomerization of vinylacetyl-CoA to crotonyl-CoA. 4HBD is an oxygen-sensitive homotetrameric enzyme with one [4Fe-4S](2+) cluster and one flavin adenine dinucleotide (FAD) in each subunit. Upon the addition of crotonyl-CoA or the analogues butyryl-CoA, acetyl-CoA, and CoA, UV-visible light and electron paramagnetic resonance (EPR) spectroscopy revealed an internal one-electron transfer to FAD and the [4Fe-4S](2+) cluster prior to hydration. We describe an active recombinant 4HBD and variants produced in Escherichia coli. The variants of the cluster ligands (H292C [histidine at position 292 is replaced by cysteine], H292E, C99A, C103A, and C299A) had no measurable dehydratase activity and were composed of monomers, dimers, and tetramers. Variants of other potential catalytic residues were composed only of tetramers and exhibited either no measurable (E257Q, E455Q, and Y296W) hydratase activity or <1% (Y296F and T190V) dehydratase activity. The E455Q variant but not the Y296F or E257Q variant displayed the same spectral changes as the wild-type enzyme after the addition of crotonyl-CoA but at a much lower rate. The results suggest that upon the addition of a substrate, Y296 is deprotonated by E455 and reduces FAD to FADH·, aided by protonation from E257 via T190. In contrast to FADH·, the tyrosyl radical could not be detected by EPR spectroscopy. FADH· appears to initiate the radical dehydration via an allylic ketyl radical that was proposed 19 years ago. The mode of radical generation in 4HBD is without precedent in anaerobic radical chemistry. It differs largely from that in enzymes, which use coenzyme B12, S-adenosylmethionine, ATP-driven electron transfer, or flavin-based electron bifurcation for this purpose.

Biotin synthase: insights into radical-mediated carbon-sulfur bond formation

The enzyme cofactor and essential vitamin biotin is biosynthesized in bacteria, fungi, and plants through a pathway that culminates with the addition of a sulfur atom to generate the five-membered thiophane ring. The immediate precursor, dethiobiotin, has methylene and methyl groups at the C6 and C9 positions, respectively, and formation of a thioether bridging these carbon atoms requires cleavage of unactivated CH bonds. Biotin synthase is an S-adenosyl-l-methionine (SAM or AdoMet) radical enzyme that catalyzes reduction of the AdoMet sulfonium to produce 5'-deoxyadenosyl radicals, high-energy carbon radicals that can directly abstract hydrogen atoms from dethiobiotin. The available experimental and structural data suggest that a [2Fe-2S](2+) cluster bound deep within biotin synthase provides a sulfur atom that is added to dethiobiotin in a stepwise reaction, first at the C9 position to generate 9-mercaptodethiobiotin, and then at the C6 position to close the thiophane ring. The formation of sulfur-containing biomolecules through a radical reaction involving an iron-sulfur cluster is an unprecedented reaction in biochemistry; however, recent enzyme discoveries suggest that radical sulfur insertion reactions may be a distinct subgroup within the burgeoning Radical SAM superfamily. This article is part of a Special Issue entitled: Radical SAM enzymes and Radical Enzymology.

Reduction of the [2Fe-2S] cluster accompanies formation of the intermediate 9-mercaptodethiobiotin in Escherichia coli biotin synthase

Biotin synthase catalyzes the conversion of dethiobiotin (DTB) to biotin through the oxidative addition of sulfur between two saturated carbon atoms, generating a thiophane ring fused to the existing ureido ring. Biotin synthase is a member of the radical SAM superfamily, composed of enzymes that reductively cleave S-adenosyl-l-methionine (SAM or AdoMet) to generate a 5'-deoxyadenosyl radical that can abstract unactivated hydrogen atoms from a variety of organic substrates. In biotin synthase, abstraction of a hydrogen atom from the C9 methyl group of DTB would result in formation of a dethiobiotinyl methylene carbon radical, which is then quenched by a sulfur atom to form a new carbon-sulfur bond in the intermediate 9-mercaptodethiobiotin (MDTB). We have proposed that this sulfur atom is the μ-sulfide of a [2Fe-2S](2+) cluster found near DTB in the enzyme active site. In the present work, we show that formation of MDTB is accompanied by stoichiometric generation of a paramagnetic FeS cluster. The electron paramagnetic resonance (EPR) spectrum is modeled as a 2:1 mixture of components attributable to different forms of a [2Fe-2S](+) cluster, possibly distinguished by slightly different coordination environments. Mutation of Arg260, one of the ligands to the [2Fe-2S] cluster, causes a distinctive change in the EPR spectrum. Furthermore, magnetic coupling of the unpaired electron with (14)N from Arg260, detectable by electron spin envelope modulation (ESEEM) spectroscopy, is observed in WT enzyme but not in the Arg260Met mutant enzyme. Both results indicate that the paramagnetic FeS cluster formed during catalytic turnover is a [2Fe-2S](+) cluster, consistent with a mechanism in which the [2Fe-2S](2+) cluster simultaneously provides and oxidizes sulfide during carbon-sulfur bond formation.

