Elucidation of the stereochemical mechanism of cystathionine γ-lyase reveals how substrate specificity constrains catalysis

Pyridoxal phosphate (PLP)-dependent enzymes play essential roles in metabolism and have found applications for organic synthesis and as enzyme therapeutics. The vinylglycine ketimine (VGK) subfamily hosts a growing set of enzymes that play diverse roles in primary and secondary metabolism. However, the molecular determinates of substrate specificity and the complex acid-base chemistry that enables VGK catalysis remain enigmatic. We use a recently discovered amino acid γ-lyase as a model system to probe catalysis in this enzyme family. We discovered that two stereochemically distinct proton transfer pathways occur. Combined kinetic and spectroscopic analysis revealed that progression through the catalytic cycle is correlated with the presence of an H-bond donor after Cγ of an amino acid substrate, suggesting substrate binding is kinetically coupled to a conformational change. High-resolution X-ray crystallography shows that cystathionine-γ-lyases generate an s-trans intermediate and that this geometry is likely conserved throughout the VGK family. An H-bond acceptor in the active site templates substrate binding but does so by pre-organizing substrates away from catalytically productive orientations. Mutagenesis eliminates this pre-organization, such that there is a relaxation of the substrate specificity, but an increase in k cat for diverse substrates. We exploit this information to perform preparative scale α,β,β-tri-deuteration of polar amino acids. Together, these data untangle a complex mode of substrate specificity and provide a foundation for the future study and applications of VGK enzymes.

Multiplexed Assessment of Promiscuous Non-Canonical Amino Acid Synthase Activity in a Pyridoxal Phosphate-Dependent Protein Family

Pyridoxal phosphate (PLP)-dependent enzymes afford access to a variety of non-canonical amino acids (ncAAs), which are premier buildings blocks for the construction of complex bioactive molecules. The vinylglycine ketimine (VGK) subfamily of PLP-dependent enzymes plays a critical role in sulfur metabolism and is home to a growing set of secondary metabolic enzymes that synthesize γ-substituted ncAAs. Identification of VGK enzymes for biocatalysis faces a distinct challenge because the subfamily contains both desirable synthases as well as lyases that break down ncAAs. Some enzymes have both activities, which may contribute to pervasive mis-annotation. To navigate this complex functional landscape, we used a substrate multiplexed screening approach to rapidly measure the substrate promiscuity of 40 homologs in the VGK subfamily. We found that enzymes involved in transsulfuration are less likely to have promiscuous activities and often possess undesirable lyase activity. Enzymes from direct sulfuration and secondary metabolism generally had a high degree of substrate promiscuity. From this cohort, we identified an exemplary γ-synthase from Caldicellulosiruptor hydrothermalis (CahyGS). This enzyme is thermostable and has high expression (~400 mg protein per L culture), enabling preparative scale synthesis of thioether containing ncAAs. When assayed with l-allylglycine, CahyGS catalyzes a stereoselective γ-addition reaction to afford access to a unique set of γ-methyl branched ncAAs. We determined high-resolution crystal structures of this enzyme that define an open-close transition associated with ligand binding and set the stage for future engineering within this enzyme subfamily.

Mechanism-based and computational modeling of hydrogen sulfide biogenesis inhibition: interfacial inhibition

Hydrogen sulfide (H₂S) is a gaseous signaling molecule that participates in various signaling functions in health and diseases. The tetrameric cystathionine γ-lyase (CSE) contributes to H₂S biogenesis and several investigations provide evidence on the pharmacological modulation of CSE as a potential target for the treatment of a multitude of conditions. D-penicillamine (D-pen) has recently been reported to selectively impede CSE-catalyzed H₂S production but the molecular bases for such inhibitory effect have not been investigated. In this study, we report that D-pen follows a mixed-inhibition mechanism to inhibit both cystathionine (CST) cleavage and H₂S biogenesis by human CSE. To decipher the molecular mechanisms underlying such a mixed inhibition, we performed docking and molecular dynamics (MD) simulations. Interestingly, MD analysis of CST binding reveals a likely active site configuration prior to gem-diamine intermediate formation, particularly H-bond formation between the amino group of the substrate and the O3' of PLP. Similar analyses realized with both CST and D-pen identified three potent interfacial ligand-binding sites for D-pen and offered a rational for D-pen effect. Thus, inhibitor binding not only induces the creation of an entirely new interacting network at the vicinity of the interface between enzyme subunits, but it also exerts long range effects by propagating to the active site. Overall, our study paves the way for the design of new allosteric interfacial inhibitory compounds that will specifically modulate H₂S biogenesis by cystathionine γ-lyase.

