FtsE, the Nucleotide Binding Domain of the ABC Transporter Homolog FtsEX, Regulates Septal PG Synthesis in E. coli

The peptidoglycan (PG) layer is an essential component of the E.coli envelope that is required to maintain cellular shape and integrity. Thus, coordinating PG synthesis and hydrolysis at the mid-cell (septal PG) is crucial during bacterial division. ABSTRACT The peptidoglycan (PG) layer, a crucial component of the tripartite E.coli envelope, is required to maintain cellular integrity, protecting the cells from mechanical stress resulting from intracellular turgor pressure. Thus, coordinating synthesis and hydrolysis of PG during cell division (septal PG) is crucial for bacteria. The FtsEX complex directs septal PG hydrolysis through the activation of amidases; however, the mechanism and regulation of septal PG synthesis are unclear. In addition, how septal PG synthesis and hydrolysis are coordinated has remained unclear. Here, we have shown that overexpression of FtsE leads to a mid-cell bulging phenotype in E.coli, which is different from the filamentous phenotype observed during overexpression of other cell division proteins. Silencing of the common PG synthesis genes murA and murB reduced bulging, confirming that this phenotype is due to excess PG synthesis. We further demonstrated that septal PG synthesis is independent of FtsE ATPase activity and FtsX. These observations and previous results suggest that FtsEX plays a role during septal PG hydrolysis, whereas FtsE alone coordinates septal PG synthesis. Overall, our study findings support a model in which FtsE plays a role in coordinating septal PG synthesis with bacterial cell division. IMPORTANCE The peptidoglycan (PG) layer is an essential component of the E.coli envelope that is required to maintain cellular shape and integrity. Thus, coordinating PG synthesis and hydrolysis at the mid-cell (septal PG) is crucial during bacterial division. The FtsEX complex directs septal PG hydrolysis through the activation of amidases; however, its role in regulation of septal PG synthesis is unclear. Here, we demonstrate that overexpression of FtsE in E.coli leads to a mid-cell bulging phenotype due to excess PG synthesis. This phenotype was reduced upon silencing of common PG synthesis genes murA and murB. We further demonstrated that septal PG synthesis is independent of FtsE ATPase activity and FtsX. These observations suggest that the FtsEX complex plays a role during septal PG hydrolysis, whereas FtsE alone coordinates septal PG synthesis. Our study indicates that FtsE plays a role in coordinating septal PG synthesis with bacterial cell division.

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