Three Conserved Glycine Residues in Valine Activation of Gramicidin S Synthetase 2 from Bacillus brevis

Abstract

The translated product from the gene fragment containing the second and third domains of gramicidin S synthetase 2 was purified to an essentially homogeneous state. It showed valine- and ornithine-activating activity and the second domain was proved to be the valine-activating domain. Three mutant genes from Bacillus brevis Nagano, BI-3, E-4, and E-5 strains, which encode defective valine-activating domains of gramicidin S synthetase 2, were sequenced. By comparison with the wild-type gene, single point mutations of guanine to adenine were found at the three conserved glycine codons; the 5303rd guanine in BI-3, the 5378th guanine in E-4, and the 4967th guanine in E-5, which corresponded to codon changes of the 1768th glycine to glutamic acid and the 1793rd and the 1656th glycine to aspartic acid. Loss of valine-adenylation activity by mutation at the 1656th glycine proved the direct participation of the TSGT/STGXPKG motif in the adenylation reaction, and suggests that this glycine residue with the conserved lysine residue of the motif forms the phosphate-binding loop for ATP-binding. The 1793rd glycine is a member of the YGXTE motif which was also conserved among adenylate-forming enzymes except acetyl-CoA synthetases. The 1768th glycine residue appears to maintain the conformation of the active site for aminoacyl adenylation since this residue is retained among the adenylate-forming enzymes, though flanking regions are not conserved. These results suggest that these glycine residues are essential for adenylate formation in the antibiotic peptide synthetase family and some other adenylate-forming enzymes.