Self-sacrifice in radical S-adenosylmethionine proteins

The radical SAM superfamily of metalloproteins catalyze the reductive cleavage of S-adenosyl-l-methionine to generate a 5'-deoxyadenosyl radical (5'-dA*) intermediate that is obligate for turnover. The 5'-dA* acts as a potent oxidant, initiating turnover by abstracting a hydrogen atom from an appropriate substrate. A special class of these enzymes use this strategy to functionalize unactivated C-H bonds by insertion of sulfur atoms. This review will describe the characterization of three members of this class - biotin synthase, lipoyl synthase, and MiaB protein - each of which has been shown to cannibalize itself during turnover.

Electron paramagnetic resonance and Mössbauer spectroscopy of intact mitochondria from respiring Saccharomyces cerevisiae

Mitochondria from respiring cells were isolated under anaerobic conditions. Microscopic images were largely devoid of contaminants, and samples consumed O(2) in an NADH-dependent manner. Protein and metal concentrations of packed mitochondria were determined, as was the percentage of external void volume. Samples were similarly packed into electron paramagnetic resonance tubes, either in the as-isolated state or after exposure to various reagents. Analyses revealed two signals originating from species that could be removed by chelation, including rhombic Fe(3+) (g = 4.3) and aqueous Mn(2+) ions (g = 2.00 with Mn-based hyperfine). Three S = 5/2 signals from Fe(3+) hemes were observed, probably arising from cytochrome c peroxidase and the a(3):Cu(b) site of cytochrome c oxidase. Three Fe/S-based signals were observed, with averaged g values of 1.94, 1.90 and 2.01. These probably arise, respectively, from the [Fe(2)S(2)](+) cluster of succinate dehydrogenase, the [Fe(2)S(2)](+) cluster of the Rieske protein of cytochrome bc (1), and the [Fe(3)S(4)](+) cluster of aconitase, homoaconitase or succinate dehydrogenase. Also observed was a low-intensity isotropic g = 2.00 signal arising from organic-based radicals, and a broad signal with g (ave) = 2.02. Mössbauer spectra of intact mitochondria were dominated by signals from Fe(4)S(4) clusters (60-85% of Fe). The major feature in as-isolated samples, and in samples treated with ethylenebis(oxyethylenenitrilo)tetraacetic acid, dithionite or O(2), was a quadrupole doublet with DeltaE (Q) = 1.15 mm/s and delta = 0.45 mm/s, assigned to [Fe(4)S(4)](2+) clusters. Substantial high-spin non-heme Fe(2+) (up to 20%) and Fe(3+) (up to 15%) species were observed. The distribution of Fe was qualitatively similar to that suggested by the mitochondrial proteome.

The ISC [corrected] proteins Isa1 and Isa2 are required for the function but not for the de novo synthesis of the Fe/S clusters of biotin synthase in Saccharomyces cerevisiae

The yeast Saccharomyces cerevisiae is able to use some biotin precursors for biotin biosynthesis. Insertion of a sulfur atom into desthiobiotin, the final step in the biosynthetic pathway, is catalyzed by biotin synthase (Bio2). This mitochondrial protein contains two iron-sulfur (Fe/S) clusters that catalyze the reaction and are thought to act as a sulfur donor. To identify new components of biotin metabolism, we performed a genetic screen and found that Isa2, a mitochondrial protein involved in the formation of Fe/S proteins, is necessary for the conversion of desthiobiotin to biotin. Depletion of Isa2 or the related Isa1, however, did not prevent the de novo synthesis of any of the two Fe/S centers of Bio2. In contrast, Fe/S cluster assembly on Bio2 strongly depended on the Isu1 and Isu2 proteins. Both isa mutants contained low levels of Bio2. This phenotype was also found in other mutants impaired in mitochondrial Fe/S protein assembly and in wild-type cells grown under iron limitation. Low Bio2 levels, however, did not cause the inability of isa mutants to utilize desthiobiotin, since this defect was not cured by overexpression of BIO2. Thus, the Isa proteins are crucial for the in vivo function of biotin synthase but not for the de novo synthesis of its Fe/S clusters. Our data demonstrate that the Isa proteins are essential for the catalytic activity of Bio2 in vivo.

Role of the [2Fe-2S]2+ cluster in biotin synthase: mutagenesis of the atypical metal ligand arginine 260

Biotin synthase (BS) is an S-adenosylmethionine (AdoMet)-dependent radical enzyme that catalyzes the addition of sulfur to dethiobiotin. Like other AdoMet radical enzymes, BS contains a [4Fe-4S] cluster that is coordinated by a highly conserved CxxxCxxC sequence motif and by the methionyl amine and carboxylate of AdoMet. The close association of the [4Fe-4S]+ cluster with AdoMet facilitates reductive cleavage of the sulfonium and the generation of transient 5'-deoxyadenosyl radicals, which are then proposed to sequentially abstract hydrogen atoms from the substrate to produce carbon radicals at C9 and C6 of dethiobiotin. BS also contains a [2Fe-2S]2+ cluster located approximately 4-5 A from dethiobiotin, and we have proposed that a bridging sulfide of this cluster quenches the substrate radicals, leading to formation of the thiophane ring of biotin. In BS from Escherichia coli, the [2Fe-2S]2+ cluster is coordinated by cysteines 97, 128, and 188, and the atypical metal ligand, arginine 260. The evolutionary conservation of an arginine guanidinium as a metal ligand suggests a novel role for this residue in tuning the reactivity or stability of the [2Fe-2S]2+ cluster. In this work, we explore the effects of mutagenesis of Arg260 to Ala, Cys, His, and Met. Although perturbations in a number of characteristics of the [2Fe-2S]2+ cluster and the proteins are noted, the reconstituted enzymes have in vitro single-turnover activities that are 30-120% of that of the wild type. Further, in vivo expression of each mutant enzyme was sufficient to sustain growth of a bioB- mutant strain on dethiobiotin-supplemented medium, suggesting the enzymes were active and efficiently reconstituted by the in vivo iron-sulfur cluster (ISC) assembly system. Although we cannot exclude an as-yet-unidentified in vivo role in cluster repair or retention, we can conclude that Arg260 is not essential for the catalytic reaction of BS.

