Modification of Cys-418 of pyruvate formate-lyase by methacrylic acid, based on its radical mechanism

The recently determined crystal structure of pyruvate formate-lyase (PFL) suggested a new view of the mechanism of this glycyl radical enzyme, namely that intermediary thiyl radicals of Cys-418 and Cys-419 participate in different ways [Becker, A. et al. (1999) Nat. Struct. Biol. 6, 969-975]. We report here a suicide reaction of PFL that occurs with the substrate-analog methacrylate with retention of the protein radical (K(I)=0.42 mM, k(i)=0.14 min(-1)). Using [1-(14)C]methacrylate (synthesized via acetone cyanhydrin), the reaction end-product was identified by peptide mapping and cocrystallization experiments as S-(2-carboxy-(2S)-propyl) substituted Cys-418. The stereoselectivity of the observed Michael addition reaction is compatible with a radical mechanism that involves Cys-418 thiyl as nucleophile and Cys-419 as H-atom donor, thus supporting the functional assignments of these catalytic amino acid residues derived from the protein structure.     

Inactivation of pyruvate formate-lyase by dioxygen: defining the mechanistic interplay of glycine 734 and cysteine 419 by rapid freeze-quench EPR

Pyruvate formate-lyase from Escherichia coli (EC 2.3.1.54; PFL) catalyzes the reversible anaerobic conversion of pyruvate and CoA into acetyl-CoA and formate. Active PFL contains a novel alpha-carbon centered glycyl radical at G734 that is required for its catalytic activity. Two adjacent cysteine residues, C418 and C419, are essential for PFL activity according to site-directed mutagenesis studies. Upon exposure to air, active PFL loses its activity with the concomitant loss of the glycyl radical. Previous EPR studies of dioxygen inactivation of PFL revealed protein-based peroxyl and sulfinyl radicals during the manual mixing and quenching process [Reddy et al. (1998) Biochemistry 37, 558-563]. To probe the mechanism of this process, we carried out experiments using rapid freeze-quench EPR spectroscopy. Upon mixing of active wild type or C418A PFL with oxygenated solution, a short-lived radical intermediate appears at the earliest time point (10 ms), followed by the appearance of a long-lived sulfinyl radical. The axial EPR spectrum of this short-lived radical (g = 2.034, 2.007) is characteristic of a peroxyl radical. When C419A PFL or the double mutant [C418A/C419A] PFL was mixed with oxygenated solution, the peroxyl radical was also observed at 10 ms but in this case persisted over 12 s. These observations provide compelling evidence to support a proposed mechanism in which dioxygen quenches the glycyl radical in the active enzyme and the resulting peroxyl radical may react further with the sulfhydryl group of the C419 residue to form the sulfinyl radical.     

The free radical of pyruvate formate-lyase. Characterization by EPR spectroscopy and involvement in catalysis as studied with the substrate-analogue hypophosphite

The first-derivative EPR spectrum of the active form of Escherichia coli pyruvate formate-lyase shows an asymmetric doublet with partially resolved hyperfine splittings (g = 2.0037). Isotope substitution studies demonstrated couplings of a carbon-centered unpaired electron to a solvent-exchangeable proton (a = 1.5 mT) and to further hydrogen nuclei (a = 0.36 and 0.57 mT). By selective incorporation of unlabelled tyrosine into 2H-labelled enzyme protein, a tyrosyl radical structure has been ruled out. Circumstantial evidence indicates that the organic free radical, which also displays an ultraviolet absorption signal at 365 nm, is located on a standard amino acid residue of the polypeptide chain. EPR signal quantification found a stoichiometry of 1 spin per active site. The formate analogue hypophosphite has been characterized as a specific kcat inhibitor of pyruvate formate-lyase which destroys the enzyme radical. Protein-linked 1-hydroxyethylphosphonate was previously described as the dead-end product after reaction of the analogue with the intermediary acetyl-enzyme form of the catalytic cycle [W. Plaga et al. (1988) Eur. J. Biochem. 178, 445-450]. EPR spectroscopy of this system has now identified the corresponding alpha-phosphoryl radical as a reaction intermediate [g = 2.0032; a(P) = 2.72 mT, a(3H) = 1.96 mT]; it showed a half-life of about 20 min at 0 degrees C. This finding proves that the enzyme radical is a hydrogen-atom-transferring coenzymic element.     

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.     

X-ray structure of pyruvate formate-lyase in complex with pyruvate and CoA. How the enzyme uses the Cys-418 thiyl radical for pyruvate cleavage

The glycyl radical enzyme pyruvate formate-lyase (PFL) synthesizes acetyl-CoA and formate from pyruvate and CoA. With the crystal structure of the non-radical form of PFL in complex with its two substrates, we have trapped the moment prior to pyruvate cleavage. The structure reveals how the active site aligns the scissile bond of pyruvate for radical attack, prevents non-radical side reactions of the pyruvate, and confines radical migration. The structure shows CoA in a syn conformation awaiting pyruvate cleavage. By changing to an anti conformation, without affecting the adenine binding mode of CoA, the thiol of CoA could pick up the acetyl group resulting from pyruvate cleavage.     

