Molecular properties of pyruvate formate-lyase activating enzyme

Streptococcus pneumoniae TIGR4 Flavodoxin: Structural and Biophysical Characterization of a Novel Drug Target

Streptococcus pneumoniae (Sp) strain TIGR4 is a virulent, encapsulated serotype that causes bacteremia, otitis media, meningitis and pneumonia. Increased bacterial resistance and limited efficacy of the available vaccine to some serotypes complicate the treatment of diseases associated to this microorganism. Flavodoxins are bacterial proteins involved in several important metabolic pathways. The Sp flavodoxin (Spfld) gene was recently reported to be essential for the establishment of meningitis in a rat model, which makes SpFld a potential drug target. To facilitate future pharmacological studies, we have cloned and expressed SpFld in E. coli and we have performed an extensive structural and biochemical characterization of both the apo form and its active complex with the FMN cofactor. SpFld is a short-chain flavodoxin containing 146 residues. Unlike the well-characterized long-chain apoflavodoxins, the Sp apoprotein displays a simple two-state thermal unfolding equilibrium and binds FMN with moderate affinity. The X-ray structures of the apo and holo forms of SpFld differ at the FMN binding site, where substantial rearrangement of residues at the 91-100 loop occurs to permit cofactor binding. This work will set up the basis for future studies aiming at discovering new potential drugs to treat S. pneumoniae diseases through the inhibition of SpFld.

Structure and Function of 4-Hydroxyphenylacetate Decarboxylase and Its Cognate Activating Enzyme

4-Hydroxyphenylacetate decarboxylase (4Hpad) is the prototype of a new class of Fe-S cluster-dependent glycyl radical enzymes (Fe-S GREs) acting on aromatic compounds. The two-enzyme component system comprises a decarboxylase responsible for substrate conversion and a dedicated activating enzyme (4Hpad-AE). The decarboxylase uses a glycyl/thiyl radical dyad to convert 4-hydroxyphenylacetate into <i>p</i>-cresol (4-methylphenol) by a biologically unprecedented Kolbe-type decarboxylation. In addition to the radical dyad prosthetic group, the decarboxylase unit contains two [4Fe-4S] clusters coordinated by an extra small subunit of unknown function. 4Hpad-AE reductively cleaves S-adenosylmethionine (SAM or AdoMet) at a site-differentiated [4Fe-4S]^2+/+ cluster (RS cluster) generating a transient 5′-deoxyadenosyl radical that produces a stable glycyl radical in the decarboxylase by the abstraction of a hydrogen atom. 4Hpad-AE binds up to two auxiliary [4Fe-4S] clusters coordinated by a ferredoxin-like insert that is C-terminal to the RS cluster-binding motif. The ferredoxin-like domain with its two auxiliary clusters is not vital for SAM-dependent glycyl radical formation in the decarboxylase, but facilitates a longer lifetime for the radical. This review describes the 4Hpad and cognate AE families and focuses on the recent advances and open questions concerning the structure, function and mechanism of this novel Fe-S-dependent class of GREs.

Cloning, expression and characterization of histidine-tagged biotin synthase of Mycobacterium tuberculosis

The emergence of Mycobacterium tuberculosis strains that are resistant to the current anti-tuberculosis (TB) drugs necessitates a need to develop a new class of drugs whose targets are different from the current ones. M. tuberculosis biotin synthase (MtbBS) is one such target that is essential for the survival of the bacteria. In this study, MtbBS was cloned, overexpressed and purified to homogeneity for biochemical characterization. It is likely to be a dimer in its native form. Its pH and temperature optima are 8.0 and 37 °C, respectively. Km for DTB and SAM was 2.81 ± 0.35 and 9.95 ± 0.98 μM, respectively. The enzyme had a maximum velocity of 0.575 ± 0.015 μM min(-1), and a turn-over of 0.0935 min(-1). 5'-deoxyadenosine (dAH), S-(5'-Adenosyl)-l-cysteine (AdoCy) and S-(5'-Adenosyl)-l-homocysteine (AdoHcy) were competitive inhibitors of MtbBS with the following inactivation parameters: Ki = 24.2 μM, IC50 = 267.4 μM; Ki = 0.84 μM, IC50 = 9.28 μM; and Ki = 0.592 μM, IC50 = 6.54 μM for dAH, AdoCy and AdoHcy respectively. dAH could inhibit the growth of M. tuberculosis H37Ra with an MIC of 392.6 μg/ml. This information should be useful for the discovery of inhibitors of MtbBS.

Molecular architectures and functions of radical enzymes and their (re)activating proteins

Certain proteins utilize the high reactivity of radicals for catalysing chemically challenging reactions. These proteins contain or form a radical and therefore named 'radical enzymes'. Radicals are introduced by enzymes themselves or by (re)activating proteins called (re)activases. The X-ray structures of radical enzymes and their (re)activases revealed some structural features of these molecular apparatuses which solved common enigmas of radical enzymes—i.e. how the enzymes form or introduce radicals at the active sites, how they use the high reactivity of radicals for catalysis, how they suppress undesired side reactions of highly reactive radicals and how they are (re)activated when inactivated by extinction of radicals. This review highlights molecular architectures of radical B12 enzymes, radical SAM enzymes, tyrosyl radical enzymes, glycyl radical enzymes and their (re)activating proteins that support their functions. For generalization, comparisons of the recently reported structures of radical enzymes with those of canonical radical enzymes are summarized here.