Identification of structural and catalytic classes of highly conserved amino acid residues in lysine 2,3-aminomutase

Lysine 2,3-aminomutase (LAM) from Clostridium subterminale SB4 catalyzes the interconversion of (S)-lysine and (S)-beta-lysine by a radical mechanism involving coenzymatic actions of S-adenosylmethionine (SAM), a [4Fe-4S] cluster, and pyridoxal 5'-phosphate (PLP). The enzyme contains a number of conserved acidic residues and a cysteine- and arginine-rich motif, which binds iron and sulfide in the [4Fe-4S] cluster. The results of activity and iron, sulfide, and PLP analysis of variants resulting from site-specific mutations of the conserved acidic residues and the arginine residues in the iron-sulfide binding motif indicate two classes of conserved residues of each type. Mutation of the conserved residues Arg134, Asp293, and Asp330 abolishes all enzymatic activity. On the basis of the X-ray crystal structure, these residues bind the epsilon-aminium and alpha-carboxylate groups of (S)-lysine. However, among these residues, only Asp293 appears to be important for stabilizing the [4Fe-4S] cluster. Members of a second group of conserved residues appear to stabilize the structure of LAM. Mutations of arginine 130, 135, and 136 and acidic residues Glu86, Asp165, Glu236, and Asp172 dramatically decrease iron and sulfide contents in the purified variants. Mutation of Asp96 significantly decreases iron and sulfide content. Arg130 or Asp172 variants display no detectable activity, whereas variants mutated at the other positions display low to very low activities. Structural roles are assigned to this latter class of conserved amino acids. In particular, a network of hydrogen bonded interactions of Arg130, Glu86, Arg135, and the main chain carbonyl groups of Cys132 and Leu55 appears to stabilize the [4Fe-4S] cluster.

Enantiomeric free radicals and enzymatic control of stereochemistry in a radical mechanism: the case of lysine 2,3-aminomutases

The product of yjeK in Escherichia coli is a homologue of lysine 2,3-aminomutase (LAM) from Clostridium subterminale SB4, and both enzymes catalyze the isomerization of (S)- but not (R)-alpha-lysine by radical mechanisms. The turnover number for LAM from E. coli is 5.0 min(-1), 0.1% of the value for clostridial LAM. The reaction of E. coli LAM with (S)-alpha-[3,3,4,4,5,5,6,6-(2)H8]lysine proceeds with a kinetic isotope effect (kH/kD) of 1.4, suggesting that hydrogen transfer is not rate-limiting. The product of the E. coli enzyme is (R)-beta-lysine, the enantiomer of the clostridial product. Beta-lysine-related radicals are observed in the reactions of both enzymes by electron paramagnetic resonance (EPR). The radical in the reaction of clostridial LAM has the (S)-configuration, whereas that in the reaction of E. coli LAM has the (R)-configuration. Moreover, the conformations of the beta-lysine-related radicals at the active sites of E. coli and clostridial LAM are different. The nuclear hyperfine splitting between the C3 hydrogen and the unpaired electron at C2 shows the dihedral angle to be 6 degrees, unlike the value of 77 degrees reported for the analogous radical bound to the clostridial enzyme. Reaction of (S)-4-thialysine produces a substrate-related radical in the steady state of E. coli LAM, as in the action of the clostridial enzyme. While (S)-beta-lysine is not a substrate for E. coli LAM, it undergoes hydrogen abstraction to form an (S)-beta-lysine-related radical with the same stereochemistry of hydrogen transfer from C2 of (S)-beta-lysine to the 5'-deoxyadenosyl radical as in the action of the clostridial enzyme. The resulting beta-lysyl radical has a conformation different from that at the active site of clostridial LAM. All evidence indicates that the opposite stereochemistry displayed by E. coli LAM is determined by the conformation of the lysine side chain in the active site. Stereochemical models for the actions of LAM from C. subterminale and E. coli are presented.

Cofactor dependence of reduction potentials for [4Fe-4S]2+/1+ in lysine 2,3-aminomutase