Bacterial methionine biosynthesis

Methionine is essential in all organisms, as it is both a proteinogenic amino acid and a component of the cofactor, S-adenosyl methionine. The metabolic pathway for its biosynthesis has been extensively characterized in Escherichia coli; however, it is becoming apparent that most bacterial species do not use the E. coli pathway. Instead, studies on other organisms and genome sequencing data are uncovering significant diversity in the enzymes and metabolic intermediates that are used for methionine biosynthesis. This review summarizes the different biochemical strategies that are employed in the three key steps for methionine biosynthesis from homoserine (i.e. acylation, sulfurylation and methylation). A survey is presented of the presence and absence of the various biosynthetic enzymes in 1593 representative bacterial species, shedding light on the non-canonical nature of the E. coli pathway. This review also highlights ways in which knowledge of methionine biosynthesis can be utilized for biotechnological applications. Finally, gaps in the current understanding of bacterial methionine biosynthesis are noted. For example, the paper discusses the presence of one gene (metC) in a large number of species that appear to lack the gene encoding the enzyme for the preceding step in the pathway (metB), as it is understood in E. coli. Therefore, this review aims to move the focus away from E. coli, to better reflect the true diversity of bacterial pathways for methionine biosynthesis.

Expression and characterization of the Arabidopsis thaliana 11S globulin family

The 11S globulins are the principal seed storage proteins in a variety of major crop species, including members of the legume and mustard families. They are targets for protein engineering studies attempting to alter the physicochemical properties of seed protein extracts (e.g. soybean) and to improve the nutritional quality of important agricultural crops. A key factor that has limited the success of this approach to date is insufficient accumulation of the engineered protein variants in vivo due to their improper folding and/or reduced stability, compared to the native protein. We have developed the Arabidopsis thaliana 11S proglobulins as a model system to enable studies exploring the factors underlying structural stability in this family of proteins. Yields of 1.5-4 mg/L were achieved for the three A. thaliana 11S proglobulins expressed in the Origami Escherichia coli cell line in super broth media at 20°C for 16 h and purified via immobilized-metal affinity chromatography. We also demonstrate that differential scanning fluorimetry is an effective and accessible technique to facilitate the screening of variants to enable the successful engineering of 11S seed storage proteins. The relative in vitro stability of the A. thaliana 11S proglobulins (proAtCRU1>proAtCRU3>proAtCRU2) is consistent between chemical and thermal denaturation studies.

A role for glutamate-333 of Saccharomyces cerevisiae cystathionine γ-lyase as a determinant of specificity

Cystathionine γ-lyase (CGL) catalyzes the hydrolysis of l-cystathionine (l-Cth), producing l-cysteine (l-Cys), α-ketobutyrate and ammonia, in the second step of the reverse transsulfuration pathway, which converts l-homocysteine (l-Hcys) to l-Cys. Site-directed variants substituting residues E48 and E333 with alanine, aspartate and glutamine were characterized to probe the roles of these acidic residues, conserved in fungal and mammalian CGL sequences, in the active-site of CGL from Saccharomyces cerevisiae (yCGL). The pH optimum of variants containing the alanine or glutamine substitutions of E333 is increased by 0.4-1.2 pH units, likely due to repositioning of the cofactor and modification of the pKa of the pyridinium nitrogen. The pH profile of yCGL-E48A/E333A resembles that of Escherichia coli cystathionine β-lyase. The effect of substituting E48, E333 or both residues is the 1.3-3, 26-58 and 124-568-fold reduction, respectively, of the catalytic efficiency of l-Cth hydrolysis. The Km(l-Cth) of E333 substitution variants is increased ~17-fold, while Km(l-OAS) is within 2.5-fold of the wild-type enzyme, indicating that residue E333 interacts with the distal amine moiety of l-Cth, which is not present in the alternative substrate O-acetyl-l-serine. The catalytic efficiency of yCGL for α,γ-elimination of O-succinyl-l-homoserine (kcat/Km(l-OSHS)=7±2), which possesses a distal carboxylate, but lacks an amino group, is 300-fold lower than that of the physiological l-Cth substrate (kcat/Km(l-Cth)=2100±100) and 260-fold higher than that of l-Hcys (kcat/Km(l-Hcys)=0.027±0.005), which lacks both distal polar moieties. The results of this study suggest that the glutamate residue at position 333 is a determinant of specificity.

