Abstract
Plasmids need to ensure their transmission to both daughter-cells when their host divides, but should at the same time avoid overtaxing their hosts by directing excessive host-resources toward production of plasmid factors. Naturally occurring plasmids have therefore evolved regulatory mechanisms to restrict their copy-number in response to the volume of the cytoplasm. In many plasmid families, copy-number control is mediated by a small plasmid-specified RNA, which is continuously produced and rapidly degraded, to ensure that its concentration is proportional to the current plasmid copy-number. We show here that pSA564 from the RepA_N-family is regulated by a small antisense RNA (RNA1), which, when over-expressed in trans, blocks plasmid replication and cures the bacterial host. The 5′ untranslated region (5′UTR) of the plasmid replication initiation gene (repA) potentially forms two mutually exclusive secondary structures, ON and OFF, where the latter both sequesters the repA ribosome binding site and acts as a rho-independent transcriptional terminator. Duplex formation between RNA1 and the 5′UTR shifts the equilibrium to favor the putative OFF-structure, enabling a single small RNA to down-regulate repA expression at both transcriptional and translational levels. We further examine which sequence elements on the antisense RNA and on its 5′UTR target are needed for this regulation. Finally, we identify the host-encoded exoribonucleases RNase J1 and J2 as the enzymes responsible for rapidly degrading the replication-inhibiting section of RNA1. This region accumulates and blocks RepA expression in the absence of either RNase J1 or J2, which are therefore essential host factors for pSA564 replication in Staphylococcus aureus.
Highlights
The bacterium Staphylococcus aureus is a versatile opportunistic pathogen present in the nasal cavities of 20–30% of the population (Mulcahy and McLoughlin, 2016)
Analysis of the pSA564 sequence revealed that it encodes a protein belonging to the RepA_N family of replication proteins (Weaver et al, 2009), between coordinates 20,793 to 21,737
Genetic Analyses of the pSA564 Replication Control Mechanism. Both pUTR269, which only carries a 269 bp region of pSA564, as well as pVG1, which replicates in S. aureus via a pSA564 minimal replicon, are incompatible with the extant pSA564 (Figures 2, 4)
Summary
The bacterium Staphylococcus aureus is a versatile opportunistic pathogen present in the nasal cavities of 20–30% of the population (Mulcahy and McLoughlin, 2016). Penicillin resistance had already been reported for S. aureus by the early 1940s (Lobanovska and Pilla, 2017), RNase J in Plasmid Replication Control and S. aureus has been proven to be a champion in acquiring antibiotic resistances by horizontal gene transfer. This transfer is efficient if the resistance gene is carried on a plasmid, as in the case of β-lactamases. The RepA_N family plasmids are generally large and replicate via a theta-replication mechanism They usually encode a marker for penicillin resistance and frequently have acquired additional resistance cassettes as well. The RepA_N family is widespread among Firmicutes, each individual plasmid appears to have a quite narrow host range (Weaver et al, 2009)
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