Travels with carbon-centered radicals. 5'-deoxyadenosine and 5'-deoxyadenosine-5'-yl in radical enzymology

As a graduate student under Professor R. H. Abeles, I began my journey with 5'-deoxyadenosine, studying the coenzyme B12 (adenosylcobalamin)-dependent dioldehydrase (DDH). I proved that suicide inactivation of dioldehydrase by glycolaldehyde proceeded with irreversible cleavage of adenosylcobalamin to 5'-deoxyadenosine. I further showed that suicide inactivation by [2-(3)H]glycolaldehyde produced 5'-deoxy[(3)H]adenosine, the first demonstration of hydrogen transfer to adenosyl-C5' of adenosylcobalamin. The tritium kinetic isotope effect (T)k was 15, which correlated well with the measurement (D)k = 12 for transformation of [1-(2)H]propane-1,2-diol to [2-(2)H]propionaldehyde by DDH. After establishing my own research program, I returned to the glycolaldehyde inactivation of DDH, showing by EPR that suicide inactivation produced glycolaldehyde-2-yl. In retrospect, suicide inactivation involved scission of adenosylcobalamin to 5'-deoxyadenosine-5'-yl, which abstracted a hydrogen from glycolaldehyde. Captodative-stabilized glycolaldehyde-2-yl could not react further, leading to suicide inactivation. In 1986, my colleagues and I took up the problem of the mechanism by which lysine 2,3-aminomutase (LAM) catalyzes S-adenosylmethionine (SAM) and pyridoxal-5'-phosphate (PLP)-dependent interconversion of l-lysine and l-β-lysine. Because the reaction followed the pattern of adenosylcobalamin-dependent rearrangements, I postulated that SAM might be an evolutionary predecessor to adenosylcobalamin. Testing this hypothesis, we traced hydrogen transfer from lysine through the adenosyl-C5' of SAM to β-lysine. Thus, the 5'-deoxyadenosyl of SAM mediated hydrogen transfer by LAM exactly as in adenosylcobalamin mediated hydrogen transfer in B12-dependent isomerizations. The mechanism postulated that SAM cleaves to form 5'-deoxyadenosine-5'-yl followed by abstraction of C3(H) from PLP-α-lysine aldimine to form PLP-α-lysine-3-yl. PLP-α-lysine-3-yl isomerizes to pyridoxal-β-lysine-2-yl, and a hydrogen abstraction from 5'-deoxyadenosine regenerates 5'-deoxyadenosine-5'-yl and releases β-lysine. Of four radicals in the postulated mechanism, three have been characterized by EPR spectroscopy as kinetically competent intermediates. The analysis of the role of iron allowed researchers to elucidate the mechanism by which SAM is cleaved to 5'-deoxyadenosine-5'-yl. LAM contains one [4Fe-4S] cluster ligated by three cysteine residues. As shown by ENDOR spectroscopy and X-ray crystallography, the fourth ligand to the cluster is SAM, through the methionyl carboxylate and amino groups. Inner sphere electron transfer within the [4Fe-4S](1+)-SAM complex leads to [4Fe-4S](2+)-Met and 5'-deoxyadenosine-5'-yl. The iron-binding motif in LAM, CxxxCxxC, found by other groups in four other SAM-dependent enzymes, is the founding motif for the radical SAM superfamily. These enzymes number in the tens of thousands and are responsible for highly diverse and chemically difficult transformations in the biosphere. Available information supports the hypothesis that this superfamily provides the chemical context from which the much more structurally complex adenosylcobalamin evolved.

Pyruvate formate-lyase and its activation by pyruvate formate-lyase activating enzyme

The activation of pyruvate formate-lyase (PFL) by pyruvate formate-lyase activating enzyme (PFL-AE) involves formation of a specific glycyl radical on PFL by the PFL-AE in a reaction requiring S-adenosylmethionine (AdoMet). Surface plasmon resonance experiments were performed under anaerobic conditions on the oxygen-sensitive PFL-AE to determine the kinetics and equilibrium constant for its interaction with PFL. These experiments show that the interaction is very slow and rate-limited by large conformational changes. A novel AdoMet binding assay was used to accurately determine the equilibrium constants for AdoMet binding to PFL-AE alone and in complex with PFL. The PFL-AE bound AdoMet with the same affinity (∼6 μM) regardless of the presence or absence of PFL. Activation of PFL in the presence of its substrate pyruvate or the analog oxamate resulted in stoichiometric conversion of the [4Fe-4S](1+) cluster to the glycyl radical on PFL; however, 3.7-fold less activation was achieved in the absence of these small molecules, demonstrating that pyruvate or oxamate are required for optimal activation. Finally, in vivo concentrations of the entire PFL system were calculated to estimate the amount of bound protein in the cell. PFL, PFL-AE, and AdoMet are essentially fully bound in vivo, whereas electron donor proteins are partially bound.

Biochemical and kinetic characterization of radical S-adenosyl-L-methionine enzyme HydG

The radical S-adenosyl-L-methionine (AdoMet) enzyme HydG is one of three maturase enzymes involved in [FeFe]-hydrogenase H-cluster assembly. It catalyzes L-tyrosine cleavage to yield the H-cluster cyanide and carbon monoxide ligands as well as p-cresol. Clostridium acetobutylicum HydG contains the conserved CX3CX2C motif coordinating the AdoMet binding [4Fe-4S] cluster and a C-terminal CX2CX22C motif proposed to coordinate a second [4Fe-4S] cluster. To improve our understanding of the roles of each of these iron-sulfur clusters in catalysis, we have generated HydG variants lacking either the N- or C-terminal cluster and examined these using spectroscopic and kinetic methods. We have used iron analyses, UV-visible spectroscopy, and electron paramagnetic resonance (EPR) spectroscopy of an N-terminal C96/100/103A triple HydG mutant that cannot coordinate the radical AdoMet cluster to unambiguously show that the C-terminal cysteine motif coordinates an auxiliary [4Fe-4S] cluster. Spectroscopic comparison with a C-terminally truncated HydG (ΔCTD) harboring only the N-terminal cluster demonstrates that both clusters have similar UV-visible and EPR spectral properties, but that AdoMet binding and cleavage occur only at the N-terminal radical AdoMet cluster. To elucidate which steps in the catalytic cycle of HydG require the auxiliary [4Fe-4S] cluster, we compared the Michaelis-Menten constants for AdoMet and L-tyrosine for reconstituted wild-type, C386S, and ΔCTD HydG and demonstrate that these C-terminal modifications do not affect the affinity for AdoMet but that the affinity for L-tyrosine is drastically reduced compared to that of wild-type HydG. Further detailed kinetic characterization of these HydG mutants demonstrates that the C-terminal cluster and residues are not essential for L-tyrosine cleavage to p-cresol but are necessary for conversion of a tyrosine-derived intermediate to cyanide and CO.

