On the chronology and topography of bacterial cell division

The production of the bacterial DNA replication inhibitor Microcin B17 is induced as cultures enter stationary phase. Using S1 nuclease protection assays we have shown that this induction is the result of increased levels of transcription initiation from a promoter located upstream from mcbA, the structural gene for Microcin B17. Upstream from the start site of transcription there is a rather typical -35 region. However, there is no good homology to the consensus -10 region. While most of the cell's transcription is shut off as a result of the cessation of growth, transcription from the mcbA promoter continues for several hours in stationary phase. A single-copy gene fusion between mcbA and lacZ was used to monitor the response of the promoter to different nutritional conditions and in different host backgrounds altered in metabolic regulatory loci. Starvation for nitrogen, phosphate or carbon sources all induced transcription from the promoter. Levels of transcription were reduced in ompR backgrounds. In contrast, mutations in other global regulatory loci, fnr, relA and cya had little or no effect.

Mutations in the ftsA gene of Escherichia coli conferred a higher resistance to lysis induced by penicillin or by a combination of cefsulodin and furazlocillin. The ftsA2 allele codes for an FtsA protein which is inactive at 42 degrees C but is able to regain its activity once it is transferred back to 30 degrees C; ftsA2 filaments formed at 42 degrees C in the presence of penicillin divided once the penicillin was removed and the temperature was lowered to 30 degrees C. Potential septation sites in the filaments of wild-type cells treated in the same way remained inactive. The binding of a radioactively labeled derivative of ampicillin to penicillin-binding protein 3 (PBP3) was significantly decreased in strain D-3, containing the mutant allele ftsA3, when the binding assay was performed at the restrictive temperature. A molecular species able to cross-react with an anti-PBP3 serum was nevertheless found to be present in the envelope of D-3 cells. These observations suggested that the FtsA protein, a protein with a structural and regulatory role in septation, and PBP3, a protein enzymatically active in the synthesis of murein for septation, interact with each other.

Antisera able to recognize FtsA, one of the septal proteins of Escherichia coli, have been obtained and used to show that native FtsA, when expressed at levels ranging from physiological to induced from lambda pR, is located in the inner membrane. Experiments of trypsin accessibility to FtsA in membranes, spheroplasts, and vesicles indicated that FtsA is located such that it faces the cytoplasm. This location is consistent with current knowledge about the participation of FtsA in a molecular complex active in cell division called septator.