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ABSTRACT
Escherichia coli cells containing the ColE1 plasmid or related plasmids are killed by considerably lower levels of mitomycin C (MTC) than are plasmid-free cells. Since exposure to MTC induces high levels of synthesis of the plasmid-encoded colicin toxin, it was originally thought that the killing effect was due to the increased levels of colicin. This possibility was discounted when it was shown that deletion mutations in the plasmid lacking most of the colicin (cea) gene still sensitized host cells to MTC. Only when the region containing the cea gene promoter was deleted did the killing effect disappear. This led to the suggestion that transcription originating from the cea gene promoter and not the colicin protein itself was required for killing. Transcription-blocking mutations in the cea gene support this suggestion. It was proposed that there is a gene (kil) located downstream from the cea gene in the same operon that is responsible for MTC killing and colicin transport. The precise location of the kil gene in ColE1 can be predicted by piecing together published sequence information. We used available sequence data to construct a number of well-defined plasmid mutants to further examine the relevance of transcription from the cea promoter and the kil gene to drug-induced killing and colicin transport. The most informative mutant had a small insertion in the kil gene. This mutant behaved as predicted; cells containing it had a greatly lowered sensitivity to MTC and were severely inhibited in the transport of colicin.
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