Biotin synthase exhibits burst kinetics and multiple turnovers in the absence of inhibition by products and product-related biomolecules

Biotin synthase (BS) is a member of the "SAM radical" superfamily of enzymes, which catalyze reactions in which the reversible or irreversible oxidation of various substrates is coupled to the reduction of the S-adenosyl-l-methionine (AdoMet) sulfonium to generate methionine and 5'-deoxyadenosine (dAH). Prior studies have demonstrated that these products are modest inhibitors of BS and other members of this enzyme family. In addition, the in vivo catalytic activity of Escherichia coli BS requires expression of 5'-methylthioadenosine/S-adenosyl-l-homocysteine nucleosidase, which hydrolyzes 5'-methylthioadenosine (MTA), S-adenosyl-l-homocysteine (AdoHcy), and dAH. In the present work, we confirm that dAH is a modest inhibitor of BS (K(i) = 20 μM) and show that cooperative binding of dAH with excess methionine results in a 3-fold enhancement of this inhibition. However, with regard to the other substrates of MTA/AdoHcy nucleosidase, we demonstrate that AdoHcy is a potent inhibitor of BS (K(i) ≤ 650 nM) while MTA is not an inhibitor. Inhibition by both dAH and AdoHcy likely accounts for the in vivo requirement for MTA/AdoHcy nucleosidase and may help to explain some of the experimental disparities between various laboratories studying BS. In addition, we examine possible inhibition by other AdoMet-related biomolecules present as common contaminants in commercial AdoMet preparations and/or generated during an assay, as well as by sinefungin, a natural product that is a known inhibitor of several AdoMet-dependent enzymes. Finally, we examine the catalytic activity of BS with highly purified AdoMet in the presence of MTAN to relieve product inhibition and present evidence suggesting that the enzyme is half-site active and capable of undergoing multiple turnovers in vitro.

Pyruvate formate lyase is required for pneumococcal fermentative metabolism and virulence

Knowledge of the in vivo physiology and metabolism of Streptococcus pneumoniae is limited, even though pneumococci rely on efficient acquisition and metabolism of the host nutrients for growth and survival. Because the nutrient-limited, hypoxic host tissues favor mixed-acid fermentation, we studied the role of the pneumococcal pyruvate formate lyase (PFL), a key enzyme in mixed-acid fermentation, which is activated posttranslationally by PFL-activating enzyme (PFL-AE). Mutations were introduced to two putative pfl genes, SPD0235 and SPD0420, and two putative pflA genes, SPD0229 and SPD1774. End-product analysis showed that there was no formate, the main end product of the reaction catalyzed by PFL, produced by mutants defective in SPD0420 and SPD1774, indicating that SPD0420 codes for PFL and SPD1774 for putative PFL-AE. Expression of SPD0420 was elevated in galactose-containing medium in anaerobiosis compared to growth in glucose, and the mutation of SPD0420 resulted in the upregulation of fba and pyk, encoding, respectively, fructose 1,6-bisphosphate aldolase and pyruvate kinase, under the same conditions. In addition, an altered fatty acid composition was detected in SPD0420 and SPD1774 mutants. Mice infected intranasally with the SPD0420 and SPD1774 mutants survived significantly longer than the wild type-infected cohort, and bacteremia developed later in the mutant cohort than in the wild type-infected group. Furthermore, the numbers of CFU of the SPD0420 mutant were lower in the nasopharynx and the lungs after intranasal infection, and fewer numbers of mutant CFU than of wild-type CFU were recovered from blood specimens after intravenous infection. The results demonstrate that there is a direct link between pneumococcal fermentative metabolism and virulence.

Structural basis for glycyl radical formation by pyruvate formate-lyase activating enzyme

Pyruvate formate-lyase activating enzyme generates a stable and catalytically essential glycyl radical on G(734) of pyruvate formate-lyase via the direct, stereospecific abstraction of a hydrogen atom from pyruvate formate-lyase. The activase performs this remarkable feat by using an iron-sulfur cluster and S-adenosylmethionine (AdoMet), thus placing it among the AdoMet radical superfamily of enzymes. We report here structures of the substrate-free and substrate-bound forms of pyruvate formate-lyase-activating enzyme, the first structures of an AdoMet radical activase. To obtain the substrate-bound structure, we have used a peptide substrate, the 7-mer RVSGYAV, which contains the sequence surrounding G(734). Our structures provide fundamental insights into the interactions between the activase and the G(734) loop of pyruvate formate-lyase and provide a structural basis for direct and stereospecific H atom abstraction from the buried G(734) of pyruvate formate-lyase.

The Radical SAM Superfamily

The radical S-adenosylmethionine (SAM) superfamily currently comprises more than 2800 proteins with the amino acid sequence motif CxxxCxxC unaccompanied by a fourth conserved cysteine. The charcteristic three-cysteine motif nucleates a [4Fe-4S] cluster, which binds SAM as a ligand to the unique Fe not ligated to a cysteine residue. The members participate in more than 40 distinct biochemical transformations, and most members have not been biochemically characterized. A handful of the members of this superfamily have been purified and at least partially characterized. Significant mechanistic and structural information is available for lysine 2,3-aminomutase, pyruvate formate-lyase, coproporphyrinogen III oxidase, and MoaA required for molybdopterin biosynthesis. Biochemical information is available for spore photoproduct lyase, anaerobic ribonucleotide reductase activation subunit, lipoyl synthase, and MiaB involved in methylthiolation of isopentenyladenine-37 in tRNA. The radical SAM enzymes biochemically characterized to date have in common the cleavage of the [4Fe-4S](1 +) -SAM complex to [4Fe-4S](2 +)-Met and the 5' -deoxyadenosyl radical, which abstracts a hydrogen atom from the substrate to initiate a radical mechanism.

Theoretical Study of the Suicide Inhibition Mechanism of the Enzyme Pyruvate Formate Lyase by Methacrylate

The determination of pyruvate formate lyase crystallographic structure brought new insights to its mechanism of reaction and presented the possibility of a direct attack to the substrate from cysteine 418 as opposed to the previously expected cysteine 419. An inhibition study performed by Knappe and co-workers, using substrate-analogue methacrylate, confirms that cysteine 418 is most likely to add directly to pyruvate, since an inhibition product has been found as a substituent in this residue. The work presented here consists of a study of the inhibition mechanism of pyruvate formate lyase by methacrylate, using density functional theory with the hybrid B3LYP functional. We were able to determine all pertinent structures, confirm the proposed experimental mechanism, and add important detail to the energy profile associated with the mechanism of inhibition. Additionally, the obtained results provide the energy values for both the chemical reaction and the stereochemical reorganization necessary in order for the thiol-methacrylate adduct to come within reactional reach of Cys419.

