NlpI-Prc Proteolytic Complex Mediates Peptidoglycan Synthesis and Degradation via Regulation of Hydrolases and Synthases in Escherichia coli

A novel peptidoglycan deacetylase modulates daughter cell separation in E. coli

Peptidoglycan hydrolases facilitate bacterial cell wall growth by creating space for insertion of new material and allowing physical separation of daughter cells. In Escherichia coli, three peptidoglycan amidases, AmiA, AmiB and AmiC, cleave septal peptidoglycan during cell division. The LytM-domain proteins EnvC and NlpD activate these amidases either from inside the cell or the outer membrane: EnvC binds to the cytoplasmic membrane-anchored divisome components FtsEX, and NlpD and ActS are outer membrane lipoproteins. Here we report the identification of a novel periplasmic deacetylase called SddA that removes acetyl groups from denuded peptidoglycan glycan strands, the products of amidases. SddA is a substrate for the periplasmic protease Prc, suggesting regulation via protein degradation. The sddA gene is co-expressed with the gene encoding EnvC, linking SddA function to amidase activation. Consistent with this link, the deletion of sddA alleviates phenotypes associated with lack of amidase activation, while overexpression of sddA alleviates phenotypes related to a defective Tol-Pal system and causes cell chaining due to reduced septum peptidoglycan cleavage unless envC is co-expressed. We present a model according to which SddA modulates the activation of the septum-splitting amidases during cell division.

A periplasmic protein modulates the proteolysis of peptidoglycan hydrolases to maintain cell wall homeostasis in Escherichia coli

Bacterial cell wall assembly and remodeling require activities of peptidoglycan (PG) hydrolases as well as PG synthases. In particular, the activity of DD-endopeptidases, which cleave the 4-3 peptide crosslinks in PG, is essential for PG expansion in gram-negative bacteria. Maintaining optimal levels of DD-endopeptidases is critical for expanding PG without compromising its integrity. In Escherichia coli, the levels of major DD-endopeptidases, MepS and MepH, along with the lytic transglycosylase MltD, are controlled by the periplasmic protease Prc and its outer membrane adaptor NlpI. However, the mechanisms regulating the turnover of these PG hydrolases have remained unclear. In this study, we identified a periplasmic protein, BipP (formerly YhjJ), that negatively controls the NlpI-Prc system. Further analyses indicate that BipP exerts this control by interacting with NlpI and inhibiting its substrate recognition in response to low DD-endopeptidase activity, providing insight into the homeostatic control of PG hydrolysis and cell wall expansion.

In Vivo Cross-Linking Sheds Light on the Salmonella Divisome in Which PBP3 and PBP3SAL Compete for Occupancy

Bacterial cell division is orchestrated by proteins that assemble in dynamic complexes collectively known as the divisome. Essential monofunctional enzymes with glycosyltransferase or transpeptidase (TPase) activities, FtsW and FtsI respectively, engage in the synthesis of septal peptidoglycan (sPG). Enigmatically, Salmonella has two TPases that can promote cell division independently: FtsI (PBP3) and the pathogen-specific paralogue PBP3SAL. How Salmonella regulates the assembly of the sPG synthase complex with these two TPases, is unknown. Here, we characterized Salmonella division complexes in wild-type cells and isogenic mutants lacking PBP3 or PBP3SAL. The complexes were cross-linked in vivo and pulled down with antibodies recognizing each enzyme. Proteomics of the immunoprecipitates showed that PBP3 and PBP3SAL do not extensively cross-link in wild type cells, supporting the presence of independent complexes. More than 40 proteins cross-link in complexes in which these two TPases are present. Those identified with high scores include FtsA, FtsK, FtsQLB, FtsW, PBP1B, SPOR domain-containing proteins (FtsN, DedD, RlpA, DamX), amidase activators (FtsX, EnvC, NlpD) and Tol-Pal proteins. Other cross-linked proteins are the protease Prc, the elongasome TPase PBP2 and, D,D-endo- and D,D-carboxypeptidases. PBP3 and PBP3SAL localize at midcell and compete for occupying the division complex in response to environmental cues. Thus, a catalytic-dead PBP3SAL-S300A variant impairs cell division in a high osmolarity and acidic condition in which it is produced at levels exceeding those of PBP3. Salmonella may therefore exploit an 'adjustable' divisome to exchange TPases for ensuring cell division in distinct environments and, in this manner, expand its colonization capacities.

Glycan strand cleavage by a lytic transglycosylase, MltD contributes to the expansion of peptidoglycan in Escherichia coli

Peptidoglycan (PG) is a protective sac-like exoskeleton present in most bacterial cell walls. It is a large, covalently crosslinked mesh-like polymer made up of many glycan strands cross-bridged to each other by short peptide chains. Because PG forms a continuous mesh around the bacterial cytoplasmic membrane, opening the mesh is critical to generate space for the incorporation of new material during its expansion. In Escherichia coli, the 'space-making activity' is known to be achieved by cleavage of crosslinks between the glycan strands by a set of redundant PG endopeptidases whose absence leads to rapid lysis and cell death. Here, we demonstrate a hitherto unknown role of glycan strand cleavage in cell wall expansion in E. coli. We find that overexpression of a membrane-bound lytic transglycosylase, MltD that cuts the glycan polymers of the PG sacculus rescues the cell lysis caused by the absence of essential crosslink-specific endopeptidases, MepS, MepM and MepH. We find that cellular MltD levels are stringently controlled by two independent regulatory pathways; at the step of post-translational stability by a periplasmic adaptor-protease complex, NlpI-Prc, and post-transcriptionally by RpoS, a stationary-phase specific sigma factor. Further detailed genetic and biochemical analysis implicated a role for MltD in cleaving the nascent uncrosslinked glycan strands generated during the expansion of PG. Overall, our results show that the combined activity of PG endopeptidases and lytic transglycosylases is necessary for successful expansion of the cell wall during growth of a bacterium.