Computational Insights into Glucose Tolerance and Stimulation in a Family 1 β‑glucosidase

Computational Insights into Glucose Tolerance and Stimulation in a Family 1 β‑glucosidase

β-Glucosidases catalyze the hydrolysis of cellobiose to glucose during lignocellulosic biomass depolymerization. A significant limitation of many β-glucosidases is product inhibition by glucose, leading to reduced conversion efficiency. However, certain β-glucosidases exhibit tolerance or even stimu...

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Αποθηκεύτηκε σε:
Λεπτομέρειες βιβλιογραφικής εγγραφής
Κύριος συγγραφέας: Artur H. S. Dias (21629751) (author)
Άλλοι συγγραφείς: Munir S. Skaf (162722) (author), Rodrigo L. Silveira (162673) (author)
Έκδοση: 2025
Θέματα:
Biophysics
Biochemistry
Genetics
Physiology
Chemical Sciences not elsewhere classified
Physical Sciences not elsewhere classified
trp349 side chain
reduced conversion efficiency
lignocellulosic biomass depolymerization
improve enzyme efficiency
forming direct interactions
directed mutagenesis experiments
considerably weaker ligand
binding free energies
substrate binding pocket
humicola insolens </
molecular mechanisms governing
glucose (− 4
cellobiose (− 12
substrate binding site
mitigating product inhibition
family 1 β
glucosidases exhibit tolerance
subsite − 1
bgl active site
product inhibition
active site
cellobiose substrate
molecular basis
mechanisms underlying
hi </
glucose tolerance
many β
glucose product
certain β
transglycosylation reactions
thereby enabling
substantial difference
specifically involving
spatially distant
significant limitation
oligosaccharide synthesis
may contribute
industrial applications
glucosidases catalyze
glucose molecules
computational insights
bulk solution
biofuel production
bgl ’
bgl surface
bgl solvated
bgl ).
allosteric regulation
5 kcal
3 kcal
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Περιγραφή
Περίληψη:β-Glucosidases catalyze the hydrolysis of cellobiose to glucose during lignocellulosic biomass depolymerization. A significant limitation of many β-glucosidases is product inhibition by glucose, leading to reduced conversion efficiency. However, certain β-glucosidases exhibit tolerance or even stimulation by glucose. The mechanisms underlying this remarkable feature remain poorly elucidated. Here, we employ molecular dynamics simulations to investigate the molecular basis of glucose tolerance and stimulation within the family 1 β-glucosidase from <i>Humicola insolens</i> (<i>Hi</i>Bgl). Potential of mean force calculations reveal a substantial difference in binding free energies between cellobiose (−12.5 kcal/mol) and glucose (−4.3 kcal/mol) at the <i>Hi</i>Bgl active site, indicating that the glucose product is a considerably weaker ligand than the cellobiose substrate. These findings are consistent with our observations that <i>Hi</i>Bgl undergoes conformational changes in its substrate binding site, specifically involving the Trp349 side chain, in the presence of glucose, potentially facilitating glucose expulsion and mitigating product inhibition. Simulations of <i>Hi</i>Bgl solvated in a 200 mM aqueous glucose environment show that glucose molecules from the bulk solution are capable of penetrating and widening the substrate binding pocket, forming direct interactions with cellobiose in the active site, which may contribute to catalytic stimulation. Additionally, we identify seven distinct secondary glucose binding sites located on the <i>Hi</i>Bgl surface, spatially distant from the active site, implying a potential role in allosteric regulation. Finally, we demonstrate that glucose at subsite +1 can adopt multiple orientations relative to glucose at subsite −1, a prerequisite for transglycosylation reactions in <i>Hi</i>Bgl. Our findings elucidate the molecular mechanisms governing <i>Hi</i>Bgl’s glucose tolerance and stimulation, thereby enabling the design of site-directed mutagenesis experiments to improve enzyme efficiency for industrial applications, particularly in biofuel production and oligosaccharide synthesis.

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