Abstract
The use of flow cytometry in microbiology allows rapid characterization of cells from a nonhomogeneous population. A method based on flow cytometry to assess the effects of lethal agents and the bacterial survival in starved cultures through the use of membrane potential-sensitive dyes and a nucleic acid marker is presented. The use of propidium iodide, rhodamine, and oxonol has facilitated the differentiation of cells of Escherichia coli and Salmonella typhimurium of various states of vitality following various treatments (heat, sonication, electroporation, and incubation with gramicidin) and during starvation in artificial seawater. The fluorescence intensity is directly correlated with viable cell counts for rhodamine 123 labelling, whereas oxonol and propidium iodide labelling is inversely correlated with viable counts. The distribution of rhodamine and oxonol uptake during starvation-survival clearly indicates that single-species starved bacteria are heterogeneous populations, and flow cytometry can be a fundamental tool for quantifying this heterogeneity.
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