Glycyl Radical Research Articles

The Anaerobic (Class III) Ribonucleotide Reductase fromLactococcus lactis: CATALYTIC PROPERTIES AND ALLOSTERIC REGULATION OF THE PURE ENZYME SYSTEM

Lactococcus lactis contains an operon with the genes (nrdD and nrdG) for a class III ribonucleotide reductase. Strict anaerobic growth depends on the activity of these genes. Both were sequenced, cloned, and overproduced in Escherichia coli. The corresponding proteins, NrdD and NrdG, were purified close to homogeneity. The amino acid sequences of NrdD (747 residues, 84.1 kDa) and NrdG (199 residues, 23.3 kDa) are 53 and 42% identical with the respective E. coli proteins. Together, they catalyze the reduction of ribonucleoside triphosphates to the corresponding deoxyribonucleotides in the presence of S-adenosylmethionine, reduced flavodoxin or reduced deazaflavin, potassium ions, dithiothreitol, and formate. EPR experiments demonstrated a [4Fe-4S](+) cluster in reduced NrdG and a glycyl radical in activated NrdD, similar to the E. coli NrdD and NrdG proteins. Different from E. coli, the two polypeptides of NrdD and the proteins in the NrdD-NrdG complex were only loosely associated. Also the FeS cluster was easily lost from NrdG. The substrate specificity and overall activity of the L. lactis enzyme was regulated according to the general rules for ribonucleotide reductases. Allosteric effectors bound to two separate sites on NrdD, one binding dATP, dGTP, and dTTP and the other binding dATP and ATP. The two sites showed an unusually high degree of cooperativity with complex interactions between effectors and a fine-tuning of their physiological effects. The results with the L. lactis class III reductase further support the concept of a common origin for all present day ribonucleotide reductases.

Glycyl radical enzymes: a conservative structural basis for radicals.

The first structures of glycyl radical enzymes, the anaerobic ribonucleotide reductase from bacteriophage T4 and pyruvate formate lyase from Escherichia coli, have been recently determined. This work provides new insights into the structure and chemistry of glycyl radical sites.

Iron-sulfur interconversions in the anaerobic ribonucleotide reductase from Escherichia coli.

The anaerobic ribonucleotide reductase from Escherichia coli contains an iron-sulfur cluster which, in the reduced [4Fe-4S](+) form, serves to reduce S-adenosylmethionine and to generate a catalytically essential glycyl radical. The reaction of the reduced cluster with oxygen was studied by UV-visible, EPR, NMR, and Mössbauer spectroscopies. The [4Fe-4S](+) form is shown to be extremely sensitive to oxygen and converted to [4Fe-4S](2+), [3Fe-4S](+/0), and to the stable [2Fe-2S](2+) form. It is remarkable that the oxidized protein retains full activity. This is probably due to the fact that during reduction, required for activity, the iron atoms, from 2Fe and 3Fe clusters, readily reassemble to generate an active [4Fe-4S] center. This property is discussed as a possible protective mechanism of the enzyme during transient exposure to air. Furthermore, the [2Fe-2S] form of the protein can be converted into a [3Fe-4S] form during chromatography on dATP-Sepharose, explaining why previous preparations of the enzyme were shown to contain large amounts of such a 3Fe cluster. This is the first report of a 2Fe to 3Fe cluster conversion.

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.

Pre-steady-state kinetic investigation of intermediates in the reaction catalyzed by adenosylcobalamin-dependent glutamate mutase.

Glutamate mutase catalyzes the reversible isomerization of L-glutamate to L-threo-3-methylaspartate. Rapid quench experiments have been performed to measure apparent rate constants for several chemical steps in the reaction. The formation of substrate radicals when the enzyme was reacted with either glutamate or methylaspartate was examined by measuring the rate at which 5'-deoxyadenosine was formed, and shown to be sufficiently fast for this step to be kinetically competent. Furthermore, the apparent rate constant for 5'-deoxyadenosine formation was very similar to that measured previously for cleavage of the cobalt-carbon bond of adenosylcobalamin by the enzyme, providing further support for a mechanism in which homolysis of the coenzyme is coupled to hydrogen abstraction from the substrate. The pre-steady-state rates of methylaspartate and glutamate formation were also investigated. No burst phase was observed with either substrate, indicating that product release does not limit the rate of catalysis in either direction. For the conversion of glutamate to methylaspartate, a single chemical step appeared to dominate the overall rate, whereas in the reverse direction a lag phase was observed, suggesting the accumulation of an intermediate, tentatively ascribed to glycyl radical and acrylate. The rates of formation and decay of this intermediate were also sufficiently rapid for it to be kinetically competent. When combined with information from previous mechanistic studies, these results allow a qualitative free energy profile to constructed for the reaction catalyzed by glutamate mutase.

