Macromolecular requirements for the physical initiation of cell division in a filamentous mutant of Agmenellum quadruplicatum

Peptidoglycan synthesis and turnover in cell division mutants of Agmenellum

The synthesis and turnover of peptidoglycan in Agmenellum quadruplicatum was investigated using D-[U-14C]alanine followed by proteolytic digestion. The rate of turnover of alanine in the peptide portion of the peptidoglycan was measured in strain BG-1 and in two division mutants of this strain: one was blocked in cell separation; and the other was a low-temperature, conditional cell division mutant. The peptide portion of peptidoglycan turned over in all three strains tested, but no correlation was observed between septum formation or cell separation and the rate of turnover. Peptidoglycan synthesis was measured during induced division in snake forms of strain SN-29. A stimulation of peptidoglycan synthesis was observed during the period of cross-wall formation, even in the absence of new protein synthesis. Thus in A. quadruplicatum, cross-wall synthesis is accompanied by a stimulation of peptidoglycan synthesis.

Cell division in Agmenellium quadruplicatum: evidence for the negative control by a protein

A high temperature conditional snake mutant, strain D1, of Agmenellum quadruplicatum was isolated which immediately stopped dividing following a shift to 41 degrees C following treatment with nitrosoguanidine. This mutant was stimulated to divide at 41 degrees C by the addition of inhibitors of RNA or protein synthesis: rifampicin, streptomycin, puromycin and chloramphenicol. Each of these inhibitors exhibited a discrete concentration optimum. The optimal concentration of chloramphenicol for cell division corresponded to the minimal concentrations necessary for the rapid inhibition of protein synthesis. The ability of chloramphenicol and other inhibitors to induce cell division in filaments decayed rapidly upon shifting to 30 degrees C. These results are interpreted as evidence for a protein acting as a negative regulator late in the cell cycle. At 41 degrees C, DNA was found distributed as a continuous zone throughout the length of the filaments. The addition of inhibitors of protein or RNA synthesis resulted in a rapid condensation of this nuclear material into multiple discrete nuclear regions suggesting that the negative control may be at the level of nuclear compartmentalization.

Cell separation in blue-green bacteria

Autolysin-like enzymes appear to be responsible for cell separation in Agmenellum quadruplicatum. Mutants that are impaired in cell separation and grow as chains exhibit reduced cell lytic activity. Lysozyme, extracted autolysin, and antibiotics that affect peptidoglycan synthesis phenotypically suppress chain formation. Various aspects of the regulation of the cell separation process were also examined. Studies involving antibiotic inhibitors of macromolecular synthesis and general growth inhibitors provided no evidence for the active regulation of the cell separation process during the latter portion of the division cycle. Evidence was obtained, however, for the partial restriction of peptidogly-can hydrolysis by unknown secondary modifications. The thin electron-dense layer of peptidoglycan along the sides of cells was much more resistant to hydrolysis by egg-white lysozyme than was the septum between daughter cells. The middle portion of the septum was more sensitive than was the layer immediately adjacent to the cytoplasmic membrane. Under conditions that would not osmotically stabilize spheroplasts, lysozyme facilitates rapid cell separation in chain-forming mutants with little leakage of cellular protein or loss of viability.