Fine tuning of the active site modulates specificity in the interaction of O-acetylserine sulfhydrylase isozymes with serine acetyltransferase

Abstract: O-acetylserine sulfhydrylase (OASS) catalyzes the synthesis of l-cysteine in the last step of the reductive sulfate assimilation pathway in microorganisms. Its activity is inhibited by the interaction with serine acetyltransferase (SAT), the preceding enzyme in the metabolic pathway. Inhibition is exerted by the insertion of SAT C-terminal peptide into the OASS active site. This action is effective only on the A isozyme, the prevalent form in enteric bacteria under aerobic conditions, but not on the B-isozyme,… Show more

“…In addition, as already discussed [19], G230 is substituted by R210, a residue that in some microorganisms plays a role in the selection of O -phosphoserine as the preferred substrate of the B isoform [53], [109]. The higher conservation degree of the residues belonging to the N-terminal domain with respect to those of the C-terminal domain allow the last two residues of pentapeptides docked in the active sites of OASS-A and OASS-B to occupy similar positions [19]. In spite of these common features, only OASS-A is able to interact with high affinity with SAT [55], [56].…”

“…The biochemical investigation of OASS-A and OASS-B reactivity [36] and active site specificity probed by pentapeptides [19] indicate that, despite an overall 40% sequence identity and a 70% sequence identity for the first active site shell (Figure 2A), the two isozymes exhibit subtle but significant structural differences (Figure 2B,C). Most of the residues of the first active site shell are conserved, with residues belonging to the N-terminal domain (residues 1–12 and 35–145, OASS-A numbering [47]) showing a 90% identity, residue P67 being substituted by A69 in OASS-B.…”

“…This conclusion is supported by extensive mutational and computational analysis [16], [61], also showing the relevance of the C-terminal amino acid isoleucine for OASS-SAT formation [51], [65]. The contribution of individual amino acids contained in the C-terminal sequence of SAT to complex formation and to binding specificity towards OASS-A and OASS-B was investigated using a small library of pentapeptides [19], [66]. Furthermore, recently, inhibitors for OASS-A have been obtained via a classical medicinal chemistry approach [18] and by virtual screening [11], [67].…”

“…OASS-A and OASS-B were expressed and purified as previously described [19]. The binding affinity of selected ligands to OASS-A and OASS-B was determined by monitoring the increase in fluorescence emission of the bound PLP at 500 nm following excitation at 412 nm [16], [55].…”

Isozyme-Specific Ligands for O-acetylserine sulfhydrylase, a Novel Antibiotic Target

“…In addition, as already discussed [19], G230 is substituted by R210, a residue that in some microorganisms plays a role in the selection of O -phosphoserine as the preferred substrate of the B isoform [53], [109]. The higher conservation degree of the residues belonging to the N-terminal domain with respect to those of the C-terminal domain allow the last two residues of pentapeptides docked in the active sites of OASS-A and OASS-B to occupy similar positions [19]. In spite of these common features, only OASS-A is able to interact with high affinity with SAT [55], [56].…”

“…The biochemical investigation of OASS-A and OASS-B reactivity [36] and active site specificity probed by pentapeptides [19] indicate that, despite an overall 40% sequence identity and a 70% sequence identity for the first active site shell (Figure 2A), the two isozymes exhibit subtle but significant structural differences (Figure 2B,C). Most of the residues of the first active site shell are conserved, with residues belonging to the N-terminal domain (residues 1–12 and 35–145, OASS-A numbering [47]) showing a 90% identity, residue P67 being substituted by A69 in OASS-B.…”

“…This conclusion is supported by extensive mutational and computational analysis [16], [61], also showing the relevance of the C-terminal amino acid isoleucine for OASS-SAT formation [51], [65]. The contribution of individual amino acids contained in the C-terminal sequence of SAT to complex formation and to binding specificity towards OASS-A and OASS-B was investigated using a small library of pentapeptides [19], [66]. Furthermore, recently, inhibitors for OASS-A have been obtained via a classical medicinal chemistry approach [18] and by virtual screening [11], [67].…”

“…OASS-A and OASS-B were expressed and purified as previously described [19]. The binding affinity of selected ligands to OASS-A and OASS-B was determined by monitoring the increase in fluorescence emission of the bound PLP at 500 nm following excitation at 412 nm [16], [55].…”

Isozyme-Specific Ligands for O-acetylserine sulfhydrylase, a Novel Antibiotic Target

“…Subsequent experimental measurement of peptide binding affinities for HiCysK, E. coli CysK (EcCysK) and StCysK confirms the predicted increases in binding affinity [53, 60]. However, the key energetic contribution to binding arises from an aromatic residue, specifically Tyr, at position P2, irrespective of residues at P3.…”

Moonlighting O-acetylserine sulfhydrylase: New functions for an old protein

Structural insight into the interaction of O‐acetylserine sulfhydrylase with competitive, peptidic inhibitors by saturation transfer difference‐NMR