Cnu, a novel oriC-binding protein of Escherichia coli

We have found, using a newly developed genetic method, a protein (named Cnu, for oriC-binding nucleoid-associated) that binds to a specific 26-base-pair sequence (named cnb) in the origin of replication of Escherichia coli, oriC. Cnu is composed of 71 amino acids (8.4 kDa) and shows extensive amino acid identity to a group of proteins belonging to the Hha/YmoA family. Cnu was previously discovered as a protein that, like Hha, complexes with H-NS in vitro. Our in vivo and in vitro assays confirm the results and further suggest that the complex formation with H-NS is involved in Cnu/Hha binding to cnb. Unlike the hns mutants, elimination of either the cnu or hha gene did not disturb the growth rate, origin content, and synchrony of DNA replication initiation of the mutants compared to the wild-type cells. However, the cnu hha double mutant was moderately reduced in origin content. The Cnu/Hha complex with H-NS thus could play a role in optimal activity of oriC.     

Rifampicin-resistant initiation of chromosome replication from oriC in ihf mutants

IHF (integration host factor) mutants exhibit asynchronous initiation of chromosome replication from oriC as determined from flow cytometric analysis of cultures where RNA synthesis was inhibited with rifampicin. However, the run-out kinetics of chromosome replication in ihf mutants shows that they continue to produce oriCs for some time in the absence of RNA synthesis resulting in a twofold increase in the oriC per mass ratio. An ihf dnaA double mutant did not exhibit this continued increase of the oriC per mass ratio. This indicates that ihf mutants can initiate replication from oriC in a rifampicin-resistant initiation mode but requires fully functional DnaA protein. The origin per mass ratio, determined by a quantitative Southern blotting technique, showed that the ihf mutants had an origin per mass ratio that was 60% of the wild type although it had a normal DnaA protein concentration. This shows that the initiation mass was substantially higher in the ihf mutants. The oriC per terminus ratio, which was also determined by Southern blotting, was very low in the ihf mutant, although it grew with the same doubling times as the wild-type strain. This indicates that cells lacking IHF replicate their chromosome(s) very fast.     

The nucleoid-associated protein StpA binds curved DNA, has a greater DNA-binding affinity than H-NS and is present in significant levels in hns mutants

The StpA protein is closely related to H-NS, the well-characterised global regulator of gene expression which is a major component of eubacterial chromatin. Despite sharing a very high degree of sequence identify and having biochemical properties in common with H-NS, the physiological function of StpA remains unknown. We show that StpA exhibits similar DNA-binding activities to H-NS. Although both display a strong preference for binding to curved DNA, StpA binds DNA with a four-fold higher affinity than H-NS, with K(d)s of 0.7 microM and 2.8 microM, respectively. It has previously been reported that expression of stpA is derepressed in an hns mutant. We have quantified the amount of StpA protein produced under this condition and find it to be only one-tenth the level of H-NS protein in wild-type cells. Our findings explain why the presence of StpA does not compensate for the lack of H-NS in an hns mutant, and why the characteristic pleiotropic hns mutant phenotype is observed.     

Anucleate cell production by Escherichia coli delta hns mutant lacking a histone-like protein, H-NS.

Normal-sized anucleate cells were observed in the cultures of a delta hns mutant strain. Even in nucleate cells, some populations showed irregular intracellular localization of the nucleoids. The delta hns mutant showed reduced ploidy, although initiation of chromosome replication was essentially synchronous as defined by flow cytometric analysis. These results indicate that the delta hns mutant is defective in the mechanisms of chromosome partitioning and chromosome replication.     