Pyruvate formate-lyase activating enzyme: elucidation of a novel mechanism for glycyl radical formation

Pyruvate formate lyase activating enzyme is a member of a novel superfamily of enzymes that utilize S-adenosylmethionine to initiate radical catalysis. This enzyme has been isolated with several different iron-sulfur clusters, but single turnover monitored by EPR has identified the [4Fe-4S](1+) cluster as the catalytically active cluster; this cluster is believed to be oxidized to the [4Fe-4S](2+) state during turnover. The [4Fe-4S] cluster is coordinated by a three-cysteine motif common to the radical/S-adenosylmethionine superfamily, suggesting the presence of a unique iron in the cluster. The unique iron site has been confirmed by Mossbauer and ENDOR spectroscopy experiments, which also provided the first evidence for direct coordination of S-adenosylmethionine to an iron-sulfur cluster, in this case the unique iron of the [4Fe-4S] cluster. Coordination to the unique iron anchors the S-adenosylmethionine in the active site, and allows for a close association between the sulfonium of S-adenosylmethionine and the cluster as observed by ENDOR spectroscopy. The evidence to date leads to a mechanistic proposal involving inner-sphere electron transfer from the cluster to the sulfonium of S-adenosylmethionine, followed by or concomitant with C-S bond homolysis to produce a 5'-deoxyadenosyl radical; this transient radical abstracts a hydrogen atom from G734 to activate pyruvate formate lyase.

Molecular characterization and expression of pyruvate formate-lyase-activating enzyme in a ruminal bacterium, Streptococcus bovis

To clarify the significance of the activation of pyruvate formate-lyase (PFL) by PFL-activating enzyme (PFL-AE) in Streptococcus bovis, the molecular properties and gene expression of PFL-AE were investigated. S. bovis PFL-AE was deduced to consist of 261 amino acids with a molecular mass of 29.9 kDa and appeared to be a monomer protein. Similar to Escherichia coli PFL-AE, S. bovis PFL-AE required Fe(2+) for activity. The gene encoding PFL-AE (act) was found to be polycistronic, and the PFL gene (pfl) was not included. However, the act mRNA level changed in parallel with the pfl mRNA level, responding to growth conditions, and the change was contrary to the change in the lactate dehydrogenase (LDH) mRNA level. PFL-AE synthesis appeared to change in parallel with PFL synthesis. Introduction of a recombinant plasmid containing S. bovis pfl and the pfl promoter into S. bovis did not affect formate and lactate production, which suggests that the activity of the pfl promoter is low. When the pfl promoter was replaced by the S. bovis ldh promoter, PFL was overexpressed, which caused an increase in the formate-to-lactate ratio. However, when PFL-AE was overexpressed, the formate-to-lactate ratio did not change, suggesting that PFL-AE was present at a level that was high enough to activate PFL. When both PFL-AE and PFL were overexpressed, the formate-to-lactate ratio further increased. It is conceivable that LDH activity is much higher than PFL activity, which may explain why the formate-to-lactate ratio is usually low.

Mapping the interactions between flavodoxin and its physiological partners flavodoxin reductase and cobalamin-dependent methionine synthase

Flavodoxins are electron-transfer proteins that contain the prosthetic group flavin mononucleotide. In Escherichia coli, flavodoxin is reduced by the FAD-containing protein NADPH:ferredoxin (flavodoxin) oxidoreductase; flavodoxins serve as electron donors in the reductive activation of anaerobic ribonucleotide reductase, biotin synthase, pyruvate formate lyase, and cobalamin-dependent methionine synthase. In addition, domains homologous to flavodoxin are components of the multidomain flavoproteins cytochrome P450 reductase, nitric oxide synthase, and methionine synthase reductase. Although three-dimensional structures are known for many of these proteins and domains, very little is known about the structural aspects of their interactions. We address this issue by using NMR chemical shift mapping to identify the surfaces on flavodoxin that bind flavodoxin reductase and methionine synthase. We find that these physiological partners bind to unique overlapping sites on flavodoxin, precluding the formation of ternary complexes. We infer that the flavodoxin-like domains of the cytochrome P450 reductase family form mutually exclusive complexes with their electron-donating and -accepting partners, complexes that require conformational changes for interconversion.

The subunit structure and catalytic mechanism of the Bacillus subtilis DNA repair enzyme spore photoproduct lyase

The major DNA photoproduct of dormant, UV-irradiated Bacillus subtilis spores is the thymine dimer 5-thyminyl-5,6-dihydrothymine [spore photoproduct (SP)]. During spore germination, SP is reversed to two intact thymines in situ by the DNA repair enzyme SP lyase, an S-adenosylmethionine (S-AdoMet)-dependent iron-sulfur ([Fe-S]) protein encoded by the splB gene. In the present work, cross-linking, SDS/PAGE, and size exclusion chromatography revealed that SplB protein dimerized when incubated with iron and sulfide under anaerobic reducing conditions. SplB isolated under aerobic conditions generated an EPR spectrum consistent with that of a partially degraded [3Fe-4S] center, and reduction of SplB with dithionite shifted the spectrum to that of a [4Fe-4S] center. Addition of S-AdoMet to SplB converted some of the [4Fe-4S] centers to an EPR-silent form consistent with electron donation to S-AdoMet. HPLC and electrospray ionization MS analyses showed that SP lyase cleaved S-AdoMet to generate 5'-deoxyadenosine. The results indicate that (i) SP lyase is a homodimer of SplB; (ii) dimer formation is coordinated by a [4Fe-4S] center; and (iii) the reduced [4Fe-4S] center is capable of donating electrons to S-AdoMet to generate a 5'-adenosyl radical that is then used for the in situ reversal of SP. Thus, SP lyase belongs to the "radical SAM" superfamily of enzymes that use [Fe-S] centers and S-AdoMet to generate adenosyl radicals to effect catalysis. SP lyase is unique in being the first and only DNA repair enzyme known to function via this novel enzymatic mechanism.

