1. H-NS specifically represses LEE5 promoter activity and Ler alleviates the repression by H-NS. PMID: 28013045
2. Transcription and stability of cas3 in Deltahns cells is limiting for resistance to phage. PMID: 26956996
3. we propose that, during E. coli evolution, the conservation of H-NS binding sites resulted in the diversification of the regulation of horizontally transferred genes, which may have facilitated E. coli adaptation to new ecological niches PMID: 26789284
4. Through DNA binding, the two proteins interplay to form a transient ternary complex Fpg/DNA/HU which results in the release of Fpg and the molecular entrapment of SSBs by HU PMID: 26392572
5. The fdeC gene encodes a protein that is expressed at the cell surface and promotes biofilm formation under continuous-flow conditions and is repressed by the global regulator H-NS. PMID: 25239893
6. It was concluded that H-NS exerts maximum repression of LEE5 via the specific sequence at around -138 and subsequently contacts a subunit of RNAP through oligomerization. PMID: 24610333
7. Bicyclomycin treatment leads to a decrease in binding signal for H-NS to the E. coli chromosome. PMID: 24499790
8. Both the DNA binding sites of H-NS as well as the function of StpA as a backup system might be selected for silencing highly transcribable genes. PMID: 23661089
9. We show that H-NS modulates the expression of the nrdAB and nrdDG operons in aerobically and in anaerobically growing cells. PMID: 23873909
10. H-NS represses LEE5p by binding to a cluster of A tracks upstream of -114 of the promoter. PMID: 22924981
11. RcsB-BglJ activates one of two H-NS-StpA repressed leuO promoters. PMID: 22295907
12. The product of bacreriophage T7 gene 5.5 (gp5.5) forms a stable complex with the Escherichia coli histone-like protein H-NS and transfer RNAs (tRNAs). PMID: 22566619
13. the attractive force that governs the Cnu-H-NS interaction is an ionic bond, unlike the hydrophobic interaction that is the major attractive force in most proteins. PMID: 22358512
14. HNS control the integrase IntI1 and integron promoters expression. PMID: 21778209
15. LeuO is a major player in antagonistic interplay against the universal silencer H-NS. PMID: 21883529
16. It binds to a middle domain of FliG that bridges the core parts of the rotor and parts nearer the edge that interact with the stator. PMID: 21890701
17. Rho-dependent transcription termination is regulated by the H-NS family of proteins. PMID: 21602341
18. Combinations of the rho, nusG, and nusA mutations were synthetically lethal, and the lethality was suppressed by expression of H-NS. PMID: 21602355
19. a new insight into the bolA regulation network demonstrating that H-NS represses the transcription of this important gene was provided. PMID: 21708124
20. H-NS formed 2 compact clusters per chromosome, driven by oligomerization of DNA-bound H-NS through interactions mediated by the amino-terminal domain of the protein; observations demonstrate H-NS plays a key role in global chromosome organization PMID: 21903814
21. Chromosomal and plasmidencoded H-NS proteins differ in their functional properties. PMID: 21320594
22. H-NS binds to long tracts of DNA, consistent with the linear spread of H-NS binding from high- to surrounding lower-affinity sites; the length of binding regions is associated with the degree of transcriptional repression imposed by H-NS. PMID: 21097887
23. H-NS directly controls regulators of stress resistance. PMID: 21034467
24. H-NS and LeuO are antagonistic regulators of CRISPR-based immunity. PMID: 20659289
25. The global regulator H-NS is required for e xtracellular DNA (eDNA) production since DNA was not detected for the hns mutant and production of H-NS restored eDNA production to wild-type levels. PMID: 20833130
26. findings substantiate the central role of RcsB in H-NS-mediated control of motility and acid stress resistance PMID: 20435136
27. These results demonstrate an active involvement of H-NS in the induction of the CRISPR-cas system and suggest a potential link between two prokaryotic defence systems against foreign DNA. PMID: 20132443
28. Binding of the IHF protein to a site immediately adjacent to fimS is required for phase-on orientational bias; in the absence of LRP and IHF binding, fimS adopts the off orientation and the H-NS protein is required to maintain this orientational bias. PMID: 19889099
29. protein-induced DNA bending plays an important role in HU site-specific DNA binding and supports a model of a mutually induced fit. PMID: 15322284
30. forms complexes with with YdgT in vivo PMID: 15458420
31. data show that the H-NS acts to repress the expression of traM and traJ as cells enter stationary phase, thereby decreasing mating ability to barely detectable levels PMID: 15491366
32. Analysis of mechanical response generated by binding of DNA-bending protein Hu to single tethered 48.5 kb lambda-DNA molecules finds that compaction of DNA increases with increasing Hu concentration. PMID: 15504049
33. key role for intrinsic conformational changes of Hha in modulating its interaction with H-NS PMID: 15720293
34. H-NS directly inhibits gadA and gadX transcription and, by controlling the intracellular level of the activator GadX, indirectly affects the expression of the whole gad system PMID: 15795232
35. the expression of the H-NS regulon is sensitive to small changes in the cellular level of H-NS, enabling the cell to response rapidly to environment cues PMID: 15819627
36. Results show that LRP binds to the regulatory region of bacterial rRNA promoters, and may contribute in combination with H-NS to the control of rRNA synthesis. PMID: 16238633
37. The oligomerization capacity of H-NS in vivo is effected by temperature, pH, and osmolarity. PMID: 16303134
38. StpA complements H-NS proteins defective in DNA binding to repress bgl, while in autoregulation of stpA it acts autonomously, indicating a difference in the mechanisms of repression. PMID: 16980475
39. role of hns in regulation of RpoS; findings suggest that H-NS regulates an RssB inhibitor or inhibitors PMID: 16980505
40. The results support the conclusion that the bacterial DNA-binding protein LRP, assisted by H-NS, forms a repressive nucleoprotein structure involved in regulation of rRNA transcription. PMID: 17196617
41. Identified as new member of the polyamine modulon together with RpoN and Cra. PMID: 17220219
42. crystal structure of the Escherichia coli nucleoid-associated HUalphabeta protein PMID: 17360520
43. The binding of H-NS to a transposase protein is a novel function for this important regulatory molecule. PMID: 17501923
44. analysis of H-NS repression by binding within the transcription unit PMID: 17569663
45. Data Show that H-NS prevented binding of RNA polymerase (RNAP) at the Hemolysin Protein E promoter (PhlyE). PMID: 17892462
46. The model for the functions of H-NS in homologous recombination and double-strand break repair is discussed PMID: 17991999
47. LeuO and H-NS regulate the expression of the yjjQ-bglJ operon and yjjP. PMID: 18055596
48. H-NS is shown to be a common regulator of multiple iron and other nutrient acquisition systems preferentially expressed at 37 degrees C and of general stress response, biofilm formation, and cold shock genes highly expressed at 23 degrees C. PMID: 19011022
49. At 37 degrees C, SlyA activates transcription of K5 capsule independent of H-NS but maximal transcription requires H-NS. PMID: 19114478
50. StpA binding profile reduced to one-third in the hns mutant and the H-NS binding profile was unaffected by stpA inactivation. PMID: 19151137

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KEGG: ecj:JW1225

STRING: 316385.ECDH10B_1297