Identification of cystathionine γ-synthase and threonine synthase from Cicer arietinum and Lens culinaris

In plants, cystathionine γ-synthase (CGS) and threonine synthase (TS) compete for the branch-point metabolite O-phospho-L-homoserine. These enzymes are potential targets for metabolic engineering studies, aiming to alter the flux through the competing methionine and threonine biosynthetic pathways, with the goal of increasing methionine production. Although CGS and TS have been characterized in the model organisms Escherichia coli and Arabidopsis thaliana, little information is available on these enzymes in other, particularly plant, species. The functional CGS and TS coding sequences from the grain legumes Cicer arietinum (chickpea) and Lens culinaris (lentil) identified in this study share approximately 80% amino acid sequence identity with the corresponding sequences from Glycine max. At least 7 active-site residues of grain legume CGS and TS are conserved in the model bacterial enzymes, including the catalytic base. Putative processing sites that remove the targeting sequence and result in functional TS were identified in the target species.

Exploration of the active site of Escherichia coli cystathionine γ-synthase

Cystathionine γ-synthase (CGS) catalyzes the condensation of O-succinyl-L-homoserine (L-OSHS) and L-cysteine (L-Cys), to produce L-cystathionine (L-Cth) and succinate, in the first step of the bacterial transsulfuration pathway. In the absence of L-Cys, the enzyme catalyzes the futile α,γ-elimination of L-OSHS, yielding succinate, α-ketobutyrate, and ammonia. A series of 16 site-directed variants of Escherichia coli CGS (eCGS) was constructed to probe the roles of active-site residues D45, Y46, R48, R49, Y101, R106, N227, E325, S326, and R361. The effects of these substitutions on the catalytic efficiency of the α,γ-elimination reaction range from a reduction of only ∼2-fold for R49K and the E325A,Q variants to 310- and 760-fold for R361K and R48K, respectively. A similar trend is observed for the k(cat) /K(m)(l-OSHS) of the physiological, α,γ-replacement reaction. The results of this study suggest that the arginine residues at positions 48, 106 and 361 of eCGS, conserved in bacterial CGS sequences, tether the distal and α-carboxylate moieties, respectively, of the L-OSHS substrate. In contrast, with the exception of the 13-fold increase observed for R106A, the K(m)(l-Cys) is not markedly affected by the site-directed replacement of the residues investigated. The decrease in k(cat) observed for the S326A variant reflects the role of this residue in tethering the side chain of K198, the catalytic base. Although no structures exist of eCGS bound to active-site ligands, the roles of individual residues is consistent with the structures inhibitor complexes of related enzymes. Substitution of D45, E325, or Y101 enables a minor transamination activity for the substrate L-Ala.

Development of a continuous assay and steady-state characterization of Escherichia coli threonine synthase

Threonine synthase (TS) catalyzes the hydrolysis of O-phospho-L-homoserine (OPHS) to produce L-threonine (L-Thr) and inorganic phosphate. Here, we report a simplified purification protocol for the OPHS substrate and a continuous, coupled-coupled, spectrophotometric TS assay. The sequential actions of threonine deaminase (TD) and hydroxyisocaproate dehydrogenase (HO-HxoDH) convert the L-Thr product of TS to α-ketobutyrate (α-KB) and then to 2-hydroxybutyrate, respectively, and are monitored as the decrease in absorbance at 340 nm resulting from the concomitant oxidation of β-nicotinamide adenine dinucleotide (NADH) to NAD(+) by HO-HxoDH. The effect of pH on the activities of Escherichia coli TD and Lactobacillus delbrueckii HO-HxoDH was determined to establish this continuous assay as suitable for steady-state characterization and to facilitate the optimization of coupling enzyme concentrations under different assay conditions to enable studies of TS across phyla. To validate this assay, TS from E. coli was characterized. The kinetic parameters (k(cat)=4s(-1) and K(m)=0.34 mM) and the pH optimum of 8.7, determined using the continuous assay, are consistent with values reported for this enzyme based on the discontinuous malachite green assay. The k(cat)/K(m)(OPHS) versus pH profile of E. coli TS is bell-shaped, and the apparent pK(a) values for the acidic and basic limbs are 7.1 and 10.4, respectively.