Lysine 2,3-aminomutase (LAM) catalyzes the interconversion of l-lysine and l-beta-lysine by a free radical mechanism. The 5'-deoxyadenosyl radical derived from the reductive cleavage of S-adenosyl-l-methionine (SAM) initiates substrate-radical formation. The [4Fe-4S](1+) cluster in LAM is the one-electron source in the reductive cleavage of SAM, which is directly ligated to the unique iron site in the cluster. We here report the midpoint reduction potentials of the [4Fe-4S](2+/1+) couple in the presence of SAM, S-adenosyl-l-homocysteine (SAH), or 5'-{N-[(3S)-3-aminocarboxypropyl]-N-methylamino}-5'-deoxyadenosine (azaSAM) as measured by spectroelectrochemistry. The reduction potentials are -430 +/- 2 mV in the presence of SAM, -460 +/- 3 mV in the presence of SAH, and -497 +/- 10 mV in the presence of azaSAM. In the absence of SAM or an analogue and the presence of dithiothreitol, dihydrolipoate, or cysteine as ligands to the unique iron, the midpoint potentials are -479 +/- 5, -516 +/- 5, and -484 +/- 3 mV, respectively. LAM is a member of the radical SAM superfamily of enzymes, in which the CxxxCxxC motif donates three thiolate ligands to iron in the [4Fe-4S] cluster and SAM donates the alpha-amino and alpha-carboxylate groups of the methionyl moiety as ligands to the fourth iron. The results show the reduction potentials in the midrange for ferredoxin-like [4Fe-4S] clusters. They show that SAM elevates the reduction potential by 86 mV relative to that of dihydrolipoate as the cluster ligand. This difference accounts for the SAM-dependent reduction of the [4Fe-4S](2+) cluster by dithionite reported earlier. Analogues of SAM have a weakened capacity to raise the potential. We conclude that the midpoint reduction potential of the cluster ligated to SAM is 1.2 V less negative than the half-wave potential for the one-electron reductive cleavage of simple alkylsulfonium ions in aqueous solution. The energetic barrier in the reductive cleavage of SAM may be overcome through the use of binding energy.

Function, attachment and synthesis of lipoic acid in Escherichia coli

A series of genetic, biochemical, and physiological studies in Escherichia coli have elucidated the unusual pathway whereby lipoic acid is synthesized. Here we describe the results of these investigations as well as the functions of enzyme proteins that are modified by covalent attachment of lipoic acid and the enzymes that catalyze the modification reactions. Some aspects of the synthesis and attachment mechanisms have strong parallels in the pathways used in synthesis and attachment of biotin and these are compared and contrasted. Homologues of the lipoic acid metabolism proteins are found in all branches of life, save the Archea, and thus these findings seem to have wide biological relevance.

Radical S-Adenosylmethionine Enzyme Coproporphyrinogen III Oxidase HemN

The S-adenosylmethionine (AdoMet) radical enzyme oxygen-independent coproporphyrinogen III oxidase HemN catalyzes the oxidative decarboxylation of coproporphyrinogen III to protoporphyrinogen IX during bacterial heme biosynthesis. The recently solved crystal structure of Escherichia coli HemN revealed the presence of an unusually coordinated iron-sulfur cluster and two molecules of AdoMet. EPR spectroscopy of the reduced iron-sulfur center in anaerobically purified HemN in the absence of AdoMet has revealed a [4Fe-4S](1+) cluster in two slightly different conformations. Mössbauer spectroscopy of anaerobically purified HemN has identified a predominantly [4Fe-4S](2+) cluster in which only three iron atoms were coordinated by cysteine residues (isomer shift of delta = 0.43 (1) mm/s). The fourth non-cysteine-ligated iron exhibited a delta = 0.57 (3) mm/s, which shifted to a delta = 0.68 (3) mm/s upon addition of AdoMet. Substrate binding by HemN did not alter AdoMet coordination to the cluster. Multiple rounds of AdoMet cleavage with the formation of the reaction product methionine indicated AdoMet consumption during catalysis and identified AdoMet as a co-substrate for HemN catalysis. AdoMet cleavage was found to be dependent on the presence of the substrate coproporphyrinogen III. Two molecules of AdoMet were cleaved during one catalytic cycle for the formation of one molecule of protoporphyrinogen IX. Finally, the binding site for the unusual second, non iron-sulfur cluster coordinating AdoMet molecule (AdoMet2) was targeted using site-directed mutagenesis. All AdoMet2 binding site mutants still contained an iron-sulfur cluster and most still exhibited AdoMet cleavage, albeit reduced compared with the wild-type enzyme. However, all mutants lost their overall catalytic ability indicating a functional role for AdoMet2 in HemN catalysis. The reported significant correlation of structural and functional biophysical and biochemical data identifies HemN as a useful model system for the elucidation of general AdoMet radical enzyme features.

Further investigation on the turnover of Escherichia coli biotin synthase with dethiobiotin and 9-mercaptodethiobiotin as substrates

