Functional analysis of a palindromic sequence required for normal replication of several staphylococcal plasmids.

Most small multicopy antibiotic-resistance plasmids of Staphylococcus aureus contain a major axis of hyphenated dyad symmetry (palA) that is required for normal replication and stability, although located outside of the minimal replicon. Rearrangements affecting palA cause plasmid instability, a marked reduction in copy number, and the accumulation of large quantities of strand-specific circular single-stranded plasmid DNA. In view of the recent observation that pT181 initiates replication by a nick and 3'-extension mechanism (S. Khan, personal communication), it is suggested that these plasmids replicate by an asymmetric rolling-circle mechanism in which the displaced plus strand remains single stranded until palA is exposed, forming a hairpin that serves as the lagging strand origin.

Cloning, sequence, and expression of the lysostaphin gene from Staphylococcus simulans.

A 1.5-kilobase-pair fragment of DNA that contains the lysostaphin gene from Staphylococcus simulans and its flanking sequences has been cloned and completely sequenced. The gene encodes a preproenzyme of Mr 42,000. The NH2-terminal sequence of the preproenzyme is composed of a signal peptide followed by seven tandem repeats of a 13-amino acid sequence. Conversion of prolysostaphin to the mature enzyme occurs extracellularly in cultures of S. simulans and involves removal of the NH2-terminal portion of the proenzyme that contains the tandem repeats. The high degree of homology of the repeats suggests that they have arisen by duplication of a 39-base-pair sequence of DNA. In S. simulans, the lysostaphin gene is present on a large beta-lactamase plasmid.

Genetic translocation in Staphylococcus aureus.

A 5.2-kilobase pair transposon, Tn551, has been found in Staphylococcus aureus, a Gram-positive bacterium. Initially detected on plasmid pI258, it undergoes rec-independent transposition to multiple chromosomal and plasmid sites, sometimes causing insertional inactivation. Unlike most other transposons, Tn551 undergoes apparently precise excision as a rule. The initial observation of Tn551 transition involved UV inactivation of the carrier plasmid; this would appear to be a general means of detecting transposable elements.