The role of active site tyrosine 58 in Citrobacter freundii methionine γ-lyase

Catalytic specificity and crystal structure of cystathionine γ-lyase from Pseudomonas aeruginosa

The escalating drug resistance among microorganisms underscores the urgent need for innovative therapeutic strategies and a comprehensive understanding of bacteria's defense mechanisms against oxidative stress and antibiotics. Among the recently discovered barriers, the endogenous production of hydrogen sulfide (H2S) via the reverse transsulfuration pathway, emerges as a noteworthy factor. In this study, we have explored the catalytic capabilities and crystal structure of cystathionine γ-lyase from Pseudomonas aeruginosa (PaCGL), a multidrug-opportunistic pathogen chiefly responsible for nosocomial infections. In addition to a canonical L-cystathionine hydrolysis, PaCGL efficiently catalyzes the production of H2S using L-cysteine and/or L-homocysteine as alternative substrates. Comparative analysis with the human enzyme and counterparts from other pathogens revealed distinct structural features within the primary enzyme cavities. Specifically, a distinctly folded entrance loop could potentially modulate the access of substrates and/or inhibitors to the catalytic site. Our findings offer significant insights into the structural evolution of CGL enzymes across different pathogens and provide novel opportunities for developing specific inhibitors targeting PaCGL.

O-Acetylhomoserine Sulfhydrylase from Clostridioides difficile: Role of Tyrosine Residues in the Active Site

O-acetylhomoserine sulfhydrylase is one of the key enzymes in biosynthesis of methionine in Clostridioides difficile. The mechanism of γ-substitution reaction of O-acetyl-L-homoserine catalyzed by this enzyme is the least studied among the pyridoxal-5'-phosphate-dependent enzymes involved in metabolism of cysteine and methionine. To clarify the role of active site residues Tyr52 and Tyr107, four mutant forms of the enzyme with replacements of these residues with phenylalanine and alanine were generated. Catalytic and spectral properties of the mutant forms were investigated. The rate of γ-substitution reaction catalyzed by the mutant forms with replaced Tyr52 residue decreased by more than three orders of magnitude compared to the wild-type enzyme. The Tyr107Phe and Tyr107Ala mutant forms practically did not catalyze this reaction. Replacements of the Tyr52 and Tyr107 residues led to the decrease in affinity of apoenzyme to coenzyme by three orders of magnitude and changes in the ionic state of the internal aldimine of the enzyme. The obtained results allowed us to assume that Tyr52 is involved in ensuring optimal position of the catalytic coenzyme-binding lysine residue at the stages of C-α-proton elimination and elimination of the side group of the substrate. Tyr107 could act as a general acid catalyst at the stage of acetate elimination.

Serine 339 in the Catalysis of γ- and β-Elimination Reactions

Serine 339 of the active site of Citrobacter freundii methionine γ-lyase (MGL) is a conserved amino acid in most pyridoxal 5’-phosphate-dependent enzymes of the cystathionine β-lyase subclass, to which MGL belongs. The reaction mechanism of the MGL-catalyzed γ-elimination reaction is poorly explored. We replaced serine 339 with alanine using site-directed mutagenesis. The replacement of serine 339 with alanine led to a significant (by two orders of magnitude) decrease in efficiency in the catalysis of the γ- and β-elimination reactions by the mutant form of the enzyme. The exchange rates of the C-α- and C-β-protons in the amino acids in complexes consisting of the enzyme and competitive inhibitors decreased by one-two orders of magnitude. The spectral characteristics of the mutant form indicated that the replacement did not lead to significant changes in the conformation and tautomerism of MGL internal aldimine. We crystallized the holoenzyme and determined its spatial structure at 1.7 E resolution. The replacement of serine 339 with alanine did not affect the overall course of the polypeptide chain of the MGL subunit and the tetrameric enzyme structure. An analysis of the obtained kinetic and spectral data, as well as the known spatial structures of C. freundii MGL, indicates that serine 339 is necessary for efficient catalysis of γ- and β-elimination reactions at the stage of C-α-proton abstraction from the external aldimine, the γ-elimination reaction at the stages of coenzyme C4’-atom protonation, and C-β-proton abstraction from a ketimine intermediate.

