Roles of Escherichia coli histone-like protein HU in DNA replication: HU-beta suppresses the thermosensitivity of dnaA46ts.

The HU protein is a small, basic, heat-stable DNA-binding protein that is well-conserved in prokaryotes and is associated with the bacterial nucleoid. In enterobacteria, including Escherichia coli, HU is a heterotypic dimer, HUalphabeta, composed of two closely related sub-units encoded by the hupA and hupB genes, respectively. HU was shown to participate in vitro in the initiation of DNA replication as an accessory factor to assist the action of DnaA protein in the unwinding of oriC DNA. To further elucidate the role of HU in the regulation of the DNA replication initiation process, we tested the synchrony phenotype in the absence of either one or both HU sub-units. The hupAB mutant exhibits an asynchronous initiation, the hupA mutant shows a similar reduced synchrony, whereas the hupB mutant shows a normal phenotype. Using a thermosensitive dnaA46 strain (dnaA46ts), an initiation mutant, we reveal a special role of HUbeta. The presence of a plasmid overproducing HUbeta in a dnaA46ts lacking HU (hupAB background) compensates for the thermosensitivity of this initiation mutant. Moreover, the overproduction of HUbeta confers to dnaA46ts a pattern of asynchrony similar to that of a dnaAcos, the intragenic suppressor of dnaA46ts. We show that the relative ratio of HUalpha versus HUbeta is greatly perturbed in dnaA46ts which accumulates little, if any, HUbeta. Therefore, the suppression of thermosensitivity in dnaA46hupAB by HUbeta may be caused by an unexpected absence of HUbeta in the dnaA46ts mutant. Visibly the HU composition is sensitive to the different states of DnaA, and may play a role during the regulation of the initiation process of the DNA replication by affecting subsequent events along the cell cycle.

Increased sensitivity to gamma irradiation in bacteria lacking protein HU.

The heterodimeric HU protein, isolated from Escherichia coli, is associated with the bacterial nucleoid and shares some properties with both histones and HMG proteins. It is the prototype of small bacterial DNA binding proteins with a pleiotropic role in the cell. HU participates in several biological processes like cell division, initiation of DNA replication, transposition, and other biochemical functions. We show here that bacteria lacking HU are extremely sensitive to gamma irradiation. Expression of either one of the subunits of HU in the hupAB double mutant nearly restores the normal survival rate. This shows that the sensitivity is due to the absence of HU rather than being the result of a secondary mutation occurring in the hupAB cells or a modification of the SOS repair system, since SOS genes are induced normally in the absence of HU. Finally, in vitro studies give an indication of its potential role: HU protects DNA against cleavage by gamma-rays.

The protein HU can displace the LexA repressor from its DNA-binding sites.

The major bacterial histone-like protein HU is a small, basic, dimeric protein composed of two closely related subunits. HU is involved in several processes in the bacterial cell such as the initiation of replication, transposition, gene inversion and cell division. It has been suggested that HU could introduce structural changes to the DNA which would facilitate or inhibit the binding of regulatory proteins to their specific sites. In this study we investigated the effect of HU on the binding of LexA protein, the regulator of SOS functions, to three of its specific binding sites. We show that HU can displace LexA from its binding sites on the operators of the lexA, recA and sfiA genes. The lexA operator was the most sensitive while the higher affinity sfiA operator was the least sensitive. Since HU, like its homologue IHF, probably binds DNA in the minor groove we tested the effect of distamycin, a drug which binds to the minor groove, on LexA binding. Like HU, this drug disrupted LexA-operator complexes. These results suggest that distortion of the minor groove of the lexA operators excludes the binding of the repressor to the major groove.

HU and IHF: similarities and differences. In Escherichia coli, the lack of HU is not compensated for by IHF.

HU is one of the most abundant DNA binding proteins in Escherichia coli. Like the histones, HU is able to condense DNA in vitro and to introduce negative super-coiling in covalently closed circular, relaxed DNA molecules in the presence of topoisomerase I. HU is well conserved in all prokaryotes but surprisingly, it is also homologous to another E. coli DNA-binding protein, IHF. Contrary to HU, IHF shows sequence specificity and is much less abundant that HU. Both are heterodimers and all four polypeptide chains probably arose from a common ancestor. The question we raised was whether IHF could supply the main functions of HU in its absence. The answer seems to be negative for the following reasons. We did not observe any significant regulation of expression of the genes coding for HU by IHF, or vice-versa. The structures that these two proteins form with double-stranded or single-stranded DNA are completely different. Finally, overexpression of IHF does not relieve the growth defects observed in HU-less mutants. However, it can be speculated from our results that even if the two proteins are not equivalent and cannot replace one another, both could stimulate (or inhibit) some specific protein-DNA interactions or affect the DNA-binding properties of one another.