Faculty Bibliography

Earlier studies have suggested the involvement of a small 1.3-kilobase plasmid, pSN2, in the production of enterotoxin D by certain Staphylococcus aureus strains. On the basis of extensive biochemical studies on pSN2, including the determination of its coding properties and its primary nucleotide sequence, we conclude that this plasmid is not in act involved in enterotoxin B production in S. aureus: although the toxin genes are apparently chromosomal, it is probable that they are part of a special genetic system such as a hitchhiking transposon

PT181 is a naturally occurring 4.5-kilobase Staphylococcus aureus plasmid encoding resistance to tetracycline. The plasmid has a copy number of about 20 per cell; a mutant, cop-608, that has a copy number of 800-1000 has been isolated. A cell-free extract has been developed that carries out complete replication of this plasmid. Extracts made from a strain containing the mutant have much greater replication activity than do extracts of strains containing pT181. In an extract from which endogenous DNA has been removed, DNA synthesis is dependent upon the addition of exogenous plasmid DNA. The replication system is specific for pT181 and related plasmids but it is inactive with other S. aureus plasmids. Furthermore, pT181 DNA does not replicate in extracts made from plasmid-negative strains or strains containing other plasmids. The results suggest that a specific plasmid-encoded substance is required for the replication of pT181 DNA

Plasmids in both Escherichia coli and Staphylococcus aureus contain an 'operon' that confers resistance to arsenate, arsenite, and antimony(III) salts. The systems were always inducible. All three salts, arsenate, arsenite, and antimony(III), were inducers. Mutants and a cloned deoxyribonucleic acid fragment from plasmid pI258 in S. aureus have lost arsenate resistance but retained resistances to arsenite and antimony, demonstrating that separate genes are involved. Arsenate-resistant arsenite-sensitive S. aureus plasmid mutants were also isolated. In E. coli, plasmid-determined arsenate resistance and reduced uptake were additive to that found with chromosomal arsenate resistance mutants. Arsenate resistance was due to reduced uptake of arsenate by the induced plasmid-containing cells. Under conditions of high arsenate, when some uptake could be demonstrated with the induced resistant cells, the arsenate was rapidly lost by the cells in the absence of extracellular phosphate. Sensitive cells retained arsenate under these conditions. When phosphate was added, phosphate-arsenate exchange occurred. High phosphate in the growth medium protected cells from arsenate, but not from arsenite or antimony(III) toxicity. We do not know the mechanisms of arsenite or antimony resistance. However, arsenite was not oxidized to less toxic arsenate. Since cell-free medium 'conditioned' by prior growth to induced resistant cells with toxic levels of arsenite or antimony(III) retained the ability to inhibit the growth of sensitive cells, the mechanism of arsenite and antimony resistance does not involve conversion of AsO2- or SbO+ to less toxic forms or binding by soluble thiols excreted by resistant cells