A megaplasmid-borne anaerobic ribonucleotide reductase in Alcaligenes eutrophus H16.

The conjugative 450-kb megaplasmid pHG1 is essential for the anaerobic growth of Alcaligenes eutrophus H16 in the presence of nitrate as the terminal electron acceptor. We identified two megaplasmid-borne genes (nrdD and nrdG) which are indispensable under these conditions. Sequence alignment identified significant similarity of the 76.2-kDa gene product NrdD and the 30.9-kDa gene product NrdG with anaerobic class III ribonucleotide reductases and their corresponding activases. Deletion of nrdD and nrdG in A. eutrophus abolished anaerobic growth and led to the formation of nondividing filamentous cells, a typical feature of bacteria whose DNA synthesis is blocked. Enzyme activity of NrdD-like ribonucleotide reductases is dependent on a stable radical at a glycine residue in a conserved C-terminal motif. A mutant of A. eutrophus with a G650A exchange in NrdD showed the DNA-deficient phenotype as the deletion strain, suggesting that G650 forms the glycyl radical. Analysis of transcriptional and translational fusions indicate that nrdD and nrdG are cotranscribed and that the translation efficiency of nrdD is 40-fold higher than that of nrdG. Thus, the two proteins NrdD and NrdG are not synthesized at a stoichiometric level.

Glycyl Radical Is a Stable Species in the Gas Phase

Glycyl Radical Is a Stable Species in the Gas Phase

Assembly of 2Fe-2S and 4Fe-4S Clusters in the Anaerobic Ribonucleotide Reductase from Escherichia coli

Escherichia coli contains a specific ribonucleotide reductase for deoxyribonucleotide synthesis and growth under anaerobiosis. The α2β2 enzyme contains an iron−sulfur center on its small β2 subunit that is involved in the one-electron reduction of S-adenosylmethionine and in the generation of a glycyl radical on the large α2 subunit. By a variety of spectroscopic methods (light absorption, resonance Raman, and Mössbauer spectroscopy) and metal and sulfide analysis, it is shown that the metal center is a (2Fe-2S)2+ cluster. Reduction by photoreduced deazaflavin or dithionite converts these centers mostly into (4Fe-4S) clusters, in both the (4Fe-4S)1+ and (4Fe-4S)2+ states, as is unambiguously demonstrated by Mössbauer spectroscopy at 4.2 and 77 K, in the presence of small (10 mT) or high (5.3 or 7 T) fields. The structure and the function of the iron−sulfur center of the anaerobic ribonucleotide reductase are discussed in relation with other members of a class of enzymes with similar metal centers and functions (reduction of S-adenosylmethionine).

A glycyl radical site in the crystal structure of a class III ribonucleotide reductase.

Ribonucleotide reductases catalyze the reduction of ribonucleotides to deoxyribonucleotides. Three classes have been identified, all using free-radical chemistry but based on different cofactors. Classes I and II have been shown to be evolutionarily related, whereas the origin of anaerobic class III has remained elusive. The structure of a class III enzyme suggests a common origin for the three classes but shows differences in the active site that can be understood on the basis of the radical-initiation system and source of reductive electrons, as well as a unique protein glycyl radical site. A possible evolutionary relationship between early deoxyribonucleotide metabolism and primary anaerobic metabolism is suggested.

A Dehydroalanyl Residue Can Capture the 5′-Deoxyadenosyl Radical Generated fromS-Adenosylmethionine by Pyruvate Formate-Lyase-Activating Enzyme

