A glutamine synthetase (GS; 1341 bp) gene with potent L-phosphinothricin (PPT) resistance was isolated and characterized from a marine bacterium Exiguobacterium sp. Molecular docking analysis indicated that the substitution of residues Glu60 and Arg64 may lead to significant changes in binding pocket. To enhance the enzymatic property of GS, variants E60A and R64G were obtained by site-directed mutagenesis. The results revealed a noteworthy change in the thermostability and activity in comparison to the wild type (WT). WT exhibited optimum activity at 35 °C, while E60A and R64G exhibited optimum activity at 45 and 40 °C, respectively. The mutant R64G was 4.3 times more stable at 70 °C in comparison to WT, while E60A was 5.7 times more stable. Kinetic analysis revealed that the k cat value of R64G mutant was 8.10-, 7.25- and 7.63-fold that of WT for ADP, glutamine and hydroxylamine, respectively. The kinetic inhibition (K i, 4.91 ± 0.42 mM) of R64G was 2.02-fold that of WT (2.43 ± 0.14 mM) for L-phosphinothricin. The analysis of structure and function relationship showed that the binding pocket underwent dramatic changes when Arg site of 64 was substituted by Gly, thus promoting the rapid capture of substrates and leading to increase in activity and PPT-resistance of mutant R64G. The rearrangements of the residues at the molecular level formed new hydrogen bonds around the active site, which contributed to the increase of thermostability of enzymes. This study provides new insights into substrate binding mechanism of glutamine synthetase and the improved GS gene also has a potential for application in transgenic crops with L-phosphinothricin tolerance.
Keywords: Glutamine synthetase; L-phosphinothricin; Molecular docking; Site directed mutagenesis; Thermostability.