2008
DOI: 10.1016/j.mib.2008.02.011
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New insights into transcriptional regulation by H-NS

Abstract: H-NS, a nucleoid-associated DNA-binding protein of enteric bacteria, was discovered thirty-five years ago and subsequently found to exert widespread and highly pleiotropic effects on gene regulation. H-NS binds to high-affinity sites and spreads along adjacent AT-rich DNA to silence transcription. Preferential binding to sequences with higher AT-content than the resident genome allows H-NS to repress the expression of foreign DNA in a process known as "xenogeneic silencing." Counter-silencing by a variety of m… Show more

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Cited by 188 publications
(186 citation statements)
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“…3 A and B). H-NS proteins are a family of global regulators that bind A-T-rich regions and are usually used to silence horizontally acquired genes (30). Proteins within the H-NS family have been suggested to be involved in T6SS regulation (31,32).…”
Section: Loss Of a Conserved Conjugative Resistance Plasmid Results mentioning
confidence: 99%
“…3 A and B). H-NS proteins are a family of global regulators that bind A-T-rich regions and are usually used to silence horizontally acquired genes (30). Proteins within the H-NS family have been suggested to be involved in T6SS regulation (31,32).…”
Section: Loss Of a Conserved Conjugative Resistance Plasmid Results mentioning
confidence: 99%
“…The ability of H-NS to influence nucleoid structure and gene expression at the level of transcription initiation has been variously attributed to its different yet inter-related mechanistic properties, including those of high-affinity and low-affinity DNA binding, assembly into a polymeric scaffold, and induction of alterations in DNA architecture such as bending, bridging, stiffening, coating, looping, and supercoiling (16,20,23,32,39,61). H-NS has also been implicated in direct RNA binding and translational regulation (41).…”
Section: Discussionmentioning
confidence: 99%
“…The presence of the two dimerization interfaces allows H-NS to assemble (either alone or with its paralogous partner StpA [53,55,60,65,67]) into a helical polymeric scaffold around which DNA is bound (3,22). Binding of H-NS to DNA results in several structural (including supercoiling) alterations that have been variously referred to as bending, bridging, coating, looping, and stiffening of the DNA (16,20,23,32,39,61). YdgT and Hha bear structural resemblance to, and also interact with, the N-terminal oligomerization domains of H-NS and StpA; in this manner, YdgT and Hha are believed to modulate the DNA-binding and nucleoid-organizing properties of H-NS and StpA even though they do not bind DNA by themselves (23,30,33,38,42,55).…”
mentioning
confidence: 99%
“…The result has been described as H-NSmediated transcriptional silencing (Bouffartigues et al, 2007;Fang & Rimsky, 2008;Göransson et al, 1990;Lang et al, 2007;Lucchini et al, 2006;Madhusudan et al, 2005;McGovern et al, 1994;Murphree et al, 1997;Navarre et al, 2006;Nye et al, 2000;Petersen et al, 2002;Westermark et al, 2000;Will et al, 2004). It has been estimated from single-molecule studies using optical tweezers that the force required to disrupt an H-NS-DNA bridge is 7 pN at an unzipping rate of 70 bp s 21 , which is the speed of RNA polymerase; RNA polymerase can exert a force of up to 25 pN (Dame et al, 2006).…”
Section: H-ns and Transcription Repressionmentioning
confidence: 99%