Structure and mechanism of the glycyl radical enzyme pyruvate formate-lyase.

Pyruvate formate-lyase (PFL) from Escherichia coli uses a radical mechanism to reversibly cleave the C1-C2 bond of pyruvate using the Gly 734 radical and two cysteine residues (Cys 418, Cys 419). We have determined by X-ray crystallography the structures of PFL (non-radical form), its complex with the substrate analog oxamate, and the C418A,C419A double mutant. The atomic model (a dimer of 759-residue monomers) comprises a 10-stranded beta/alpha barrel assembled in an antiparallel manner from two parallel five-stranded beta-sheets; this architecture resembles that of ribonucleotide reductases. Gly 734 and Cys 419, positioned at the tips of opposing hairpin loops, meet in the apolar barrel center (Calpha-Sgamma = 3.7 A). Oxamate fits into a compact pocket where C2 is juxtaposed with Cys 418Sgamma (3.3 A), which in turn is close to Cys 419Sgamma (3.7 A). Our model of the active site is suggestive of a snapshot of the catalytic cycle, when the pyruvate-carbonyl awaits attack by the Cys 418 thiyl radical. We propose a homolytic radical mechanism for PFL that involves Cys 418 and Cys 419 both as thiyl radicals, with distinct chemical functions.     

Equilibrium constant for conversion of pyruvate to acetyl phosphate and formate

Preparations of pyruvate formate-lyase were made from Escherichia coli cells. Net reversal of the "phosphoroclastic split" of pyruvate was readily demonstrated with these preparations. Incubation of acetyl phosphate with formate resulted in the accumulation of pyruvate in concentrations up to 0.5 mm. Catalytic amounts of coenzyme A were essential. Pyruvate was also readily formed from acetyl coenzyme A and formate. The equilibrium constant of the reaction (pyruvate(-) + HPO(4) (2-) --> acetyl phosphate(2-) + formate(-)) has been determined to be about 23 at 37 C.     

Pyruvate degradation via pyruvate formate-lyase (EC 2.3.1.54) and the enzymes of formate fermentation in the green alga Chlorogonium elongatum

Formate was formed in extracts of Chlorogonium elongatum via direct cleavage of pyruvate by a pyruvate formate-lyase (PFL, EC 2.3.1.54). The conversion of PFL to the catalytically active form required S-adenosylmethionine, ferric (2+), photoreduced deazariboflavin as reductant, pyruvate as allosteric effector and strict anaerobic conditions. At the optimum pH (pH 8.0), PFL catalyzed formate formation, pyruvate synthesis and the isotope exchange from [¹⁴C]formate into pyruvate with rates of 30.0, 1.5 and 1.2 nmol min^-1 mg^-1 protein, respectively. Treatment of the active enzyme with O₂ irreversibly inactivated PFL activity (half-time 2 min). In addition to PFL, the activities of phosphotransacetylase (EC 2.3.1.8), acetate kinase (EC 2.7.2.1), aldehyde dehydrogenase (CoA acetylating, EC 1.2.1.10) and alcohol dehydrogenase (EC 1.1.1.1) were also detected in extracts of C. elongatum. The occurrence of these enzymes indicates pyruvate degradation via a formate-fermentation pathway during anaerobiosis of algal cells in the dark.Abbreviations DTT dithiothreitol - Hepes 4-(2-hydroxyethyl)-1-piperazine+ethane sulfonic acid - PFL pyruvate formate-lyase     

Structure of the N-terminal region of Haemophilus influenzae H10017: implications for function

Haemophilus influenzae is a gram-negative pathogen that causes infections ranging from asymptomatic colonization of the human upper respiratory tract to serious invasive diseases such as meningitis. Although the genome of Haemophilus influenzae has been completely sequenced, the structure and function of many of these proteins are unknown. HI0017 is one of these uncharacterized proteins. Here we describe the three-dimensional solution structure of the N-terminal portion of HI0017 as determined by NMR spectroscopy. The structure consists of a five-stranded antiparallel -sheet and two short -helices. It is similar to the C-terminal domain of Diphtheria toxin repressor (DtxR). The C-terminal portion of HI0017 has an amino acid sequence that closely resembles pyruvate formate-lyase – an enzyme that converts pyruvate and CoA into acetyl-CoA and formate by a radical mechanism. Based on structural and sequence comparisons, we propose that the C-terminus of HI0017 functions as an enzyme with a glycyl radical mechanism, while the N-terminus participates in protein/protein interactions involving an activase (iron-sulfur protein) and/or the substrate.     

