UC Berkeley

Mycobacterium tuberculosis (Mtb) cell wall, built on a cross-linked sugar-peptide polymer called peptidoglycan, protects the bacterial cell from adverse environments. Peptidoglycan homeostasis is maintained by extracellular peptidoglycan synthases and hydrolases. Intricate coordination of their activities is required to maintain structural integrity of the cell wall during growth, division, and response to stress. The sensor protein kinase B (PknB) is likely to play a critical role in monitoring the state of the peptidoglycan outside the cell and inducing subsequent metabolic changes inside. In this study, computational, biochemical, and structural approaches were used to characterize the peptidoglycan hydrolases of Mtb and to investigate the molecular mechanism of peptidoglycan signaling through PknB.

Peptidoglycan hydrolases are critical players in bacterial growth, division, cell shape determination, and peptidoglycan fragment-mediated communication. Computational analysis identified 22 mycobacterial peptidoglycan hydrolases based on homology to known enzymes from model organisms. The peptidoglycan degradation machinery of Mtb includes 4 N-acetylmuramoyl-L-alanine amidases, 8 lytic transglycosidases, and 10 peptidases of various specificities. Ten of these enzymes form a core set of mycobacterial peptidoglycan hydrolases, while four of them are essential for growth in Mtb. Comprehensive biochemical and structural investigation of the Mtb peptidoglycan hydrolases was initiated by cloning and heterologously expressing constructs representing all 22 Mtb peptidoglycan hydrolases in Escherichia coli. Robust expression was observed for all but one target protein. Twelve were successfully purified on large scale.

The peptidoglycan amidases Rv3717 and Rv3915 share similar catalytic cores yet have non-redundant functions in peptidoglycan turnover. Hydrolase activity assays using polymerized peptidoglycan sacculi and soluble peptidoglycan fragments elucidated contributions of individual amino acid residues, metal binding, and disulfide bond formation to catalysis. The structure of product-bound Rv3717 suggested a mechanism that limits this enzyme's activity on polymerized sacculi.

Peptidoglycan D,D-peptidases Rv2911, Rv3330 and Rv3627 are low molecular weight penicillin-binding proteins that participate in peptidoglycan maturation and degradation. Surprisingly, these three enzymes were inactive on peptidoglycan sacculi or peptidoglycan fragments, yet were active on beta-lactams meropenem and Bocillin. The structure of Rv3330 solved in complex with meropenem revealed a potential peptide-binging groove distant from the active site. The observed lack of activity of low molecular weight penicillin-binding proteins suggests a requirement for an activator. Discovery of such factors will significantly advance our understanding of Mtb peptidoglycan homeostasis.

PknB is an essential sensor kinase that controls cell wall biosynthesis. Its homologs in Gram-positive bacteria have been implicated in binding peptidoglycan fragments and in mediating bacterial responses to cell wall stress. To investigate the mechanism of peptidoglycan recognition by PknB, the structure of its extracellular sensor domain was solved. It consists of four 70-amino acid PASTA repeat domains that adopt an extended conformation. The last repeat domain contains a hydrophobic pocket with a conserved tryptophan, a signature of a ligand-binding site. The structure of PknB extracellular domain suggests that ligand-dependent localization and oligomerization control kinase activity.