Biosynthesis of biotin and lipoic acid

The genetics and mechanistic enzymology of biotin biosynthesis have been the subject of much investigation in the last decade, owing to the interest for biotin production by fermentation, on the one hand, and for the design of inhibitors with potential herbicidal properties, on the other hand. Four enzymes are involved in the synthesis of biotin from its two precursors, alanine and pimeloyl-CoA. They are now well-characterized and the X-ray structures of the first three have been published. 8-Amino-7-oxopelargonic acid synthase is a pyridoxal 5'-phosphate (PLP) enzyme, very similar to other acyl-CoA alpha-oxoamine synthases, and its detailed mechanism has been determined. The origin of its specific substrate, pimeloyl-CoA, however, is not completely established. It could be produced by a modified fatty acid pathway involving a malonyl thioester as the starter. 7,8-Diaminopelargonic acid (DAPA) aminotransferase, although sharing sequence and folding homologies with other transaminases, is unique as it uses S-adenosylmethionine (AdoMet) as the NH2 donor. The mechanism of dethiobiotin synthethase is also now well understood. It catalyzes the formation of the ureido ring via a DAPA carbamate activated with ATP. On the other hand, the mechanism of the last enzyme, biotin synthase, which has long raised a very puzzling problem, is only starting to be unraveled and appears indeed to be very complex. Biotin synthase belongs to the family of AdoMet-dependent enzymes that reductively cleave AdoMet into a deoxyadenosyl radical, and it is responsible for the homolytic cleavage of C-H bonds. A first radical formed on dethiobiotin is trapped by the sulfur donor, which was found to be the iron-sulfur (Fe-S) center contained in the enzyme, and cyclization follows in a second step. Two important features come from these results: (1) a new role for an Fe-S center has been revealed, and (2) biotin synthase is not only a catalyst but also a substrate for the reaction. Lipoate synthase, which catalyzes the formation of two C-S bonds from octanoic acid, has a very high sequence similarity with biotin synthase. Although no in vitro enzymology has been carried out with lipoate synthase, the sequence homology as well as the results of in vivo studies support the conclusion that both enzymes are strongly mechanistically related.

p-Hydroxyphenylacetate decarboxylase from Clostridium difficile. A novel glycyl radical enzyme catalysing the formation of p-cresol

The human pathogenic bacterium Clostridium difficile is a versatile organism concerning its ability to ferment amino acids. The formation of p-cresol as the main fermentation product of tyrosine by C. difficile is unique among clostridial species. The enzyme responsible for p-cresol formation is p-hydroxyphenylacetate decarboxylase. The enzyme was purified from C. difficile strain DMSZ 1296(T) and initially characterized. The N-terminal amino-acid sequence was 100% identical to an open reading frame in the unfinished genome of C. difficile strain 630. The ORF encoded a protein of the same size as the purified decarboxylase and was very similar to pyruvate formate-lyase-like proteins from Escherichia coli and Archaeoglobus fulgidus. The enzyme decarboxylated p-hydroxyphenylacetate (K(m) = 2.8 mM) and 3,4-dihydroxyphenylacetate (K(m) = 0.5 mM). It was competitively inhibited by the substrate analogues p-hydroxyphenylacetylamide and p-hydroxymandelate with K(i) values of 0.7 mM and 0.48 mM, respectively. The protein was readily and irreversibly inactivated by molecular oxygen. Although the purified enzyme was active in the presence of sodium sulfide, there are some indications for an as yet unidentified low molecular mass cofactor that is required for catalytic activity in vivo. Based on the identification of p-hydroxyphenylacetate decarboxylase as a novel glycyl radical enzyme and the substrate specificity of the enzyme, a catalytic mechanism involving ketyl radicals as intermediates is proposed.

Interim report on genomics of Escherichia coli

We present a summary of recent progress in understanding Escherichia coli K-12 gene and protein functions. New information has come both from classical biological experimentation and from using the analytical tools of functional genomics. The content of the E. coli genome can clearly be seen to contain elements acquired by horizontal transfer. Nevertheless, there is probably a large, stable core of >3500 genes that are shared among all E. coli strains. The gene-enzyme relationship is examined, and, in many cases, it exhibits complexity beyond a simple one-to-one relationship. Also, the E. coli genome can now be seen to contain many multiple enzymes that carry out the same or closely similar reactions. Some are similar in sequence and may share common ancestry; some are not. We discuss the concept of a minimal genome as being variable among organisms and obligatorily linked to their life styles and defined environmental conditions. We also address classification of functions of gene products and avenues of insight into the history of protein evolution.

Characterization of the Streptococcus mutans pyruvate formate-lyase (PFL)-activating enzyme gene by complementary reconstitution of the In vitro PFL-reactivating system

The act gene was identified and an act mutant as well as the pfl mutant was constructed in Streptococcus mutans. Pyruvate formate-lyase (PFL) activity was regenerated with the mixture of the respective cell extracts from these mutants by complementary reconstitution of the in vitro reactivating system. The S. mutans act gene encoded the sole enzyme able to activate the PFL protein in this organism.

Pyruvate formate-lyase-activating enzyme: strictly anaerobic isolation yields active enzyme containing a [3Fe-4S](+) cluster

Pyruvate formate-lyase-activating enzyme (PFL-AE) from Escherichia coli (E. coli) catalyzes the stereospecific abstraction of a hydrogen atom from Gly734 of pyruvate formate-lyase (PFL) in a reaction that is strictly dependent on the cosubstrate S-adenosyl-l-methionine (AdoMet). Although PFL-AE is an iron-dependent enzyme, isolation of the enzyme with its metal center intact has proven difficult due to the oxygen sensitivity and lability of the metal center. We report here the first isolation of PFL-AE under nondenaturing, strictly anaerobic conditions. Iron and sulfide analysis as well as UV-visible, EPR, and resonance Raman data support the presence of a [3Fe-4S](+) cluster in the purified enzyme. The isolated native enzyme, but not apo-enzyme, exhibits a high specific activity (31 U/mg) in the absence of added iron, indicating that the native cluster is necessary and sufficient for enzymatic activity.

