Abstract
Studies of 31 strains of Moraxella urethralis have shown that 20 of them are competent for genetic transformation. This finding has led to the development of transformation assays for identification of newly isolated strains of this organism. Crude deoxyribonucleic acid (DNA) samples from all strains of M. urethralis readily transform auxotrophic mutants of competent strains to prototrophy, whereas DNA samples from unrelated bacteria such as Acinetobacter, Moraxella, and Neisseria species uniformly fail to elicit positive transformation of mutant tester strains. One of the competent strains of M. urethralis investigated is a naturally occurring mutant defective in its ability to utilize citrate as a carbon and energy source. DNA samples from 29 of the 30 remaining strains of utilization; the one nonreacting strain is citrate negative and probably possesses the same genetic lesion as the citrate-negative mutant. Three organisms originally identified as strains of M. urethralis, because of their phenotypic properties, are probably incorrectly designated, since DNA samples from these strains failed to transform any of the tester mutant strains used in the present study. The transformation assay for M. urethralis is very simple and can be performed readily in a clinical laboratory. The entire procedure can be carried out in less than 24 h.
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