Abstract
Restriction–modification (RM) systems are extremely widespread among bacteria and archaea, and are often specified by mobile genetic elements. In type II RM systems, where the restriction endonuclease (REase) and protective DNA methyltransferase (MTase) are separate proteins, a major regulatory challenge is delaying expression of the REase relative to the MTase after RM genes enter a new host cell. Basic understanding of this regulation is available for few RM systems, and detailed understanding for none. The PvuII RM system is one of a large subset in which the central regulatory role is played by an activator–repressor protein (called C, for controller). REase expression depends upon activation by C, whereas expression of the MTase does not. Thus delay of REase expression depends on the rate of C-protein accumulation. This is a nonlinear process, as C also activates transcription of its own gene. Mathematical modeling of the PvuII system led to the unexpected predictions of responsiveness to a factor not previously studied in RM system control—gene copy number—and of a hysteretic response. In this study, those predictions have been confirmed experimentally. The results may apply to many other C-regulated RM systems, and help explain their ability to spread so widely.
Highlights
Restriction–modification (RM) systems are extremely widespread among bacteria and archaea [1]
The perils of misregulating Type IIP RM systems are illustrated by the fact that at least some of them behave as toxin–antitoxin systems, with the restriction endonuclease (REase) as toxin and the MTase as antitoxin, and exhibit ‘selfish’ behavior [9,10,11]
Loss of the genes for the RM system can result in death of the host cell, as protective methylation decreases before REase activity disappears
Summary
Restriction–modification (RM) systems are extremely widespread among bacteria and archaea [1]. They have been found in nearly every major bacterial group, save for some species that grow exclusively inside eukaryotic host cells. Loss of the genes for the RM system can result in death of the host cell, as protective methylation decreases before REase activity disappears. Despite their importance, basic understanding of gene regulation is available for few RM systems, and detailed understanding for none
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