A fail-safe mechanism in the septal ring assembly pathway generated by the sequential recruitment of cell separation amidases and their activators.

During cytokinesis in Escherichia coli, the peptidoglycan (PG) layer produced by the divisome must be split to promote cell separation. Septal PG splitting is mediated by the amidases: AmiA, AmiB, and AmiC. To efficiently hydrolyze PG, the amidases must be activated by LytM domain factors. EnvC specifically activates AmiA and AmiB, while NlpD specifically activates AmiC. Here, we used an exportable, superfolding variant of green fluorescent protein (GFP) to demonstrate that AmiB, like its paralog AmiC, is recruited to the division site by an N-terminal targeting domain. The results of colocalization experiments indicate that EnvC is recruited to the division site well before its cognate amidase AmiB. Moreover, we show that EnvC and AmiB have differential FtsN requirements for their localization. EnvC accumulates at division sites independently of this essential division protein, whereas AmiB localization is FtsN dependent. Interestingly, we also report that AmiB and EnvC are recruited to division sites independently of one another. The same is also true for AmiC and NlpD. However, unlike EnvC, we find that NlpD shares an FtsN-dependent localization with its cognate amidase. Importantly, when septal PG synthesis is blocked by cephalexin, both EnvC and NlpD are recruited to septal rings, whereas the amidases fail to localize. Our results thus suggest that the order in which cell separation amidases and their activators localize to the septal ring relative to other components serves as a fail-safe mechanism to ensure that septal PG synthesis precedes the expected burst of PG hydrolysis at the division site, accompanied by amidase recruitment.