New N-Alkylated Heterocyclic Compounds as Prospective NDM1 Inhibitors: Investigation of In Vitro and In Silico Properties

A new family of pyrazole-based compounds (1–15) was synthesized and characterized using different physicochemical analyses, such as FTIR, UV-Visible, ¹H, ¹³C NMR, and ESI/LC-MS. The compounds were evaluated for their in vitro antifungal and antibacterial activities against several fungal and bacterial strains. The results indicate that some compounds showed excellent antibacterial activity against E. coli, S. aureus, C. freundii, and L. monocytogenes strains. In contrast, none of the compounds had antifungal activity. Molecular electrostatic potential (MEP) map analyses and inductive and mesomeric effect studies were performed to study the relationship between the chemical structure of our compounds and the biological activity. In addition, molecular docking and virtual screening studies were carried out to rationalize the antibacterial findings to characterize the modes of binding of the most active compounds to the active pockets of NDM1 proteins.

Analyses of pre-steady-state kinetics and isotope effects of the γ-elimination reaction catalyzed by Citrobacter freundii methionine γ-lyase

Methionine γ-lyase (MGL) is a pyridoxal 5'-phosphate-dependent enzyme catalyzing γ-elimination in l-methionine. Pyridoxal 5'-phosphate-dependent enzymes have unique spectral properties that allow to monitor sequential formation and decomposition of various intermediates via the detection of absorbance changes. The kinetic mechanism of the γ-elimination reaction catalyzed by Citrobacter freundii MGL was elucidated here by fast stopped-flow kinetic analysis. Single-wavelength detection of characteristic absorbance changes enabled us to compare transformations of intermediates in the course of the reaction with different substrates. The influence of various γ-substituents in the substrate on the formation of key intermediates was estimated. Kinetic isotope effects of α- and β-protons were determined using deuterium-substituted l-methionine. Contributions of amino acid residues Tyr113 and Tyr58 located in the active site on the formation and decomposition of reaction intermediates were identified too. α-Aminocrotonate formation is the rate-limiting step of the enzymatic γ-elimination reaction. Kinetic isotope effects strongly support concerted reaction mechanisms of transformation between an external aldimine and a ketimine intermediate as well as a ketimine intermediate and an unsaturated ketimine.

Gamma cleavage is a rate-determining step in the gamma-elimination reaction of L-methionine analogues catalyzed by methionine-gamma-lyase

Methionine-γ-lyase (MGL) is a pyridoxal-5'-phosphate dependent enzyme found in bacteria and protozoa that catalyzes a variety of reactions, including the γ-elimination of L-methionine (L-Met). Here we report experimental kinetic data and density functional theory (DFT) computational data for the γ-elimination reaction of L-Met and several other substrate analogues by a recombinant MGL from P. gingivalis (MGL_Pg). UV-Visible spectrophotometry experiments revealed a heavily populated species with maximum absorbance at 478 nm during steady-state catalysis of L-Met, L-ethionine, L-methionine sulfone and L-homoserine, which we assign to a late crotonate intermediate formed after the γ-cleavage step in the reaction and thus common to all substrates. A more red-shifted (498 nm) species was observed during the reaction of L-homoserine lactone, which we assign to an early quinonoid intermediate with the aid of time-dependent self-consistent field calculations. Significant differences in both binding and the rate of turnover were observed for the substrates. MGL_Pg's highest catalytic efficiency was recorded for L-vinylglycine (k_cat/K_m = 6455 s^-1 M^-1), exceeding that of L-Met (k_cat/K_m = 4211 s^-1 M^-1), while L-Met sulfone displayed the largest turnover number (k_cat = 1638 min^-1). A direct correlation between experimental k_cat values and DFT-calculated γ-cleavage Gibbs activation energies was identified for the various substrates. In light of these data, we propose that the γ-cleavage step in the catalytic reaction pathway is rate-limiting. This conclusion has direct implications for the rational design of substrates or inhibitors aimed at regulating MGL activity.

