Summary
The phenomenon of conjugation consists of many stages. The most important are: the formation of contacts between mating cells, the transfer of DNA from the donor to the recipient, and the integration of the transfered DNA fragments into the chromosome of the recipient. Only after completion of all these stages are recombinants formed. With the aid of specific inhibitiors (nalidixic acid, FUDR), thymine starvation, and use of special thermosensitive mutants it is possible to study the role of DNA synthesis during every stage of conjugation. It was demonstrated that the genetic transfer is due to semiconservative DNA-replication in the donor cell. The fragments of DNA transfered are synthesized in the period of mating by a special replication system (F-replicon). In case of T S DNA mutants unable to grow at 41°, the ability to synthesize DNA during conjugation is preserved.
The inhibition of the DNA synthesis in the donor cell by poisons leads to complete inhibition of genetic transfer. The third stage — formation of recombinants requires DNA synthesis in the recipient cell and is inhibited by poisoning, thymine starvation or T S DNA mutations in the recipient. In cases where recombination is not involved (i.e. sexduction) the inhibition of DNA synthesis in the recipient has no significant effect.
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Communicated by P. Starlinger and R. H. Pritchard
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Bresler, S.E., Lanzov, V.A. & Lukjaniec-Blinkova, A.A. On the mechanism of conjugation in Escherichia coli K 12. Molec. Gen. Genet. 102, 269–284 (1968). https://doi.org/10.1007/BF00433718
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DOI: https://doi.org/10.1007/BF00433718