Reversible filamentous growth in the psychrophile Bacillus psychrophilus

At the near-maximum growth temperature of 32.5 °C, the psychrophile Bacillus psychrophilus loses the ability to septate and divide, resulting in the formation of filaments, which are four to six times longer than cells grown at 20 °C. DNA synthesis relative to growth occurs at the same rate both in the filaments at 32.5 °C, (which actually become multi-nucleated) and in normal-size cells at 20 °C, showing that the inhibition of DNA synthesis by the elevated temperature is not the cause of the filamentous growth, as has been found for other microorganisms. Similarly, temperature-sensitive cell-wall mucopeptide synthesis does not appear to be responsible. Reversal of filament production occurs when preformed filaments are incubated at 20 °C. Such reversal, i.e., septation of preformed filaments, requires the de novo synthesis of protein, probably throughout the reversal period.Filamentous cells are more nutritionally demanding than cells at 20 °C, with at least one substrate becoming limiting within 8 hr at 32.5 °C but not at 20 °C. However, such variation in nutritional requirement is not the cause of filament formation. KCl and NaCl stimulate cell division in cells growing at 32.5 °C but not in preformed filaments. Other membrane-active agents such as lysolecithin, dimethyl sulfoxide, ethanol, sodium oleate, and pantoyl lactone do not stimulate septum formation in filaments.