Lysine 2,3-aminomutase from Clostridium subterminale SB4: mass spectral characterization of cyanogen bromide-treated peptides and cloning, sequencing, and expression of the gene kamA in Escherichia coli

Lysine 2,3-aminomutase (KAM, EC 5.4.3.2.) catalyzes the interconversion of L-lysine and L-beta-lysine, the first step in lysine degradation in Clostridium subterminale SB4. KAM requires S-adenosylmethionine (SAM), which mediates hydrogen transfer in a mechanism analogous to adenosylcobalamin-dependent reactions. KAM also contains an iron-sulfur cluster and requires pyridoxal 5'-phosphate (PLP) for activity. In the present work, we report the cloning and nucleotide sequencing of the gene kamA for C. subterminale SB4 KAM and conditions for its expression in Escherichia coli. The cyanogen bromide peptides were isolated and characterized by mass spectral analysis and, for selected peptides, amino acid and N-terminal amino acid sequence analysis. PCR was performed with degenerate oligonucleotide primers and C. subterminale SB4 chromosomal DNA to produce a portion of kamA containing 1,029 base pairs of the gene. The complete gene was obtained from a genomic library of C. subterminale SB4 chromosomal DNA by use of DNA probe analysis based on the 1,029-base pair fragment. The full-length gene consisted of 1,251 base pairs specifying a protein of 47,030 Da, in reasonable agreement with 47, 173 Da obtained by electrospray mass spectrometry of the purified enzyme. N- and C-terminal amino acid analysis of KAM and its cyanogen bromide peptides firmly correlated its amino acid sequence with the nucleotide sequence of kamA. A survey of bacterial genome databases identified seven homologs with 31 to 72% sequence identity to KAM, none of which were known enzymes. An E. coli expression system consisting of pET 23a(+) plus kamA yielded unsatisfactory expression and bacterial growth. Codon usage in kamA includes the use of AGA for all 29 arginine residues. AGA is rarely used in E. coli, and arginine clusters at positions 4 and 5, 25 and 27, and 134, 135, and 136 apparently compound the barrier to expression. Coexpression of E. coli argU dramatically enhanced both cell growth and expression of KAM. Purified recombinant KAM is equivalent to that purified from C. subterminale SB4.

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, Mössbauer 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.

Recovery of catalytic activity from an inactive aggregated mutant of l-aspartase

Two highly conserved lysyl residues have been replaced with an arginine to examine their role in the mechanism of l-aspartase from Escherichia coli. Replacement of an active-site lysine results in a significant loss of catalytic efficiency [A. S. Saribas, J. F. Schindler, and R. E. Viola (1994) J. Biol. Chem. 269, 6313-6319], while replacement of the second lysine leads to a completely inactive and insoluble protein. Fluorescence spectral evidence has suggested that the loss of activity is due to the misfolding of this aspartase mutant. Some catalytic activity is recovered when the mutant is treated with varying levels of denaturants, and extended treatment with high levels of guanidine.HCl results in the recovery of a substantial fraction of the wild-type activity from this inactive mutant. However, upon removal of the denaturant this mutant enzyme slowly reverts to its inactive and insoluble form. Treatment with an artificial chaperone system in which solubilization by detergent is followed by its removal with beta-cyclodextrin leads to a stable enzyme under nondenaturing conditions with about half the catalytic activity of the wild-type enzyme. These results confirm a structural role for lysine-55 in l-aspartase and demonstrate that additional characterization is required before conclusions can be drawn from the production of an inactive mutant.

Pyruvate formate lyase is structurally homologous to type I ribonucleotide reductase

BACKGROUND

Pyruvate formate lyase (PFL) catalyses a key step in Escherichia coli anaerobic glycolysis by converting pyruvate and CoA to formate and acetylCoA. The PFL mechanism involves an unusual radical cleavage of pyruvate, involving an essential C alpha radical of Gly734 and two cysteine residues, Cys418 and Cys419, which may form thiyl radicals required for catalysis. We undertook this study to understand the structural basis for catalysis.

RESULTS

The first structure of a fragment of PFL (residues 1-624) at 2.8 A resolution shows an unusual barrel-like structure, with a catalytic beta finger carrying Cys418 and Cys419 inserted into the centre of the barrel. Several residues near the active-site cysteines can be ascribed roles in the catalytic mechanism: Arg176 and Arg435 are positioned near Cys419 and may bind pyruvate/formate and Trp333 partially buries Cys418. Both cysteine residues are accessible to each other owing to their cis relationship at the tip of the beta finger. Finally, two clefts that may serve as binding sites for CoA and pyruvate have been identified.

CONCLUSIONS

PFL has striking structural homology to the aerobic ribonucleotide reductase (RNR): the superposition of PFL and RNR includes eight of the ten strands in the unusual RNR alpha/beta barrel as well as the beta finger, which carries key catalytic residues in both enzymes. This provides the first structural proof that RNRs and PFLs are related by divergent evolution from a common ancestor.

Ribonucleotide reductases

Ribonucleotide reductases provide the building blocks for DNA replication in all living cells. Three different classes of enzymes use protein free radicals to activate the substrate. Aerobic class I enzymes generate a tyrosyl radical with an iron-oxygen center and dioxygen, class II enzymes employ adenosylcobalamin, and the anaerobic class III enzymes generate a glycyl radical from S-adenosylmethionine and an iron-sulfur cluster. The X-ray structure of the class I Escherichia coli enzyme, including forms that bind substrate and allosteric effectors, confirms previous models of catalytic and allosteric mechanisms. This structure suggests considerable mobility of the protein during catalysis and, together with experiments involving site-directed mutants, suggests a mechanism for radical transfer from one subunit to the other. Despite large differences between the classes, common catalytic and allosteric mechanisms, as well as retention of critical residues in the protein sequence, suggest a similar tertiary structure and a common origin during evolution. One puzzling aspect is that some organisms contain the genes for several different reductases.

