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by claude@2026-07, 2026-07-06
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The paper investigated cysteine-biosynthesis inhibition by characterizing C-terminal peptides derived from serine acetyltransferase (CysE) and the transcriptional regulator CymR that interact with the single O-acetyl-ʟ-serine sulfhydrylase homologue in Staphylococcus aureus (SaCysK). Using X-ray crystallography, binding assays (surface plasmon resonance), and SaCysK enzymatic inhibition tests, the authors found that both CysE and CymR decapeptides occupy the SaCysK active site, but CymR decapeptide sidechains form more extensive interactions, yielding nanomolar binding (KD = 25 nM) and inhibition (IC50 = 180 nM). Structure–activity relationship experiments with 16 rationally designed peptides identified the CymR pentapeptide as the minimal sequence needed to retain high-affinity interaction, with the additional finding that subtle pentapeptide modifications can preserve potency. The paper does not discuss endometriosis or adenomyosis; it was included in the corpus via a keyword match in the upstream search index.
Abstract
The conditionally essential pathway of bacterial cysteine biosynthesis is gaining traction for the development of antibiotic adjuvants. Bacterial cysteine biosynthesis is generally facilitated by two enzymes possessing O-acetyl-ʟ-serine sulfhydrylase (OASS) activity, CysK and CysM. CysK enzymes can also form functional complexes with other proteins that regulate cysteine metabolism. In Staphylococcus aureus there exists a single OASS homologue, herein termed Sa CysK. Knockout of Sa CysK was found to increase sensitivity to oxidative stress, making it a relevant target for inhibitor development. Sa CysK forms two functional complexes via interaction with the preceding enzyme in the pathway serine acetyltransferase (CysE) or the transcriptional regulator of cysteine metabolism (CymR). These interactions occur through the insertion of a C-terminal peptide of CysE or CymR into the active site of Sa CysK, inhibiting OASS activity, and therefore represent an excellent starting point for developing Sa CysK inhibitors. Here we detail the characterization of CysE and CymR-derived C-terminal peptides as inhibitors of Sa CysK. First, interactions between CysE or CymR-derived C-terminal decapeptides and Sa CysK were assessed by X-ray crystallography. While both peptides occupied the active site of Sa CysK, the alternate sidechains of the CymR decapeptide formed more extensive interactions. Surface plasmon resonance binding assays and Sa CysK inhibition assays revealed that the CymR decapeptide bound to Sa CysK with nanomolar affinity (K D = 25 nM) and inhibited Sa CysK activity (IC 50 = 180 nM), making it a promising lead for the development of Sa CysK inhibitors. To understand the determinants of this high affinity interaction the structure-activity relationships of 16 rationally designed peptides were also investigated. This identified that the C-terminal pentapeptide of CymR alone facilitates the high affinity interaction with Sa CysK, and that subtle structural modification of the pentapeptide is possible without impacting potency. Ultimately, this work has identified CymR pentapeptides as a promising scaffold for the development of antibiotic adjuvants targeting Sa CysK. Author summary There is increasing interest in the investigation of non-essential pathways including bacterial cysteine metabolism for developing antibiotic adjuvants. Within this pathway the O-acetyl-ʟ-serine sulfhydrylase (OASS) enzymes CysK and CysM have been a focus. As such, the OASS enzyme of Staphylococcus aureus , Sa CysK, gained our interest. Previous efforts to inhibit CysK enzymes have mimicked the interaction between CysK and the C-terminus of serine acetyltransferase (CysE) which occurs inside the CysK active site and inhibits OASS activity. CysE peptides have only moderate potency, typically binding with micromolar affinity. In S. aureus another complex forms between Sa CysK and a transcriptional regulator CymR, but the ability of CymR peptides to inhibit CysK enzymes has not been investigated. We noticed there is variation between the C-terminus of CysE and CymR, suggesting that CymR peptides make distinct interactions with Sa CysK and may be superior inhibitors. Here we characterized CysE and CymR peptides as Sa CysK inhibitors. We found CymR peptides make more extensive molecular interactions with Sa CysK and bind with higher affinity, being the most potent peptide inhibitors of a CysK enzyme to date. A CymR pentapeptide is the minimal length required for this potency and provides a promising scaffold for developing antibiotic adjuvants targeting Sa CysK.
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Abstract
The conditionally essential pathway of bacterial cysteine biosynthesis is gaining traction for the development of antibiotic adjuvants. Bacterial cysteine biosynthesis is generally facilitated by two enzymes possessing O-acetyl-ʟ-serine sulfhydrylase (OASS) activity, CysK and CysM. CysK enzymes can also form functional complexes with other proteins that regulate cysteine metabolism. In Staphylococcus aureus there exists a single OASS homologue, herein termed SaCysK. Knockout of SaCysK was found to increase sensitivity to oxidative stress, making it a relevant target for inhibitor development. SaCysK forms two functional complexes via interaction with the preceding enzyme in the pathway serine acetyltransferase (CysE) or the transcriptional regulator of cysteine metabolism (CymR). These interactions occur through the insertion of a C-terminal peptide of CysE or CymR into the active site of SaCysK, inhibiting OASS activity, and therefore represent an excellent starting point for developing SaCysK inhibitors. Here we detail the characterization of CysE and CymR-derived C-terminal peptides as inhibitors of SaCysK. First, interactions between CysE or CymR-derived C-terminal decapeptides and SaCysK were assessed by X-ray crystallography. While both peptides occupied the active site of SaCysK, the alternate sidechains of the CymR decapeptide formed more extensive interactions. Surface plasmon resonance binding assays and SaCysK inhibition assays revealed that the CymR decapeptide bound to SaCysK with nanomolar affinity (KD = 25 nM) and inhibited SaCysK activity (IC50 = 180 nM), making it a promising lead for the development of SaCysK inhibitors. To understand the determinants of this high affinity interaction the structure-activity relationships of 16 rationally designed peptides were also investigated. This identified that the C-terminal pentapeptide of CymR alone facilitates the high affinity interaction with SaCysK, and that subtle structural modification of the pentapeptide is possible without impacting potency. Ultimately, this work has identified CymR pentapeptides as a promising scaffold for the development of antibiotic adjuvants targeting SaCysK.
Author summary There is increasing interest in the investigation of non-essential pathways including bacterial cysteine metabolism for developing antibiotic adjuvants. Within this pathway the O-acetyl-ʟ-serine sulfhydrylase (OASS) enzymes CysK and CysM have been a focus. As such, the OASS enzyme of Staphylococcus aureus, SaCysK, gained our interest. Previous efforts to inhibit CysK enzymes have mimicked the interaction between CysK and the C-terminus of serine acetyltransferase (CysE) which occurs inside the CysK active site and inhibits OASS activity. CysE peptides have only moderate potency, typically binding with micromolar affinity. In S. aureus another complex forms between SaCysK and a transcriptional regulator CymR, but the ability of CymR peptides to inhibit CysK enzymes has not been investigated. We noticed there is variation between the C-terminus of CysE and CymR, suggesting that CymR peptides make distinct interactions with SaCysK and may be superior inhibitors. Here we characterized CysE and CymR peptides as SaCysK inhibitors. We found CymR peptides make more extensive molecular interactions with SaCysK and bind with higher affinity, being the most potent peptide inhibitors of a CysK enzyme to date. A CymR pentapeptide is the minimal length required for this potency and provides a promising scaffold for developing antibiotic adjuvants targeting SaCysK.
Competing Interest Statement
The authors have declared no competing interest.
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