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. 1979 Oct;140(1):147–153. doi: 10.1128/jb.140.1.147-153.1979

Developmental induction of Myxococcus xanthus myxospores.

J Wireman
PMCID: PMC216790  PMID: 115838

Abstract

Myxospore differentiation during the developmental cycle of Myxococcus xanthus is characterized by several distinguishable morphological stages. Two experimentally useful criteria of myxospore induction are the conversion of vegetative rods to optically refractile short rods or ovoids and the development of resistance to sonic lysis. The use of optical refractility as the first morphological criterion of myxospore induction has facilitated an analysis of induction on developmental plates. The time-dependent changes in the cell population from vegetative rods to the final products of development, autolysed cells and myxospores, were determined in liquid suspension by interrupting cells from developmental plates before the first appearance of myxospores. The treatment of cells involved a two-step induction system. The cells were first aerated in buffer at 32 degrees C (preinduction) and then aerated in 1% tryptone (Difco) at 32 degrees C (induction). At early plate times (0 to 18 h) there was little or no response to these treatments. After 18 h, many of the cells undergoing development on plates responded to preinduction in buffer by subsequent induction to myxospores in tryptone medium (intermediate cells). After 32 h, cells induced to myxospores in tryptone medium and did not require preinduction (competent cells). After 36 h, cells begin to undergo differentiation to myxospores on plates. These results indicate that there was a sequence of physiological changes in developing cells that are defined by the differential response of cells to treatment in liquid suspension. The liquid induction system described here provides a means to analyze the regulation of developmental myxospore induction.

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Selected References

These references are in PubMed. This may not be the complete list of references from this article.

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