Antibacterial action of gramicidin S and tyrocidines in relation to active transport, in vitro transcription, and spore outgrowth.

The cyclopeptide antibiotic gramicidin S or tyrocidine in concentrations of 2 to 4 mumol/mg of membrane protein inhibited the active transport of [3H]alanine and [3H]uridine in membrane vesicles isolated from Bacillus brevis and Bacillus subtilis. We used one analog of gramicidin S and two of tyrocidine A to study the relationship between peptide structure and antibacterial action as seen in inhibiting active transport and in vitro transcription and in delaying spore outgrowth. The data showed that [Ser2,2']-gramicidin S, in which the two ornithine residues were replaced by two serines, was at least 50 times less active antibacterially and gave a low response in transport inhibition and delay of spore outgrowth compared with the natural peptide. The antibacterial activity of [Val6]-tyrocidine A was twice lower than that of tyrocidine A, and it also showed a considerable reduction in transport and transcription inhibition. [Orn7]-tyrocidine A containing two ornithine residues in positions corresponding to those in gramicidin S was almost inactive in all functions tested. The correlation between peptide structure and activity is discussed.

Biological role of gramicidin S in spore functions. Studies on gramicidin-S-negative mutants of Bacillus brevis ATCC9999.

Gramicidin-S-negative mutants of Bacillus brevis ATCC9999 have been isolated with a remarkly higher yield after ethidium bromide or acridine orange treatment, than after N-methyl-N'-nitro-N-nitrosoguanidine treatment. Four (MIV, Smr170, R5 and EB 16) of 38 isolated mutants were characterized with respect to the lesion in gramicidin-S-synthesizing activity. The mutants sporulate to the same extent as the parental strain except mutant Smr 170 which sporulates less. However, mutant spores were more heat-sensitive and possessed a reduced level of dipicolinic acid content. No significant difference was observed in the germination time of wild-type and mutant spores. All spores germinated after 80--110 min, but the outgrowth time was different: all gramicidin-S-negative mutants grew out immediately after germination whereas wild-type spores required a lag period of 9--10 h. When the mutants were allowed to sporulate in the presence of gramicidin S, the spores were found to be heat-resistant and their outgrowth postponed to the same period as the parent spores. The addition of gramicidin also eliminated the deficiency of dipicolinic acid. A new class of gramicidin-S-negative mutant, R5, which only activates L-valine and L-leucine, is described. A possible biological function of gramicidin S in the heat-resistance and in the timing of spore outgrowth is discussed.