Biotin synthase, a member of the "radical-SAM" family, produces biotin by inserting a sulfur atom between C-6 and C-9 of dethiobiotin. Each of the two saturated carbon atoms is activated through homolytic cleavage of a C-H bond by a deoxyadenosyl radical, issued from the monoelectronic reduction of S-adenosylmethionine (SAM or AdoMet). An important unexplained observation is that the enzyme produces only 1 mol of biotin per enzyme monomer. Some possible reasons for this absence of multiple turnovers are considered here, in connection with the postulated mechanisms. There is a general agreement among several groups that the active form of biotin synthase contains one (4Fe-4S)(2+,1+) center, which mediates the electron transfer to AdoMet, and one (2Fe-2S)(2+) center, which is considered the sulfur source [Ugulava, N. B., Sacanell, C. J., and Jarrett, J. T. (2001) Biochemistry 40, 8352-8358; Tse Sum Bui, B., Benda, R., Schunemann, V., Florentin, D., Trautwein, A. X., and Marquet, A. (2003) Biochemistry 42, 8791-8798; Jameson, G. N. L., Cosper, M. M., Hernandez, H. L., Johnson, M. K., and Huynh, B. H. (2004) Biochemistry 43, 2022-2031]. An alternative hypothesis considers that biotin synthase has a pyridoxal phosphate (PLP)-dependent cysteine desulfurase activity, producing a persulfide which could be the sulfur donor. The absence of turnover was explained by the inhibition due to deoxyadenosine, an end product of the reaction [Ollagnier-de Choudens, S., Mulliez, E., and Fontecave, M. (2002) FEBS Lett. 535, 465-468]. In this work, we show that our purified enzyme has no cysteine desulfurase activity and the required sulfide has to be added as Na(2)S. It cannot be replaced by cysteine, and consistently, PLP has no effect. We observed that deoxyadenosine does not inhibit the reaction either. On the other hand, if the (2Fe-2S)(2+) center is the sulfur source, its depletion after reaction could explain the absence of turnover. We found that after addition of fresh cofactors, including Fe(2+) and S(2)(-), either to the assay when one turn is completed or after purification of the reacted enzyme by different techniques, only a small amount of biotin (0.3-0.4 equiv/monomer) is further produced. This proves that an active enzyme cannot be fully reconstituted after one turn. When 9-mercaptodethiobiotin, which already contains the sulfur atom of biotin, is used as the substrate, the same turnover of one is observed, with similar reaction rates. We postulate that the same intermediate involving the (2Fe-2S) cluster is formed from both substrates, with a rate-determining step following the formation of this intermediate.

Escherichia coli lipoyl synthase binds two distinct [4Fe-4S] clusters per polypeptide

Lipoyl synthase (LS) is a member of a recently established class of metalloenzymes that use S-adenosyl-l-methionine (SAM) as the precursor to a high-energy 5'-deoxyadenosyl 5'-radical (5'-dA(*)). In the LS reaction, the 5'-dA(*) is hypothesized to abstract hydrogen atoms from C-6 and C-8 of protein-bound octanoic acid with subsequent sulfur insertion, generating the lipoyl cofactor. Consistent with this premise, 2 equiv of SAM is required to synthesize 1 equiv of the lipoyl cofactor, and deuterium transfer from octanoyl-d(15) H-protein of the glycine cleavage system-one of the substrates for LS-has been reported [Cicchillo, R. M., Iwig, D. F., Jones, A. D., Nesbitt, N. M., Baleanu-Gogonea, C., Souder, M. G., Tu, L., and Booker, S. J. (2004) Biochemistry 43, 6378-6386]. However, the exact identity of the sulfur donor remains unknown. We report herein that LS from Escherichia coli can accommodate two [4Fe-4S] clusters per polypeptide and that this form of the enzyme is relevant to turnover. One cluster is ligated by the cysteine amino acids in the C-X(3)-C-X(2)-C motif that is common to all radical SAM enzymes, while the other is ligated by the cysteine amino acids residing in a C-X(4)-C-X(5)-C motif, which is conserved only in lipoyl synthases. When expressed in the presence of a plasmid that harbors an Azotobacter vinelandii isc operon, which is involved in Fe/S cluster biosynthesis, the as-isolated wild-type enzyme contained 6.9 +/- 0.5 irons and 6.4 +/- 0.9 sulfides per polypeptide and catalyzed formation of 0.60 equiv of 5'-deoxyadenosine (5'-dA) and 0.27 equiv of lipoylated H-protein per polypeptide. The C68A-C73A-C79A triple variant, expressed and isolated under identical conditions, contained 3.0 +/- 0.1 irons and 3.6 +/- 0.4 sulfides per polypeptide, while the C94A-C98A-C101A triple variant contained 4.2 +/- 0.1 irons and 4.7 +/- 0.8 sulfides per polypeptide. Neither of these variant proteins catalyzed formation of 5'-dA or the lipoyl group. Mössbauer spectroscopy of the as-isolated wild-type protein and the two triple variants indicates that greater than 90% of all associated iron is in the configuration [4Fe-4S](2+). When wild-type LS was reconstituted with (57)Fe and sodium sulfide, it harbored considerably more iron (13.8 +/- 0.6) and sulfide (13.1 +/- 0.2) per polypeptide and catalyzed formation of 0.96 equiv of 5'-dA and 0.36 equiv of the lipoyl group. Mössbauer spectroscopy of this protein revealed that only approximately 67% +/- 6% of the iron is in the form of [4Fe-4S](2+) clusters, amounting to 9.2 +/- 0.4 irons and 8.8 +/- 0.1 sulfides or 2 [4Fe-4S](2+) clusters per polypeptide, with the remainder of the iron occurring as adventitiously bound species. Although the Mössbauer parameters of the clusters associated with each of the variants are similar, EPR spectra of the reduced forms of the cluster show small differences in spin concentration and g-values, consistent with each of these clusters as distinct species residing in each of the two cysteine-containing motifs.