Sulfoxides of sulfur-containing amino acids are suicide substrates of Citrobacter freundii methionine γ-lyase. Structural bases of the enzyme inactivation

Interactions of Citrobacter freundii methionine γ-lyase (MGL) with sulfoxides of typical substrates were investigated. It was found that sulfoxides are suicide substrates of the enzyme. The products of the β- and γ-elimination reactions of sulfoxides, thiosulfinates, oxidize three cysteine residues of the enzyme. Three-dimensional structures of MGL inactivated by dimethyl thiosulfinate and diethyl thiosulfinate were determined at 1.46 Å and 1.59 Å resolution. Analysis of the structures identified SH groups oxidized by thiosulfinates and revealed the structural bases of MGL inactivation. The extent of inactivation of MGL in the catalysis of the β-elimination reaction depends on the length of the «tail» at oxidized Cys115. Oxidation of Cys115 results in MGL incapable to catalyze the stage of methyl mercaptan elimination of the physiological reaction.

Identification of O-acetylhomoserine sulfhydrylase, a putative enzyme responsible for methionine biosynthesis in Clostridioides difficile: Gene cloning and biochemical characterizations

O-acetylhomoserine sulfhydrylase (OAHS) is a pyridoxal 5'-phosphate-dependent enzyme involved in microbial methionine biosynthesis. In this study, we report gene cloning, protein purification, and some biochemical characteristics of OAHS from Clostridioides difficile. The enzyme is a tetramer with molecular weight of 185 kDa. It possesses a high activity in the reaction of L-homocysteine synthesis, comparable to reported activities of OAHSes from other sources. OAHS activity is inhibited by metabolic end product L-methionine. L-Propargylglycine was found to be a suicide inhibitor of the enzyme. Substrate analogue N^γ -acetyl-L-2,4-diaminobutyric acid is a competitive inhibitor of OAHS with K_i = 0.04 mM. Analysis of C. difficile genome allows to suggest that the bacterium uses the way of direct sulfhydrylation for the synthesis of L-methionine. The data obtained may provide the basis for further study of the role of OAHS in the pathogenic bacterium and the development of potential inhibitors.

Crystal structure of mutant form Cys115His of Citrobacter freundii methionine γ-lyase complexed with l-norleucine

The mutant form of Citrobacter freundii methionine γ-lyase with the replacement of active site Cys115 for His has been found to be inactive in the γ-elimination reaction of methionine while fully active in the γ-elimination reaction of O-acetyl-l-homoserine and in the β-elimination reaction of S-alk(en)yl-substituted cysteines. In this work, the crystal structure of the mutant enzyme complexed with competitive inhibitor, l-norleucine was determined at 1.45Å resolution. At the enzyme active site the inhibitor proved to be bound both noncovalently and covalently, which corresponds to the two intermediates of the γ- and β-elimination reactions, Michaelis complex and the external aldimine. Analysis of the structure allowed us to suggest the possible reason for the inability of the mutant enzyme to catalyze the physiological reaction.

Structural and mechanistic insights into homocysteine degradation by a mutant of methionine γ-lyase based on substrate-assisted catalysis

Methionine γ-lyse (MGL) catalyzes the α, γ-elimination of l-methionine and its derivatives as well as the α, β-elimination of l-cysteine and its derivatives to produce α-keto acids, volatile thiols, and ammonia. The reaction mechanism of MGL has been characterized by enzymological studies using several site-directed mutants. The Pseudomonas putida MGL C116H mutant showed drastically reduced degradation activity toward methionine while retaining activity toward homocysteine. To understand the underlying mechanism and to discern the subtle differences between these substrates, we analyzed the crystal structures of the reaction intermediates. The complex formed between the C116H mutant and methionine demonstrated that a loop structure (Ala51-Asn64) in the adjacent subunit of the catalytic dimer cannot approach the cofactor pyridoxal 5'-phosphate (PLP) because His116 disrupts the interaction of Asp241 with Lys240, and the liberated side chain of Lys240 causes steric hindrance with this loop. Conversely, in the complex formed between C116H mutant and homocysteine, the thiol moiety of the substrate conjugated with PLP offsets the imidazole ring of His116 via a water molecule, disrupting the interaction of His116 and Asp241 and restoring the interaction of Asp241 with Lys240. These structural data suggest that the Cys116 to His mutation renders the enzyme inactive toward the original substrate, but activity is restored when the substrate is homocysteine due to substrate-assisted catalysis.