Biochemical and genetic characterization of benzylsuccinate synthase from Thauera aromatica: a new glycyl radical enzyme catalysing the first step in anaerobic toluene metabolism

Toluene is anoxically degraded to CO2 by the denitrifying bacterium Thauera aromatica. The initial reaction in this pathway is the addition of fumarate to the methyl group of toluene, yielding benzylsuccinate as the first intermediate. We purified the enzyme catalysing this reaction, benzylsuccinate synthase (EC 4.1.99-), and studied its properties. The enzyme was highly oxygen sensitive and contained a redox-active flavin cofactor, but no iron centres. The native molecular mass was 220 kDa; four subunits of 94 (alpha), 90 (alpha'), 12 (beta) and 10 kDa (gamma) were detected on sodium dodecyl sulphate (SDS) gels. The N-terminal sequences of the alpha- and alpha'-subunits were identical, suggesting a C-terminal degradation of half of the alpha-subunits to give the alpha'-subunit. The composition of native enzyme therefore appears to be alpha2beta2gamma2. A 5 kb segment of DNA containing the genes for the three subunits of benzylsuccinate synthase was cloned and sequenced. The masses of the predicted gene products correlated exactly with those of the subunits, as determined by electrospray mass spectrometry. Analysis of the derived amino acid sequences revealed that the large subunit of the enzyme shares homology to glycyl radical enzymes, particularly near the predicted radical site. The highest similarity was observed with pyruvate formate lyases and related proteins. The radical-containing subunit of benzylsuccinate synthase is oxygenolytically cleaved at the site of the glycyl radical, producing the alpha'-subunit. The predicted cleavage site was verified using electrospray mass spectrometry. In addition, a gene coding for an activating protein catalysing glycyl radical formation was found. The four genes for benzylsuccinate synthase and the activating enzyme are organized as a single operon; their transcription is induced by toluene. Synthesis of the predicted gene products was achieved in Escherichia coli in a T7-promotor/polymerase system.

Reconstitution and characterization of the polynuclear iron-sulfur cluster in pyruvate formate-lyase-activating enzyme. Molecular properties of the holoenzyme form

The glycyl radical (Gly-734) contained in the active form of pyruvate formate-lyase (PFL) of Escherichia coli is generated by the S-adenosylmethionine-dependent pyruvate formate-lyase-activating enzyme (PFL activase). A 5'-deoxyadenosyl radical intermediate produced by the activase has been suggested as the species that abstracts the pro-S hydrogen of the glycine 734 residue in PFL (Frey, M., Rothe, M., Wagner, A. F. V., and Knappe, J. (1994) J. Biol. Chem. 269, 12432-12437). To enable mechanistic investigations of this system we have worked out a convenient large scale preparation of functionally competent PFL activase from its apoform. The previously inferred metallic cofactor was identified as redox-interconvertible polynuclear iron-sulfur cluster, most probably of the [4Fe-4S] type, according to UV-visible and EPR spectroscopic information. Cys --> Ser replacements by site-directed mutagenesis determined Cys-29, Cys-33, and Cys-36 to be essential to yield active holoenzyme. Gel filtration chromatography showed a monomeric structure (28 kDa) for both the apoenzyme and holoenzyme form. The iron-sulfur cluster complement proved to be a prerequisite for effective binding of adenosylmethionine, which induces a characteristic shift of the EPR signal shape of the reduced enzyme form ([4Fe-4S]+) from axial to rhombic symmetry.

A flavodoxin that is required for enzyme activation: the structure of oxidized flavodoxin from Escherichia coli at 1.8 A resolution

In Escherichia coli, flavodoxin is the physiological electron donor for the reductive activation of the enzymes pyruvate formate-lyase, anaerobic ribonucleotide reductase, and B12-dependent methionine synthase. As a basis for studies of the interactions of flavodoxin with methionine synthase, crystal structures of orthorhombic and trigonal forms of oxidized recombinant flavodoxin from E. coli have been determined. The orthorhombic form (space group P2(1)2(1)2(1), a = 126.4, b = 41.10, c = 69.15 A, with two molecules per asymmetric unit) was solved initially by molecular replacement at a resolution of 3.0 A, using coordinates from the structure of the flavodoxin from Synechococcus PCC 7942 (Anacystis nidulans). Data extending to 1.8-A resolution were collected at 140 K and the structure was refined to an Rwork of 0.196 and an Rfree of 0.250 for reflections with I > 0. The final model contains 3,224 non-hydrogen atoms per asymmetric unit, including 62 flavin mononucleotide (FMN) atoms, 354 water molecules, four calcium ions, four sodium ions, two chloride ions, and two Bis-Tris buffer molecules. The structure of the protein in the trigonal form (space group P312, a = 78.83, c = 52.07 A) was solved by molecular replacement using the coordinates from the orthorhombic structure, and was refined with all data from 10.0 to 2.6 A (R = 0.191; Rfree = 0.249). The sequence Tyr 58-Tyr 59, in a bend near the FMN, has so far been found only in the flavodoxins from E. coli and Haemophilus influenzae, and may be important in interactions of flavodoxin with its partners in activation reactions. The tyrosine residues in this bend are influenced by intermolecular contacts and adopt different orientations in the two crystal forms. Structural comparisons with flavodoxins from Synechococcus PCC 7942 and Anaebaena PCC 7120 suggest other residues that may also be critical for recognition by methionine synthase.

Re-investigation of glucose metabolism in Fibrobacter succinogenes, using NMR spectroscopy and enzymatic assays. Evidence for pentose phosphates phosphoketolase and pyruvate formate lyase activities

The glucose metabolism of Fibrobacter succinogenes S85 was studied in detail; key intermediates and alternative pathways were evidenced by NMR and/or enzymatic assays. A high phosphoketolase activity was detected in four strains of Fibrobacter under strictly anaerobic conditions, with ribose-5-phosphate as substrate, no activity was evidenced with fructose-6-phosphate. This is the first report of a pentose phosphates phosphoketolase in bacteria unable to use pentoses. In contrast, the Entner-Doudoroff pathway and the oxidative branch of the pentose phosphate pathway could not be evidenced. Incubation of living cells of F. succinogenes with Na2(13)CO3 confirmed the incorporation of 13CO2 in the carboxylic group of succinate. The presence of fumarase was evidenced by in vivo 4C-NMR using 2-heptyl-4-hydroxyquinoline-N-oxide (HQNO): the enzyme showed a high reversibility under physiological conditions. The production of formate from glucose catabolism was evidenced by enzymatic assay and by NMR and a pyruvate formate lyase activity was detected using strictly anaerobic conditions.