AdoMet radical proteins--from structure to evolution--alignment of divergent protein sequences reveals strong secondary structure element conservation

Eighteen subclasses of S-adenosyl-l-methionine (AdoMet) radical proteins have been aligned in the first bioinformatics study of the AdoMet radical superfamily to utilize crystallographic information. The recently resolved X-ray structure of biotin synthase (BioB) was used to guide the multiple sequence alignment, and the recently resolved X-ray structure of coproporphyrinogen III oxidase (HemN) was used as the control. Despite the low 9% sequence identity between BioB and HemN, the multiple sequence alignment correctly predicted all but one of the core helices in HemN, and correctly predicted the residues in the enzyme active site. This alignment further suggests that the AdoMet radical proteins may have evolved from half-barrel structures (alphabeta)4 to three-quarter-barrel structures (alphabeta)6 to full-barrel structures (alphabeta)8. It predicts that anaerobic ribonucleotide reductase (RNR) activase, an ancient enzyme that, it has been suggested, serves as a link between the RNA and DNA worlds, will have a half-barrel structure, whereas the three-quarter barrel, exemplified by HemN, will be the most common architecture for AdoMet radical enzymes, and fewer members of the superfamily will join BioB in using a complete (alphabeta)8 TIM-barrel fold to perform radical chemistry. These differences in barrel architecture also explain how AdoMet radical enzymes can act on substrates that range in size from 10 atoms to 608 residue proteins.

SufA/IscA: reactivity studies of a class of scaffold proteins involved in [Fe-S] cluster assembly

IscA/SufA proteins belong to complex protein machineries which are involved in iron-sulfur cluster biosynthesis. They are defined as scaffold proteins from which preassembled clusters are transferred to target apoproteins. The experiments described here demonstrate that the transfer reaction proceeds in two observable steps: a first fast one leading to a protein-protein complex between the cluster donor (SufA/IscA) and the acceptor (biotin synthase), and a slow one consisting of cluster transfer leading to the apoform of the scaffold protein and the holoform of the target protein. Mutation of cysteines in the acceptor protein specifically inhibits the second step of the reaction, showing that these cysteines are involved in the cluster transfer mechanism but not in complex formation. No cluster transfer from IscA to IscU, another scaffold of the isc operon, could be observed, whereas IscU was shown to be an efficient cluster source for cluster assembly in IscA. Implications of these results are discussed.

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 Mössbauer 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 Mössbauer 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.

Role of the [2Fe−2S] Cluster in Recombinant Escherichia coli Biotin Synthase

Biotin synthase (BioB) converts dethiobiotin into biotin by inserting a sulfur atom between C6 and C9 of dethiobiotin in an S-adenosylmethionine (SAM)-dependent reaction. The as-purified recombinant BioB from Escherichia coli is a homodimeric molecule containing one [2Fe-2S](2+) cluster per monomer. It is inactive in vitro without the addition of exogenous Fe. Anaerobic reconstitution of the as-purified [2Fe-2S]-containing BioB with Fe(2+) and S(2)(-) produces a form of BioB that contains approximately one [2Fe-2S](2+) and one [4Fe-4S](2+) cluster per monomer ([2Fe-2S]/[4Fe-4S] BioB). In the absence of added Fe, the [2Fe-2S]/[4Fe-4S] BioB is active and can produce up to approximately 0.7 equiv of biotin per monomer. To better define the roles of the Fe-S clusters in the BioB reaction, Mössbauer and electron paramagnetic resonance (EPR) spectroscopy have been used to monitor the states of the Fe-S clusters during the conversion of dethiobiotin to biotin. The results show that the [4Fe-4S](2+) cluster is stable during the reaction and present in the SAM-bound form, supporting the current consensus that the functional role of the [4Fe-4S] cluster is to bind SAM and facilitate the reductive cleavage of SAM to generate the catalytically essential 5'-deoxyadenosyl radical. The results also demonstrate that approximately (2)/(3) of the [2Fe-2S] clusters are degraded by the end of the turnover experiment (24 h at 25 degrees C). A transient species with spectroscopic properties consistent with a [2Fe-2S](+) cluster is observed during turnover, suggesting that the degradation of the [2Fe-2S](2+) cluster is initiated by reduction of the cluster. This observed degradation of the [2Fe-2S] cluster during biotin formation is consistent with the proposed sacrificial S-donating function of the [2Fe-2S] cluster put forth by Jarrett and co-workers (Ugulava et al. (2001) Biochemistry 40, 8352-8358). Interestingly, degradation of the [2Fe-2S](2+) cluster was found not to parallel biotin formation. The initial decay rate of the [2Fe-2S](2+) cluster is about 1 order of magnitude faster than the initial formation rate of biotin, indicating that if the [2Fe-2S] cluster is the immediate S donor for biotin synthesis, insertion of S into dethiobiotin would not be the rate-limiting step. Alternatively, the [2Fe-2S] cluster may not be the immediate S donor. Instead, degradation of the [2Fe-2S] cluster may generate a protein-bound polysulfide or persulfide that serves as the immediate S donor for biotin production.

Crystal structure of biotin synthase, an S-adenosylmethionine-dependent radical enzyme

The crystal structure of biotin synthase from Escherichia coli in complex with S-adenosyl-L-methionine and dethiobiotin has been determined to 3.4 angstrom resolution. This structure addresses how "AdoMet radical" or "radical SAM" enzymes use Fe4S4 clusters and S-adenosyl-L-methionine to generate organic radicals. Biotin synthase catalyzes the radical-mediated insertion of sulfur into dethiobiotin to form biotin. The structure places the substrates between the Fe4S4 cluster, essential for radical generation, and the Fe2S2 cluster, postulated to be the source of sulfur, with both clusters in unprecedented coordination environments.