The sequence requirements for a functional Escherichia coli replication origin are different for the chromosome and a minichromosome

We have developed a simple three-step method for transferring oriC mutations from plasmids to the Escherichia coli chromosome. Ten oriC mutations were used to replace the wild-type chromosomal origin of a recBCsbcB host by recombination. The mutations were subsequently transferred to a wild-type host by transduction. oriC mutants with a mutated DnaA box R1 were not obtained, suggesting that R1 is essential for chromosomal origin function. The other mutant strains showed the same growth rates, DNA contents and cell mass as wild-type cells. Mutations in the left half of oriC, in DnaA boxes M, R2 or R3 or in the Fis or IHF binding sites caused moderate asynchrony of the initiation of chromosome replication, as measured by flow cytometry. In mutants with a scrambled DnaA box R4 or with a modified distance between DnaA boxes R3 and R4, initiations were severely asynchronous. Except for oriC14 and oriC21, mutated oriCs could not, or could only poorly, support minichromosome replication, whereas most of them supported chromosome replication, showing that the classical definition of a minimal oriC is not valid for chromosome replication. We present evidence that the functionality of certain mutated oriCs is far better on the chromosome than on a minichromosome.     

Roles of the DNA binding proteins H-NS and StpA in homologous recombination and repair of bleomycin-induced damage in Escherichia coli

The DNA binding protein H-NS promotes homologous recombination in Escherichia coli, but the role of its paralog StpA in this process remains unclear. Here we show that an hns mutant, but not an stpA mutant, are marginally defective in conjugational recombination and is sensitive to the double-strand-break-inducing agent bleomycin. Interestingly, the hns stpA double mutant is severely defective in homologous recombination and more bleomycin-sensitive than is the hns or stpA single mutant, indicating that the stpA mutation synergistically enhances the defects of homologous recombination and the increased bleomycin-sensitivity in the hns mutant. In addition, the transduction analysis in the hns stpA double mutant indicated that the stpA mutation also enhances the defect of recombination in the hns mutant. These results suggest that H-NS plays an important role in both homologous recombination and repair of bleomycin-induced damage, while StpA can substitute the H-NS function. The recombination analysis of hns single, stpA single, and hns stpA double mutants in the recBC sbcA and recBC sbcBC backgrounds suggested that the reduction of the hns single or hns stpA double mutants may not be due to the defect in a particular recombination pathway, but may be due to the defect in a common process of the pathways. The model for the functions of H-NS and StpA in homologous recombination and double-strand break repair is discussed.     

Periodic formation of the oriC complex of Escherichia coli.

We examined formation of an oriC-membrane complex through the chromosome replication cycle by dot-blot hybridization using an oriC plasmid as a probe. In a wild-type culture synchronized for chromosome replication, oriC complex formation was observed periodically and transiently corresponding to the replication initiation event. Prior to initiation of replication the oriC complex was recovered in the outer membrane fraction as well as at the time of initiation of replication. Moreover, periodic formation of the oriC complex was observed even when further initiation of replication was suppressed by culturing an initiation ts mutant at the restrictive temperature. Similar periodic formation of the oriC complex was also observed when DNA elongation was inhibited by addition of nalidixic acid to the culture. However, the second periodic peak did not appear when rifampicin or chloramphenicol was added. Cells which formed the oriC complex at the restrictive temperature could immediately initiate chromosome replication when the cells were transferred to the permissive temperature. We conclude that the oriC region of Escherichia coli forms a specific complex periodically just before and at the time of initiation of chromosome replication and that oriC complex formation is a prerequisite for initiation of chromosome replication.     

Novel Escherichia coli mutant, dnaR, thermosensitive in initiation of chromosome replication.

A newly isolated Escherichia coli mutant thermosensitive in DNA synthesis had an allele named dnaR130, which was located at 26.3 minutes on the genetic map. The mutant was defective in initiation of chromosome replication but not in propagation at a high temperature. This mutant was capable of growing in the absence of the rnh function at the high temperature by means of a dnaA-independent replication mechanism. In the mutant exposed to the high temperature, an oriC plasmid was able to replicate, although at a lower rate than at the low temperature. The plasmid replication at the high temperature depended on the dnaA function essential for the initiation of replication from oriC. The mutant lacking the rnh function persistently maintained the oriC plasmid at the high temperature in a dnaA-dependent manner. Thus, the dnaR function was required for initiation of replication of the bacterial chromosome from oriC but not the oriC plasmid. This result reveals that a dnaR-dependent initiation mechanism that is dispensable for oriC plasmid replication operates in the bacterial chromosome replication.     

