Dependence of macromolecular composition and morphology of Streptomyces hygroscopicus on specific growth rate.

The dependence of macromolecular composition and morphology of Streptomyces hygroscopicus on specific growth rate micron was investigated. The percentage of DNA on dry weight (%DNA) is constant, % protein is also nearly independent of micron whereas %RNA rises considerably with increasing micron, regarding mycelia grown in glucose-limited and ammonium-limited continuous cultures as well as in discontinuous cultures with various carbon sources. It is probable that the overall synthesis of DNA, RNA and protein is regulated in the mycelium-forming bacterium S. hygroscopicus by the same mechanisms found in unicellular bacteria like Escherichia coli because of the qualitatively similar dependence of %DNA, %RNA and %protein on micron. But differences exist in quantitative regard whereby %DNA, %RNA and %protein of S. hygroscopicus are much smaller at low micron and, with increasing micron, approach those of unicellular bacteria. The hypothesis about the increase of the hyphal regions showing high synthesis activity in S. hygroscopicus mycelia grown in glucose-limited continuous cultures with increasing micron -- derived from comparison of macromolecular composition of S. hygroscopicus and unicellular bacteria -- was confirmed autoradiographically with respect to protein synthesis. The increase of the part of mycelial regions showing high cytoplasmic activity results in an increase of mean hyphal diameter, of mean relative apical growth rate alpha and/or mean relative branching rate beta. Beta depends sigmoidally and alpha inverses sigmoidally on micron. Therefore, the morphology of the mycelium determined by alpha and beta also depends on micron. The hyphal growth unit L/N, the distance from apex to first branch Lp and the mean distance between neighbouring branches Ln decline with increasing micron and reach a minimum at micron = 0.32 (1/h). A further rise of micron is accompanied with an increase of L/N, Lp and Ln. This means that mycelia growing slowly or very quickly have a loose form whereas quickly growing mycelia are characterized by a more compact form. The complicated dependence of alpha, beta, L/N, Lp and Ln on micron indicates that the morphology is regulated by different mechanisms depending on the specific growth rate.

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