Cellular esterases catalyze many essential biological functions by performing hydrolysis reactions on diverse substrates. The promiscuity of esterases complicates assignment of their substrate preferences and biological functions. To identify universal factors controlling esterase substrate recognition, we designed a 32-member structure-activity relationship (SAR) library of fluorogenic ester substrates and used this library to systematically interrogate esterase preference for chain length, branching patterns, and polarity to differentiate common classes of esterase substrates. Two structurally homologous bacterial esterases were screened against this library, refining their previously broad overlapping substrate specificity. esterase ybfF displayed a preference for γ-position thioethers and ethers, whereas Rv0045c from displayed a preference for branched substrates with and without thioethers. We determined that this substrate differentiation was partially controlled by individual substrate selectivity residues Tyr-119 in ybfF and His-187 in Rv0045c; reciprocal substitution of these residues shifted each esterase's substrate preference. This work demonstrates that the selectivity of esterases is tuned based on transition state stabilization, identifies thioethers as an underutilized functional group for esterase substrates, and provides a rapid method for differentiating structural isozymes. This SAR library could have multifaceted future applications, including imaging, biocatalyst screening, molecular fingerprinting, and inhibitor design.
Among the proteins required for lipid metabolism in Mycobacterium tuberculosis are a significant number of uncharacterized serine hydrolases, especially lipases and esterases. Using a streamlined synthetic method, a library of immolative fluorogenic ester substrates was expanded to better represent the natural lipidomic diversity of Mycobacterium. This expanded fluorogenic library was then used to rapidly characterize the global structure activity relationship (SAR) of mycobacterial serine hydrolases in M. smegmatis under different growth conditions. Confirmation of fluorogenic substrate activation by mycobacterial serine hydrolases was performed using nonspecific serine hydrolase inhibitors and reinforced the biological significance of the SAR. The hydrolases responsible for the global SAR were then assigned using gel-resolved activity measurements, and these assignments were used to rapidly identify the relative substrate specificity of previously uncharacterized mycobacterial hydrolases. These measurements provide a global SAR of mycobacterial hydrolase activity, a picture of cycling hydrolase activity, and a detailed substrate specificity profile for previously uncharacterized hydrolases.
Metabolic G-protein Coupled Receptors (GPCRs). (A) Intramembrane access to the binding pocket of GPR40 (also known as free fatty acid receptor 1; PDB code: 4PHU). The binding pocket of GPR40 (grey) is covered by extracellular loop 2 (ECL2; cyan) preventing entry from the extracellular space. Instead the allosteric regulator, TAK-875 (pink), accesses the binding pocket through the plasma membrane. (B) Structural determination of the lysophosphatidic acid receptor (LPA 1 ; PDB code: 4Z34). LPA 1 was crystallized with a stabilizing Cytochrome b 562 RIL subunit (circled in orange) inserted into the third intracellular loop and with membrane lipids bound to help orient LPA 1 in the plasma membrane. (C) Pharmacological regulation of metabotropic glutamate receptor 5 (mGlu5; PDB code: 4OO9). Slab view of the allosteric binding site (allosteric regulator mavoglurant (red)) within the 7-transmembrane helices of mGlu5 (green).
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.
Ubiquitous cellular esterases catalyze many essential biological functions by performing hydrolysis reactions on diverse substrates. These diverse substrates and functions however complicate a priori prediction of their substrate preferences and biological functions. Analogous to substrate activity screening for serine protease activity, we designed a 36‐member structure activity relationship (SAR) library of fluorogenic esterase substrates with low background hydrolysis, high sensitivity, and modular, straightforward synthesis. In three parallel substrate series containing alkyl, ether, and thioether substituents, the SAR library systemically interrogates esterase preference for chain length, branching patterns, polarity, and hydrogen bonding to differentiate common classes of esterase substrates. Applying this library against two structurally homologous bacterial esterases, previously broad overlapping substrate specificity was refined to preferences for γ‐position thioethers and ethers for ybfF from Vibrio cholerae and branched substrates with and without thioethers for Rv0045c from Mycobacterium tuberculosis. Structural control over this substrate differentiation was then assigned to individual substrate selectivity residues of Tyr116 in ybfF and His187 in Rv0045c whose reciprocal substitution inverted each esterase's substrate preference. This SAR esterase library could have multi‐faceted future applications including in vivo imaging, biocatalyst screening, molecular fingerprinting, and inhibitor design.Support or Funding InformationThis work was supported by a grant from the National Institutes of Health (NIH 1 R15 GM110641‐01A1).This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.
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