The structure of the C-terminal domain of methionine synthase: presenting S-adenosylmethionine for reductive methylation of B12

BACKGROUND

In both mammalian and microbial species, B12-dependent methionine synthase catalyzes methyl transfer from methyltetrahydrofolate (CH3-H4folate) to homocysteine. The B12 (cobalamin) cofactor plays an essential role in this reaction, accepting the methyl group from CH3-H4folate to form methylcob(III)alamin and in turn donating the methyl group to homocysteine to generate methionine and cob(I)alamin. Occasionally the highly reactive cob(I)alamin intermediate is oxidized to the catalytically inactive cob(II)alamin form. Reactivation to sustain enzyme activity is achieved by a reductive methylation, requiring S-adenosylmethionine (AdoMet) as the methyl donor and, in Esherichia coli, flavodoxin as an electron donor. The intact system is controlled and organized so that AdoMet, rather than methyltetrahydrofolate, is the methyl donor in the reactivation reaction. AdoMet is not wasted as a methyl donor in the catalytic cycle in which methionine is synthesized from homocysteine. The structures of the AdoMet binding site and the cobalamin-binding domains (previously determined) provide a starting point for understanding the methyl transfer reactions of methionine synthase.

RESULTS

We report the crystal structure of the 38 kDa C-terminal fragment of E.coli methionine synthase that comprises the AdoMet-binding site and is essential for reactivation. The structure, which includes residues 901-1227 of methionine synthase, is a C-shaped single domain whose central feature is a bent antiparallel betasheet. Database searches indicate that the observed polypeptide has no close relatives. AdoMet binds near the center of the inner surface of the domain and is held in place by both side chain and backbone interactions.

CONCLUSIONS

The conformation of bound AdoMet, and the interactions that determine its binding, differ from those found in other AdoMet-dependent enzymes. The sequence Arg-x-x-x-Gly-Tyr is critical for the binding of AdoMet to methionine synthase. The position of bound AdoMet suggests that large areas of the C-terminal and cobalamin-binding fragments must come in contact in order to transfer the methyl group of AdoMet to cobalamin. The catalytic and activation cycles may be turned off and on by alternating physical separation and approach of the reactants.

Bacteriophage T4 anaerobic ribonucleotide reductase contains a stable glycyl radical at position 580

It has been recently recognized that the class III anaerobic ribonucleotide reductase requires the presence of a second activating gene product, NrdG. We have proposed that the role for NrdG involves the generation of an oxygen sensitive glycyl free radical within the NrdD enzyme. In this article we present the generation of such a glycyl free radical within the T4 NrdD subunit and its dependence upon the phage NrdG subunit. Initially, an overexpression system was created that allowed the joint production of T4 NrdD and T4 NrdG. With this system and in the presence of T4 NrdG, an oxygen-sensitive cleavage of NrdD was observed that mimicked the cleavage observed in phage infected Escherichia coli extracts. Under anaerobic conditions the presence of T4 NrdD with NrdG revealed a strong doublet EPR signal (g = 2.0039). Isotope labeling of the NrdD with [2H]glycine and [13C]glycine, respectively, confirmed the presence of a stabilized glycine radical. The unpaired electron is strongly coupled to C-2 in glycine and the doublet splitting originates from one of the alpha-protons. The glycine residue at position 580 was determined to be the radical containing residue through site-directed mutagenesis studies involving a G580A NrdD mutant. The glycyl radical generation was specific for the T4 NrdG, and the host E. coli NrdG was found to be unable to activate the phage reductase. Finally, anaerobic purification revealed the holoenzyme complex to contain iron, whereas the NrdD polypeptide was found to lack the metal. Our results suggest a tetrameric structure for the T4 anaerobic ribonucleotide reductase containing one homodimer each of NrdD and NrdG, with a single glycyl radical present.

The anaerobic Escherichia coli ribonucleotide reductase. Subunit structure and iron sulfur center

During anaerobic growth Escherichia coli uses a specific ribonucleoside triphosphate reductase for the production of deoxyribonucleoside triphosphates. The active species of this enzyme was previously found to be a large homodimer of 160 kDa (alpha 2) with a stable, oxygen-sensitive radical located at Gly-681 of the 80-kDa polypeptide chain. The radical is formed in an enzymatic reaction involving S-adenosylmethionine, NADPH, a reducing flavodoxin system and an additional 17.5-kDa polypeptide, previously called activase. Here, we demonstrate by EPR spectroscopy that this small protein contains a 4Fe-4S cluster that joins two peptides in a 35-kDa small homodimer (beta 2). A degraded form of this cluster may have been responsible for an EPR signal observed earlier in preparations of the large 160-kDa subunit that suggested the presence of a 3Fe-4S cluster in the reductase. These preparations were contaminated with a small amount of the small protein. The large and the small proteins form a tight complex. From sucrose gradient centrifugation, we determined a 1:1 stoichiometry of the two proteins in the complex. The anaerobic reductase thus has an alpha 2 beta 2 structure. We speculate that the small protein interacts with S-adenosylmethionine and forms a transient radical involved in the generation of the stable glycyl radical in the large protein that participates in the catalytic process.

A radical approach to enzyme catalysis

Free radicals are generally perceived as highly reactive species which are harmful to biological systems. There are, however, a number of enzymes that use carbon-based radicals to catalyse a variety of important and unusual reactions. The most prominent example is ribonucleotide reductase, an enzyme which is crucial for the synthesis of DNA. In general, radicals are used to remove hydrogen from unreactive positions in the substrate, and in this way the substrate is activated to undergo chemical transformations that would otherwise be difficult to achieve. Several different mechanisms have evolved which allow enzymes to generate and maintain radicals in increasingly aerobic environments. An unexpected finding is the existence of stable protein-based radicals, residing on a variety of amino-acid side chains, which serve to link the radical-generating and catalytic sites and to store the radical between turnovers.

Generation of the glycyl radical of the anaerobic Escherichia coli ribonucleotide reductase requires a specific activating enzyme

The anaerobic ribonucleotide reductase from Escherichia coli contains a glycyl radical as part of its polypeptide structure. The radical is generated by an enzyme system present in E. coli. The reductase is coded for by the nrdD gene located at 96 min. Immediately downstream, we now find an open reading frame with the potential to code for a 17.5-kDa protein with sequence homology to a protein required for the generation of the glycyl radical of pyruvate formate lyase. The protein corresponding to this open reading frame is required for the generation of the glycyl radical of the anaerobic reductase and binds tightly to the reductase. The "activase" contains iron, required for activity. The general requirements for generation of a glycyl radical are identical for the reductase and pyruvate formate lyase. For the reductase, the requirement of an iron-containing activase suggests the possibility that the iron-sulfur cluster of the enzyme is not involved in radical generation but may participate directly in the reduction of the ribonucleotide.