Inactivation of Escherichia coli pyruvate formate-lyase by hypophosphite: evidence for a rate-limiting phosphorus-hydrogen bond cleavage

Recently, Knappe and co-workers [Knappe, J., Neugebauer, F. A., Blaschkowski, H. P., & Ganzler, M. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 1332] have shown that the catalytically active form of pyruvate formate-lyase from Escherichia coli is associated with a protein-bound organic free radical which is quenched upon enzyme inactivation by oxygen or hypophosphite. Our interest in the chemical mechanism of this unusual enzymatic reaction has led us to investigate several key aspects of the inactivation of the lyase by hypophosphite and its relationship to the normal enzymatic reaction. We report here that the inactivation of both the free and acetylated forms of the lyase is subject to a primary kinetic isotope effect using [2H2]hypophosphite. This suggests that phosphorus-hydrogen bond cleavage is at least partially rate limiting during inactivation. In addition, the inactivated enzyme can be fully reactivated. We have also determined a Vmax/Km isotope effect of 3.6 +/- 0.7 for pyruvate formation from [2H]formate and acetyl coenzyme A. Thus, carbon-hydrogen bond cleavage is partially rate limiting in the normal reverse reaction. On the basis of our findings, the previous work of Knappe and co-workers, the likelihood that hypophosphite is a formate analogue, the known susceptibility of both hypophosphite and formate to homolysis, and a chemical precedent for homolytic cleavage of pyruvate, we offer a preliminary mechanistic proposal for the lyase reaction.     

S-adenosylmethionine-dependent enzyme activation

S-Adenosylmethionine (SAM)-dependent activations of pyruvate formate-lyase, lysine 2,3-aminomutase and cobalamin-dependent methionine synthase are discussed. In each case, cleavage of SAM is accompanied by the formation of a catalytically active enzyme. The chemistry of activation of these three enzymes falls into three distinct classes: generation of an essential enzyme radical (pyruvate formate-lyase), formation of a catalytically active 5'-deoxyadenosyl radical (lysine 2,3-aminomutase) and reductive methylation to form a required methylcobalamin complex (methionine synthase).     

Primary structures of Escherichia coli pyruvate formate-lyase and pyruvate-formate-lyase-activating enzyme deduced from the DNA nucleotide sequences

The structural gene of pyruvate formate-lyase (pfl) and that of pyruvate-formate-lyase-activating enzyme were shown to be adjacent on the chromosomal map of Escherichia coli. DNA sequencing was performed along a stretch of 3592 nucleotides to obtain the amino acid sequences of both proteins. The derived primary structures (759 and 245 residues) were confirmed by partial structure analyses on the purified proteins. The open reading frames are separated by a 194-nucleotide stretch, and their flanking regions include signal elements that are compatible with separate control of protein synthesis from the two genes.     

Effect of inactivation of nuo and ackA-pta on redistribution of metabolic fluxes in Escherichia coli.

The nuoA-N gene cluster encodes a transmembrane NADH:ubiquinone oxidoreductase (NDH-I) responsible for coupling redox chemistry to proton-motive force generation. Interactions between nuo and the acetate-producing pathway encoded by ackA-pta were investigated by examining the metabolic patterns of several mutant strains under anaerobic growth conditions. In an ackA-pta strain, the flux to acetate was decreased dramatically, whereas flux to lactate was increased significantly when compared with its parent strain; the fluxes to pyruvate and ethanol also increased slightly. In addition, pyruvate was excreted. A strain carrying the nuo mutation showed metabolic flux distribution similar to the wild type. The ackA-pta-nuo strain showed a different metabolic pattern. It not only exhibited reduced acetate accumulation but also significantly lower ethanol and formate synthesis. Metabolic flux distribution analysis suggests that the excessive carbon flux was redirected at the pyruvate node through the lactate dehydrogenase pathway for lactate formation rather than the pyruvate formate-lyase (PFL) pathway for acetyl-CoA and formate production. The diminished capacity through the formate and ethanol (ADH) pathways was not the result of genetic disruption of functional PFL or ADH production. The introduction of a Bacillus subtilis acetolactate synthase gene returned formate, ethanol, and lactate levels to those of the wild type (ackA(+)pta(+)nuo(+)) strain. Furthermore, transfer of a lactate dehydrogenase mutation yielded a strain producing ethanol as the sole fermentation product. As confirmation of the nuo effect, cultures of the ackA-pta strain, supplemented with an NDH-I inhibitor, produced intermediary levels of flux to ethanol and formate. Mutations in both ackA-pta and nuo are required to significantly reduce the flux through the PFL pathway.     

A stable organic free radical in anaerobic benzylsuccinate synthase of Azoarcus sp. strain T

The novel enzyme benzylsuccinate synthase initiates anaerobic toluene metabolism by catalyzing the addition of toluene to fumarate, forming benzylsuccinate. Based primarily on its sequence similarity to the glycyl radical enzymes, pyruvate formate-lyase and anaerobic ribonucleotide reductase, benzylsuccinate synthase was speculated to be a glycyl radical enzyme. In this report we use EPR spectroscopy to demonstrate for the first time that active benzylsuccinate synthase from the denitrifying bacterium Azoarcus sp. strain T harbors an oxygen-sensitive stable organic free radical. The EPR signal of the radical was centered at g = 2.0021 and was characterized by a major 2-fold splitting of about 1.5 millitesla. The strong similarities between the EPR signal of the benzylsuccinate synthase radical and that of the glycyl radicals of pyruvate formate-lyase and anaerobic ribonucleotide reductase provide evidence that the benzylsuccinate synthase radical is located on a glycine residue, presumably glycine 828 in Azoarcus sp. strain T benzylsuccinate synthase.