Comparative analysis of the human serine hydrolase OVCA2 to the model serine hydrolase homolog FSH1 from S. cerevisiae

Bun, Jessica S.; Slack, Michael D.; Schemenauer, Daniel; Johnson, R. Jeremy

doi:10.1371/journal.pone.0230166

Cited by 5 publications

(5 citation statements)

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“…37,38 The fluorogenic library is separated into structural groups based on common subclasses of serine hydrolase activity with expansion of the tertiary and bulky esters in the current substrate library (Figure 1). 37,40,45,46 Within these subclasses, the alkyl ester substrates (1−6) allow general classification of serine hydrolases based on substrate length preferences and the introduction of polarity and unsaturation into these substrates (7−11; 12−15) provide greater solubility, reactivity, and selectivity. 38 As a proposed arylesterase with specificity for xenobiotics, 15 LipN may selectively recognize cyclic, hydrophobic, or constrained esters (16)(17)(18)(19)(20)(21)32).…”

Section: ■ Resultsmentioning

confidence: 99%

“…This pattern of essentiality for the nucleophilic serine and catalytic base histidine and lesser role for the acidic asparate/glutamate residue has been observed in a variety of serine hydrolases and other bHSLs. 40,45,46 Within other conserved bHSL motifs, oxyanion hole residues�Gly 144 and Gly145�were found to be required for complete catalysis, as conservative substitutions with alanine decreased the k cat /K M values by 15-to 140-fold against all three fluorogenic substrates. The only substitution without a near complete loss of catalytic activity was D215A, which had k cat /K M values within 3-fold of wild-type LipN for substrates 1 and 7.…”

Section: ■ Resultsmentioning

confidence: 99%

“…The enzymatic activity of Mm LipN was measured against p -nitrophenyl acetate, p -nitrophenyl butyrate, p -nitrophenyl valerate, p -nitrophenyl octanoate, and p -nitrophenyl myristate (Sigma-Aldrich) using a 96-well microplate assay (Figure ). ,, Substrates ( p -nitrophenyl acetate (2 M), p -nitrophenyl butyrate (2 M), p -nitrophenyl valerate (2 M), p -nitrophenyl octanoate (200 mM), and p -nitrophenyl myristate (200 mM)) were prepared as stock solutions in acetonitrile and diluted into PBS containing acetylated BSA (PBS–BSA; 0.1 mg/mL). The starting concentration for p -nitrophenyl acetate and p -nitrophenyl butyrate was 20 mM and for p -nitrophenyl valerate, p -nitrophenyl octanoate, and p -nitrophenyl myristate was 2 mM.…”

Section: Methodsmentioning

confidence: 99%

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Sequence and Structural Motifs Controlling the Broad Substrate Specificity of the Mycobacterial Hormone-Sensitive Lipase LipN

et al. 2023

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Mycobacterium tuberculosis has a complex life cycle transitioning between active and dormant growth states depending on environmental conditions. LipN (Rv2970c) is a conserved mycobacterial serine hydrolase with regulated catalytic activity at the interface between active and dormant growth conditions. LipN also catalyzes the xenobiotic degradation of a tertiary ester substrate and contains multiple conserved motifs connected with the ability to catalyze the hydrolysis of difficult tertiary ester substrates. Herein, we expanded a library of fluorogenic ester substrates to include more tertiary and constrained esters and screened 33 fluorogenic substrates for activation by LipN, identifying its unique substrate signature. LipN preferred short, unbranched ester substrates, but had its second highest activity against a heteroaromatic five-membered oxazole ester. Oxazole esters are present in multiple mycobacterial serine hydrolase inhibitors but have not been tested widely as ester substrates. Combined structural modeling, kinetic measurements, and substitutional analysis of LipN showcased a fairly rigid binding pocket preorganized for catalysis of short ester substrates. Substitution of diverse amino acids across the binding pocket significantly impacted the folded stability and catalytic activity of LipN with two conserved motifs (HGGGW and GDSAG) playing interconnected, multidimensional roles in regulating its substrate specificity. Together this detailed substrate specificity profile of LipN illustrates the complex interplay between structure and function in mycobacterial hormone-sensitive lipase homologues and indicates oxazole esters as promising inhibitor and substrate scaffolds for mycobacterial hydrolases.

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Section: ■ Resultsmentioning

confidence: 99%

Section: ■ Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Sequence and Structural Motifs Controlling the Broad Substrate Specificity of the Mycobacterial Hormone-Sensitive Lipase LipN

et al. 2023

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“…J. Fungi 2020, 6, x FOR PEER REVIEW 13 of 15 hydrolase fold and employ a Ser-His-Asp catalytic triad [21], but more than half of the serine hydrolases (>120 enzymes) remain poorly annotated, with no described physiological function or identified substrates [19,22]. In this study, the results showed that there was a 10-70% decrease in the four typical yellow pigments by mrpigG deletion.…”

Section: Discussionmentioning

confidence: 66%

“…In current study, the generation of mrpigG mutants by homologous recombination, as shown in Figure 5 and Figure 7 , demonstrated that mrpigG was a member of the MP gene cluster. Searched with the Pfam 33.1 program, the data showed that mrpigG belonged to the serine hydrolase family, which is a large, ubiquitous family of enzymes grouped based on their ability to perform hydrolysis reactions on a range of biological substrates, such as ester, thioester, amide and epoxide bonds in small molecules, peptides or proteins [ 19 , 20 , 21 ]. The majority of serine hydrolases (>60%) adopt an α,β-hydrolase fold and employ a Ser-His-Asp catalytic triad [ 21 ], but more than half of the serine hydrolases (>120 enzymes) remain poorly annotated, with no described physiological function or identified substrates [ 19 , 22 ].…”

Section: Discussionmentioning

confidence: 99%

Effects of mrpigG on Development and Secondary Metabolism of Monascus ruber M7

Chen

2020

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Monascus pigments (MPs) have been used as food colorants for several centuries in Asian countries and are now used throughout the world via Asian catering. The MP biosynthetic pathway has been well-illustrated, but the functions of a few genes, including mrpigG, in the MP gene cluster are still unclear. In the current study, in order to investigate the function of mrpigG in M. ruber M7, gene deletion (ΔmrpigG), complementation (ΔmrpigG::mrpigG) and overexpression (M7::PtrpC-mrpigG) mutants were successfully obtained. The morphologies and biomasses, as well as the MP and citrinin production, of these mutants were analyzed. The results revealed that the disruption, complementation and overexpression of mrpigG showed no apparent defects in morphology, biomass or citrinin production (except MP production) in ΔmrpigG compared with M. ruber M7. Although the MP profiles of ΔmrpigG and M. ruber M7 were almost the same—with both having four yellow pigments, two orange pigments (OPs) and two red pigments (RPs)—their yields were decreased in ΔmrpigG to a certain extent. Particularly, the content of rubropunctatin (an OP) and its derivative rubropunctamine (an RP) in ΔmrpigG, both of which have a five-carbon side chain, accounted for 57.7%, and 22.3% of those in M. ruber M7. On the other hand, monascorubrin (an OP) and its derivative monascorubramine (an RP), both of which have a seven-carbon side chain, were increased by 1.15 and 2.55 times, respectively, in ΔmrpigG compared with M. ruber M7. These results suggest that the MrPigG protein may preferentially catalyze the biosynthesis of MPs with a five-carbon side chain.

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