Transformation of Azotobacter vinelandii with plasmid DNA

Azotobacter vinelandii cells can be transformed at high frequencies with the broad-host-range plasmids pRK2501, RSF1010, and pGSS15, using a modification of the procedure developed by Page and von Tigerstrom (J. Bacteriol. 139:1058-1061, 1979) for chromosomal DNA-mediated transformation. The frequency of transformation per microgram of plasmid DNA per viable cell with pRK2501 and pGSS15 was about 5 X 10(-2) and 2 X 10(-2), respectively. With RSF1010, transformation frequencies ranged from 3 X 10(-4) to 4 X 10(-2). With each plasmid, the frequency of transformation was independent of the phase of the growth cycle. When concentrations of pRK2501 ranging from 0.1 to 51 micrograms of DNA were tested, the frequency of transformation was directly proportional to the amount of DNA. This linear response indicated that, although the uptake of plasmid DNA with this procedure may be inefficient, there is a high probability that once inside a cell the plasmid will be stably maintained. Cells that have been transformed with pRK2501 did not grow well on transforming medium which lacks iron and contains fixed nitrogen. However, on growth medium which contains iron and lacks fixed nitrogen, transformants produced distinctive colonies larger than those of nontransformed cells. Resistance to kanamycin due to transformation by pRK2501 was stably maintained for at least 10 successive generations in the absence of selective pressure. The present protocol should facilitate the molecular cloning of genes in Azotobacter spp.

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