MiaB protein from Thermotoga maritima. Characterization of an extremely thermophilic tRNA-methylthiotransferase

In Escherichia coli, the MiaB protein catalyzes the methylthiolation of N-6-isopentenyl adenosine in tRNAs, the last reaction step during biosynthesis of 2-methylthio-N-6-isopentenyl adenosine (ms2i6A-37). For the first time the thermophilic bacterium Thermotoga maritima is shown here to contain such a MiaB tRNA-modifying enzyme, named MiaBTm, and to synthesize ms2i6A-37 as demonstrated by an analysis of modified nucleosides from tRNA hydrolysates. The corresponding gene (TM0653) was identified by sequence similarity to the miaB gene cloned and expressed in E. coli. MiaBTm was purified to homogeneity and thoroughly characterized by biochemical and spectroscopic methods. It is a monomer of 443 residues with a molecular mass of 50,710 kilodaltons. Its amino acid sequence shares the CysXXX-CysXXCys sequence with MiaB from E. coli as well as with biotin synthase and lipoate synthase. This sequence was shown to be essential for chelation of an iron-sulfur center and for activity in these enzymes. As isolated, MiaBTm contains both iron and sulfide and an apoprotein form can coordinate up to 4 iron and 4 sulfur atoms per polypeptide chain. UV-visible absorption, resonance Raman, variable temperature magnetic circular dichroism, and EPR spectroscopy of MiaBTm indicate the presence of a [4Fe-4S]+2/+1 cluster under reducing and anaerobic conditions, whereas [3Fe-4S]+1 and [2Fe-2S]+2 forms are generated under aerobic conditions. The redox potential of the [4Fe-4S]+2/+1 transition is -495 +/- 10 mV (versus the normal hydrogen electrode). Finally, the expression of MiaBTm from T. maritima in an E. coli mutant strain lacking functional miaB gene allowed production of ms2i6A-37. These results provide further information on the enzymes involved in methylthiolation of tRNAs.

Fate of the (2Fe-2S)(2+) cluster of Escherichia coli biotin synthase during reaction: a Mössbauer characterization

Biotin synthase, the enzyme which catalyzes the last step of the biosynthesis of biotin, contains only (2Fe-2S)(2+) clusters when isolated under aerobic conditions. Previous results showed that reduction by dithionite or photoreduced deazaflavin converts the (2Fe-2S)(2+) to (4Fe-4S)(2+,+). However, until now, no detailed investigation concerning the fate of the (2Fe-2S)(2+) during reduction under assay conditions (NADPH, flavodoxin, flavodoxin reductase) has been realized. Here, we show by Mössbauer spectroscopy on a partially purified fraction overexpressing the enzyme that, in the presence of a S(2)(-) source and Fe(2+), there is conversion of the predominant (2Fe-2S)(2+) clusters into a 1:1 mixture of (2Fe-2S)(2+) and (4Fe-4S)(2+). No change in this cluster composition was observed in the presence of the physiological reducing system. When the reaction was allowed to proceed by addition of the substrate dethiobiotin, the (4Fe-4S)(2+) was untouched whereas the (2Fe-2S)(2+) was degraded into a new species. This is consistent with the hypothesis that the reduced (4Fe-4S) cluster is involved in mediating the cleavage of AdoMet and that the (2Fe-2S)(2+) is the sulfur source for biotin.

Control of adenosylmethionine-dependent radical generation in biotin synthase: a kinetic and thermodynamic analysis of substrate binding to active and inactive forms of BioB

Biotin synthase (BS) is an AdoMet-dependent radical enzyme that catalyzes the insertion of sulfur into saturated C6 and C9 atoms in the substrate dethiobiotin. To facilitate sulfur insertion, BS catalyzes the reductive cleavage of AdoMet to methionine and 5'-deoxyadenosyl radicals, which then abstract hydrogen atoms from the C6 and C9 positions of dethiobiotin. The enzyme from Escherichia coli is purified as a dimer that contains one [2Fe-2S]2+ cluster per monomer and can be reconstituted in vitro to contain an additional [4Fe-4S]2+ cluster per monomer. Since each monomer contains each type of cluster, the dimeric enzyme could contain one active site per monomer, or could contain a single active site at the dimer interface. To address these possibilities, and to better understand the manner in which biotin synthase controls radical generation and reactivity, we have examined the binding of AdoMet and DTB to reconstituted biotin synthase. We find that both the [2Fe-2S]2+ cluster and the [4Fe-4S]2+ cluster must be present for tight substrate binding. Further, substrate binding is highly cooperative, with the affinity for AdoMet increasing >20-fold in the presence of DTB, while DTB binds only in the presence of AdoMet. The stoichiometry of binding is ca. 2:1:1 AdoMet:DTB:BS dimer, suggesting that biotin synthase has a single functional active site per dimer. AdoMet binding, either in the presence or in the absence of DTB, leads to a decrease in the magnitude of the UV-visible absorption band at approximately 400 nm that we attribute to changes in the coordination environment of the [4Fe-4S]2+ cluster. Using these spectral changes as a probe, we have examined the kinetics of AdoMet and DTB binding, and propose an ordered binding mechanism that is followed by a conformational change in the enzyme-substrate complex. This kinetic analysis suggests that biotin synthase is evolved to bind AdoMet both weakly and slowly in the absence of DTB, while both the rate of binding and the affinity for AdoMet are increased in the presence of DTB. Cooperative binding of AdoMet and DTB may be an important mechanism for limiting the production of 5'-deoxyadenosyl radicals in the absence of the correct substrate.