The glycyl radical (Gly-734) contained in the active form of pyruvate formate-lyase (PFL) ofEscherichia coliis produced post-translationally by pyruvate formate-lyase-activating enzyme (PFL activase), employing adenosylmethionine (AdoMet) and dihydroflavodoxin as co-substrates. Previous2H-labelings found incorporation of the pro-Shydrogen of Gly-734 into the 5′-deoxyadenosine co-product, indicating that a deoxyadenosyl radical intermediate, generated by reductive cleavage of AdoMet, serves as the actual H atom abstracting species in this system. We have now examined an octapeptide (Suc-Arg-Val-Pro-ΔAla-Tyr-Ala-Val-Arg-NH2) that is analogous to the Gly-734 site of the PFL polypeptide but contains a dehydroalanyl residue (ΔAla) in the glycyl position. Applied to the PFL activase reaction, this peptide becomesC-adenosylated at the olefinic β carbon of ΔAla. The modified peptide was isolated in μmol-quantities and characterized, after chymotryptic truncation, by MS and 2D NMR. PFL activase functions catalytically (kcat≥ 1 min−1) in the peptide modification reaction, which occurs with stoichiometric consumption of AdoMet. The mechanism appears to involve addition of the nucleophilic deoxyadenosyl radical to the electrophilic CC double bond of ΔAla, followed by quenching of the peptide backbone-centered adduct radical by the buffer medium. The trapping-property of the ΔAla residue should be exploitable in investigating of how the Fe4S4protein PFL activase generates the highly reactive deoxyadenosyl radical.

Biochemistry, physiology and molecular biology of glycyl radical enzymes

Enzymes that contain a glycyl radical are functional only in the absence of oxygen. When synthesised, these proteins are catalytically inactive and must undergo activation through the process of hydrogen atom abstraction from a C-terminally located glycyl residue in the polypeptide chain. This process is catalysed by an iron–sulfur-containing activating enzyme that utilises S-adenosylmethionine as substrate, and a one-electron donor, usually dihydroflavodoxin. The 4Fe–4S cluster in the activating enzyme is directly involved in redox catalysis, generating a transient 5′-deoxyadenosyl radical intermediate that is proposed to be the hydrogen atom abstracting species. DNA sequence analysis has revealed that the genes encoding the glycyl radical enzyme and its cognate activating protein are either co-transcribed or are adjacent on the chromosome. Recent genomic analyses have revealed that glycyl radical enzymes may be widespread amongst obligate and facultative anaerobic microbes.

Catalytic Mechanism of Pyruvate Formate-Lyase (PFL). A Theoretical Study

Pyruvate formate-lyase (PFL) is a glycyl radical containing enzyme that catalyzes the reversible CoA-dependent conversion of pyruvate into acetyl-CoA and formate. We have studied the catalytic mechanism of this enzyme by means of accurate quantum chemical methods. It is shown that an overall homolytic radical mechanism is very feasible. In particular, the formation of a tetrahedral radical intermediate, by addition of thiyl radical to pyruvate, is supported by the calculated reaction energies and barriers. Furthermore, we propose that the thioester exchange between active site cysteine and CoA proceeds via a radical mechanism. This is made possible by the quenching of the formate radical by Cys418, and not Gly734, as previously proposed.

A glycyl radical solution: oxygen-dependent interconversion of pyruvate formate-lyase.

Pyruvate formate-lyase (PFL) catalyses the non-oxidative dissimilation of pyruvate to formate and acetyl-CoA using a radical-chemical mechanism. The enzyme is enzymically interconverted between inactive and active forms, the active form contains an organic free radical located on a glycyl residue in the C-terminal portion of the polypeptide chain. Introduction of the radical into PFL only occurs anaerobically, and the activating enzyme responsible is an iron-sulphur protein that uses S-adenosyl methionine as cofactor and reduced flavodoxin as reductant. As the radical form of PFL is inactivated by molecular oxygen it is safeguarded during the transition to aerobiosis by conversion back to the radical-free, oxygen-stable form. This reaction is catalysed by the anaerobically induced multimeric enzyme alcohol dehydrogenase. The genes encoding PFL and its activating enzyme are adjacent on the chromosome but form discrete transcriptional units. This genetic organization is highly conserved in many, but not all, organisms that have PFL. Recent studies have shown that proteins exhibiting significant similarity to PFL and its activating enzyme are relatively widespread in facultative and obligate anaerobic eubacteria, as well as archaea. The physiological function of many of these PFL-like enzymes remains to be established. It is becoming increasingly apparent that glycyl radical enzymes are more prevalent than previously surmised. They represent a class of enzymes with unusual biochemistry and probably predate the appearance of molecular oxygen.

Ribonucleotide reductases and radical reactions.

Ribonucleotide reductases (RNRs) catalyse the reduction of ribonucleotides to deoxyribonucleotides. They play a pivotal role in the regulation of DNA synthesis and are targets for antiproliferative drugs. Ribonucleotide reductases are unique enzymes in that they all require a protein radical for activity. Class I nonheme iron RNRs (mammals, plants, Escherichia coli) use a tyrosyl/cysteinyl radical pair, class II adenosylcobalamin RNRs (prokaryotes, archaea) a cysteinyl radical, class III iron-sulphur RNRs (facultative anaerobes) a glycyl radical. Here we describe the reactivity of these radicals with respect to the natural ribonucleotide substrates as well as to a variety of enzyme inhibitors, radical scavengers, nitric oxide, superoxide radicals and substrate analogues.

