Molecular switching of a DNA-sliding clamp to a repressor mediates long-range gene silencing

Long-range gene regulation is rare in bacteria and is confined to the classical DNA looping model. Here, we use a combination of biophysical approaches, including X-ray crystallography and single-molecule analysis, to show that long-range gene silencing on the plasmid RK2, a source of multidrug resistance across diverse Gram-negative bacteria, is achieved cooperatively by a DNA-sliding clamp, KorB, and a clamp-locking protein, KorA. We find that KorB is a CTPase clamp that can entrap and slide along DNA to reach distal target promoters. We resolved the tripartite crystal structure of a KorB-KorA-DNA co-complex, revealing that KorA latches KorB into a closed-clamp state. KorA thus stimulates repression by stalling KorB sliding at target promoters to occlude RNA polymerase holoenzymes. Altogether, our findings explain the mechanistic basis for KorB role-switching from a DNA-sliding clamp to a co-repressor, and provide a new paradigm for the long-range regulation of gene expression. Overall design: Illumina paired-end deep-sequencing to determine plasmid copy number in relation to genome copy number