The PLP-dependent biotin synthase from Escherichia coli: mechanistic studies

Biotin synthase (BioB), an iron-sulfur enzyme, catalyzes the last step of the biotin biosynthesis pathway. The reaction consists in the introduction of a sulfur atom into two non-activated C-H bonds of dethiobiotin. Substrate radical activation is initiated by the reductive cleavage of S-adenosylmethionine (AdoMet) into a 5'-deoxyadenosyl radical. The recently described pyridoxal 5'-phosphate-bound enzyme was used to show that only one molecule of AdoMet, and not two, is required for the formation of one molecule of biotin. Furthermore 5'-deoxyadenosine, a product of the reaction, strongly inhibited biotin formation, an observation that may explain why BioB is not able to make more than one turnover. However this enzyme inactivation is not irreversible.

Evidence from Mössbauer spectroscopy for distinct [2Fe-2S](2+) and [4Fe-4S](2+) cluster binding sites in biotin synthase from Escherichia coli

Biotin synthase is an AdoMet-dependent radical enzyme that catalyzes the insertion of an FeS cluster-derived sulfur atom into dethiobiotin. The dimeric enzyme is purified containing one [2Fe-2S]2+ cluster per monomer, but it is most active when reconstituted with an additional [4Fe-4S]2+ cluster per monomer. Using Mössbauer spectroscopy coupled with differential reconstitution of each cluster with 57Fe, we show that the reconstituted enzyme has approximately 1:1 [2Fe-2S]2+ and [4Fe-4S]2+ clusters and that the [4Fe-4S]2+ cluster is assembled at an alternate site not previously occupied by the [2Fe-2S]2+ cluster. These data suggest that biotin synthase is evolved to simultaneously accommodate two different clusters with unique roles in catalysis.

Biotin synthase is a pyridoxal phosphate-dependent cysteine desulfurase

Biotin synthase (BioB) is an iron-sulfur dimeric enzyme which catalyzes the last step in biotin synthesis. The reaction consists of the introduction of a sulfur atom into dethiobiotin. It is shown here that BioB displays a significant cysteine desulfurase activity, providing it with the ability to mobilize sulfur from free cysteine. This activity is dependent on pyridoxal 5'-phosphate (PLP) and dithiothreitol and proceeds through a protein-bound persulfide. Like other cysteine desulfurases, BioB binds 1 equiv of PLP. By site-directed mutagenesis, two conserved cysteines, Cys97 and Cys128, are shown to be critical for cysteine desulfuration and are good candidates as the site for a persulfide. Since biotin synthase activity is greatly increased by PLP and cysteine, even though it does not exceed 1 nmol of biotin/nmol of monomer, it is proposed that cysteine desulfuration is intimately linked to biotin synthesis. New scenarios for sulfur insertion into dethiobiotin, in which cysteine persulfides play a key role, are discussed.

Reductive cleavage of S-adenosylmethionine by biotin synthase from Escherichia coli

Biotin synthase (BioB) catalyzes the insertion of a sulfur atom between the C6 and C9 carbons of dethiobiotin. Reconstituted BioB from Escherichia coli contains a [4Fe-4S](2+/1+) cluster thought to be involved in the reduction and cleavage of S-adenosylmethionine (AdoMet), generating methionine and the reactive 5'-deoxyadenosyl radical responsible for dethiobiotin H-abstraction. Using EPR and Mössbauer spectroscopy as well as methionine quantitation we demonstrate that the reduced S = 1/2 [4Fe-4S](1+) cluster is indeed capable of injecting one electron into AdoMet, generating one equivalent of both methionine and S = 0 [4Fe-4S](2+) cluster. Dethiobiotin is not required for the reaction. Using site-directed mutagenesis we show also that, among the eight cysteines of BioB, only three (Cys-53, Cys-57, Cys-60) are essential for AdoMet reductive cleavage, suggesting that these cysteines are involved in chelation of the [4Fe-4S](2+/1+) cluster.

Enzymatic modification of tRNAs: MiaB is an iron-sulfur protein

The product of the miaB gene, MiaB, from Escherichia coli participates in the methylthiolation of the adenosine 37 residue during modification of tRNAs that read codons beginning with uridine. A His-tagged version of MiaB has been overproduced and purified to homogeneity. Gel electrophoresis and size exclusion chromatography revealed that MiaB protein is a monomer. As isolated MiaB contains both iron and sulfide and an apoprotein form can chelate as much as 2.5-3 iron and 3-3.5 sulfur atoms per polypeptide chain. UV-visible and EPR spectroscopy of MiaB indicate the presence of a [4Fe-4S] cluster under reducing and anaerobic conditions, whereas [2Fe-2S] and [3Fe-4S] forms are generated under aerobic conditions. Preliminary site-directed mutagenesis studies suggest that Cys(157), Cys(161), and Cys(164) are involved in iron chelation and that the cluster is essential for activity. Together with the previously shown requirement of S-adenosylmethionine (AdoMet) for the methylthiolation reaction, the finding that MiaB is an iron-sulfur protein suggests that it belongs to a superfamily of enzymes that uses [Fe-S] centers and AdoMet to initiate radical catalysis. MiaB is the first and only tRNA modification enzyme known to contain an Fe-S cluster.