Abstract
Retaining β-exoglucosidases operate by a mechanism in which the key amino acids driving the glycosidic bond hydrolysis act as catalytic acid/base and nucleophile. Recently we designed two distinct classes of fluorescent cyclophellitol-type activity-based probes (ABPs) that exploit this mechanism to covalently modify the nucleophile of retaining β-glucosidases. Whereas β-epoxide ABPs require a protonated acid/base for irreversible inhibition of retaining β-glucosidases, β-aziridine ABPs do not. Here we describe a novel sensitive method to identify both catalytic residues of retaining β-glucosidases by the combined use of cyclophellitol β-epoxide- and β-aziridine ABPs. In this approach putative catalytic residues are first substituted to noncarboxylic amino acids such as glycine or glutamine through site-directed mutagenesis. Next, the acid/base and nucleophile can be identified via classical sodium azide-mediated rescue of mutants thereof. Selective labeling with fluorescent β-aziridine but not β-epoxide ABPs identifies the acid/base residue in mutagenized enzyme, as only the β-aziridine ABP can bind in its absence. The Absence of the nucleophile abolishes any ABP labeling. We validated the method by using the retaining β-glucosidase GBA (CAZy glycosylhydrolase family GH30) and then applied it to non-homologous (putative) retaining β-glucosidases categorized in GH1 and GH116: GBA2, GBA3, and LPH. The described method is highly sensitive, requiring only femtomoles (nanograms) of ABP-labeled enzymes.
Highlights
Cyclophellitol-derived activity-based probes label the nucleophile of retaining -glucosidases by exploiting their catalytic mechanism
Our approach entails a combination of site-directed mutagenesis, subsequent identification of putative catalytic residues by sodium azide-mediated rescue of enzymatic activity, and discrimination between the acid/base and nucleophile by detection of activity-based probes (ABPs) 2-labeled -glucosidases on slab-gels
Elucidation of the Acid/Base and Nucleophile in GBA—The nucleophile (Glu-340) and acid/base (Glu-235) of GBA have been identified unequivocally (Fig. 2a) [29, 39], and we used this enzyme to validate our envisioned method where nucleophile-modifying cyclophellitol ABPs can distinguish the location of the acid/base and nucleophile in retaining -glucosidases
Summary
Cyclophellitol-derived activity-based probes label the nucleophile of retaining -glucosidases by exploiting their catalytic mechanism. In retaining -glucosidases, sodium azide-mediated rescue results in retention of stereochemistry in the case of acid/base absence (-azidoglucoside; Fig. 1f) and inversion of stereochemistry when the nucleophile is lacking (␣-azidoglucoside; Fig. 1g) [31,32,33] Success of this method hinges on the ability to isolate and identify the nature of the glucosazide adduct formed, which essentially means that the approach works best when executed on isolated, soluble mutant glycosidases. Our approach entails a combination of site-directed mutagenesis, subsequent identification of putative catalytic residues by sodium azide-mediated rescue of enzymatic activity, and discrimination between the acid/base and nucleophile by detection of ABP 2-labeled -glucosidases on slab-gels. We demonstrate through application of our ABP methodology that none of the proteins klotho, klotho, and KLPH (GH1) possesses -glucosidase activity
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