BMC Microbiology (Mar 2024)
Structure predictions and functional insights into Amidase_3 domain containing N-acetylmuramyl-L-alanine amidases from Deinococcus indicus DR1
Abstract
Abstract Background N-acetylmuramyl-L-alanine amidases are cell wall modifying enzymes that cleave the amide bond between the sugar residues and stem peptide in peptidoglycan. Amidases play a vital role in septal cell wall cleavage and help separate daughter cells during cell division. Most amidases are zinc metalloenzymes, and E. coli cells lacking amidases grow as chains with daughter cells attached to each other. In this study, we have characterized two amidase enzymes from Deinococcus indicus DR1. D. indicus DR1 is known for its high arsenic tolerance and unique cell envelope. However, details of their cell wall biogenesis remain largely unexplored. Results We have characterized two amidases Ami1 Di and Ami2 Di from D. indicus DR1. Both Ami1 Di and Ami2 Di suppress cell separation defects in E. coli amidase mutants, suggesting that these enzymes are able to cleave septal cell wall. Ami1 Di and Ami2 Di proteins possess the Amidase_3 catalytic domain with conserved –GHGG- motif and Zn2+ binding sites. Zn2+- binding in Ami1 Di is crucial for amidase activity. AlphaFold2 structures of both Ami1 Di and Ami2 Di were predicted, and Ami1 Di was a closer homolog to AmiA of E. coli. Conclusion Our results indicate that Ami1 Di and Ami2 Di enzymes can cleave peptidoglycan, and structural prediction studies revealed insights into the activity and regulation of these enzymes in D. indicus DR1.