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.

Novel keto acid formate-lyase and propionate kinase enzymes are components of an anaerobic pathway in Escherichia coli that degrades L-threonine to propionate.

An immunological analysis of an Escherichia coli strain unable to synthesize the main pyruvate formate-lyase enzyme Pfl revealed the existence of a weak, cross-reacting 85 kDa polypeptide that exhibited the characteristic oxygen-dependent fragmentation typical of a glycyl radical enzyme. Polypeptide fragmentation of this cross-reacting species was shown to be dependent on Pfl activase. Cloning and sequence analysis of the gene encoding this protein revealed that it coded for a new enzyme, termed TdcE, which has 82% identity with Pfl. On the basis of RNA analyses, the tdcE gene was shown to be part of a large operon that included the tdcABC genes, encoding an anaerobic threonine dehydratase, tdcD, coding for a propionate kinase, tdcF, the function of which is unknown, and the tdcG gene, which encodes a L-serine dehydratase. Expression of the tdcABCDEFG operon was strongly catabolite repressed. Enzyme studies showed that TdcE has both pyruvate formate-lyase and 2-ketobutyrate formate-lyase activity, whereas the TdcD protein is a new propionate/acetate kinase. By monitoring culture supernatants from various mutants using 1H nuclear magnetic resonance (NMR), we followed the anaerobic conversion of L-threonine to propionate. These studies confirmed that 2-ketobutyrate, the product of threonine deamination, is converted in vivo by TdcE to propionyl-CoA. These studies also revealed that Pfl and an as yet unidentified thiamine pyrophosphate-dependent enzyme(s) can perform this reaction. Double null mutants deficient in phosphotransacetylase (Pta) and acetate kinase (AckA) or AckA and TdcD were unable to metabolize threonine to propionate, indicating that propionyl-CoA and propionyl-phosphate are intermediates in the pathway and that ATP is generated during the conversion of propionyl-P to propionate by AckA or TdcD.

On the local structure of the glycyl radical in different enzymes

Full hyperfine coupling tensors are computed for different geometric conformers of the glycyl radical, using gradient corrected Density Functional Theory (DFT) together with large basis sets (IGLO-III). Comparison is made with three enzymes in which the radical is present, namely Escherichia coli pyruvate formate lyase (PFL), Escherichia coli anaerobic ribonucleotide reductase (RNR) and bacteriophage T4 anaerobic RNR. The excellent agreement in hyperfine coupling constants between theory and experiment confirms again that the radical is a glycyl radical and that, although embedded in the protein, it maintains the planar gas phase structure in both E. coli PFL and E. coli RNR. In contrast to these two systems, we propose a non-planar structure for bacteriophage T4 anaerobic RNR, in order to explain the unusually high Azz(13Cα) coupling (66 G) recently measured by Sjöberg et al.18

Dioxygen inactivation of pyruvate formate-lyase: EPR evidence for the formation of protein-based sulfinyl and peroxyl radicals.

We here report EPR studies that provide evidence for radical intermediates generated from the glycyl radical of activated pyruvate formate-lyase (PFL) during the process of oxygen-dependent enzyme inactivation, radical quenching, and protein fragmentation. Upon exposure of active PFL to air, a long-lived radical intermediate was generated, which exhibits an EPR spectrum assigned to a sulfinyl radical (RSO*). The EPR spectrum of a sulfinyl radical was also generated from the activated C418A mutant of PFL, indicating that Cys 418 is not the site of sulfinyl radical formation. Exposure of the activated C419A mutant or C418AC419A double mutant to air on the other hand, resulted in a new EPR spectrum that we assign to the alpha-carbon peroxyl radical (ROO*) of the active-site glycine, G734. These findings suggest that C419 is the site of sulfinyl radical formation and that replacement of this cysteine with alanine results in the accumulation of the carbon peroxyl radical. The results also support the proposal that the peroxyl radical and the sulfinyl radical are intermediates in the oxygen-dependent inactivation and cleavage of the protein. Moreover, these observations are consistent with the hypothesis that C419 and G734 are in close proximity in the activated enzyme and may participate in a glycyl/thiyl radical equilibrium. A mechanism that accounts for the formation of the radical intermediates is proposed.