The enzymes of the transsulfuration pathways: active-site characterizations

The diversity of reactions catalyzed by enzymes reliant on pyridoxal 5'-phosphate (PLP) demonstrates the catalytic versatility of this cofactor and the plasticity of the protein scaffolds of the major fold types of PLP-dependent enzymes. The enzymes of the transsulfuration (cystathionine γ-synthase and cystathionine β-lyase) and reverse transsulfuration (cystathionine β-synthase and cystathionine γ-lyase) pathways interconvert l-cysteine and l-homocysteine, the immediate precursor of l-methionine, in plants/bacteria and yeast/animals, respectively. These enzymes provide a useful model system for investigation of the mechanisms of substrate and reaction specificity in PLP-dependent enzymes as they catalyze distinct side chain rearrangements of similar amino acid substrates. Exploration of the underlying factors that enable enzymes to control the substrate and reaction specificity of this cofactor will enable the engineering of these properties and the development of therapeutics and antimicrobial compounds. Recent studies probing the role of active-site residues, of the enzymes of the transsulfuration pathways, as determinants of substrate and reaction specificity are the subject of this review. This article is part of a Special Issue entitled: Pyridoxal Phosphate Enzymology.

Characterization of site-directed mutants of residues R58, R59, D116, W340 and R372 in the active site of E. coli cystathionine beta-lyase

Cystathionine beta-lyase (CBL) catalyzes the hydrolysis of L-cystathionine (L-Cth) to produce L-homocysteine, pyruvate, and ammonia. A series of active-site mutants of Escherichia coli CBL (eCBL) was constructed to investigate the roles of residues R58, R59, D116, W340, and R372 in catalysis and inhibition by aminoethoxyvinylglycine (AVG). The effects of these mutations on the k(cat)/K(m) (L-Cth) for the beta-elimination reaction range from a reduction of only 3-fold for D116A and D116N to 6 orders of magnitude for the R372L and R372A mutants. The order of importance of these residues for the hydrolysis of L-Cth is: R372 >> R58 > W340 approximately R59 > D116. Comparison of the kinetic parameters for L-Cth hydrolysis with those for inhibition of eCBL by AVG demonstrates that residue R58 tethers the distal carboxylate group of the substrate and confirms that residues W340 and R372 interact with the alpha-carboxylate moiety. The increase in the pK(a) of the acidic limb and decrease in the pK(a) of the basic limb of the k(cat)/K(m) (L-Cth) versus pH profiles of the R58K and R58A mutants, respectively, support a role for this residue in modulating the pK(a) of an active-site residue.

Site-directed mutagenesis on human cystathionine-gamma-lyase reveals insights into the modulation of H2S production

In recent years, increased interest has been directed towards hydrogen sulfide (H2S) as the third gasotransmitter and its role in various diseases. Cystathionine-gamma-lyase (CSE) is one of the enzymes responsible for the endogenous production of H2S in mammals. With the aid of the crystal structures of human CSE and site-directed mutagenesis studies, we have identified several amino acid residues in CSE that are actively involved in the catalysis of H2S production. Contrary to reports suggesting that Tyr114 is required for substrate binding, our results reveal a significant increase in the production of H2S upon mutation of Tyr114 to phenylalanine. This is attributed to an increased rate of pyridoxal 5'-phosphate (PLP) regeneration due to weakened pi-stacking interactions between Phe114 and PLP. Thr189 is also identified as a crucial residue where hydrogen bonding to Asp187 keeps the latter in an optimal position for hydrogen bonding to the pyridoxal nitrogen of PLP. Furthermore, mutation of Glu339 to lysine, alanine or tyrosine reveals the importance of the hydrophobicity of the 339th amino acid in determining the specificity of the enzyme for the catalysis of alpha,gamma-elimination or alpha,beta-elimination reaction. Our study also shows that the rate of H2S production is increased with increasing exogenous PLP concentration, hence supporting our hypothesis that apo-CSE is formed during the catalysis of H2S production. Taken together, these findings suggest novel routes towards the design of activators or inhibitors that modulate the production of H2S; these modulators may also serve as lead compounds in the development of drugs or mechanistic probes in the study of various H2S-related diseases.