The bacteriophage lambda DNA replication protein P inhibits the oriC DNA- and ATP-binding functions of the DNA replication initiator protein DnaA of Escherichia coli

Under the condition of expression of lambda P protein at lethal level, the oriC DNA-binding activity is significantly affected in wild-type E. coli but not in the rpl mutant. In purified system, the lambda P protein inhibits the binding of both oriC DNA and ATP to the wild-type DnaA protein but not to the rpl DnaA protein. We conclude that the lambda P protein inhibits the binding of oriC DNA and ATP to the wild-type DnaA protein, which causes the inhibition of host DNA synthesis initiation that ultimately leads to bacterial death. A possible beneficial effect of this interaction of lambda P protein with E. coli DNA initiator protein DnaA for phage DNA replication has been proposed.     

Coordinated replication and sequestration of oriC and dnaA are required for maintaining controlled once-per-cell-cycle initiation in Escherichia coli

Escherichia coli cells were constructed in which the dnaA gene was moved to a location opposite oriC on the circular chromosome. In these cells the dnaA gene was replicated with significant delay relative to the origin. Consequently, the period where the newly replicated and hemimethylated oriC was sequestered no longer coincided with the period where the dnaA gene promoter was sequestered. DnaA protein synthesis was therefore expected to continue during origin sequestration. Despite a normal length of the sequestration period in such cells, they had increased origin content and also displayed asynchrony of initiation. This indicated that reinitiation occasionally occurred at some origins within the same cell cycle. The extra initiations took place in spite of a reduction in total DnaA protein concentration to about half of the wild-type level. We propose that this more efficient utilization of DnaA protein results from an increased availability at the end of the origin sequestration period. Therefore, coordinated sequestration of oriC and dnaA is required for maintaining controlled once-per-cell-cycle initiation.     

A comprehensive set of DnaA-box mutations in the replication origin, oriC, of Escherichia coli

We probed the complex between the replication origin, oriC , and the initiator protein DnaA using different types of mutations in the five binding sites for DnaA, DnaA boxes R1–R4 and M: (i) point mutations in individual DnaA boxes and combinations of them; (ii) replacement of the DnaA boxes by a scrambled 9 bp non-box motif; (iii) positional exchange; and (iv) inversion of the DnaA boxes. For each of the five DnaA boxes we found at least one type of mutation that resulted in a phenotype. This demonstrates that all DnaA boxes in oriC have a function in the initiation process. Most mutants with point mutations retained some origin activity, and the in vitro DnaA-binding capacity of these origins correlated well with their replication proficiency. Inversion or scrambling of DnaA boxes R1 or M inactivated oriC -dependent replication of joint replicons or minichromosomes under all conditions, demonstrating the importance of these sites. In contrast, mutants with inverted or scrambled DnaA boxes R2 or R4 could not replicate in wild-type hosts but gave transformants in host strains with deleted or compromised chromosomal oriC at elevated DnaA concentrations. We conclude that these origins require more DnaA per origin for initiation than does wild-type oriC . Mutants in DnaA box R3 behaved essentially like wild-type oriC , except for those in which the low-affinity box R3 was replaced by the high-affinity box R1. Apparently, initiation is possible without DnaA binding to box R3, but high-affinity DnaA binding to DnaA box R3 upsets the regulation. Taken together, these results demonstrate that there are finely tuned DnaA binding requirements for each of the individual DnaA boxes for optimal build-up of the initiation complex and replication initiation in vivo     

Drunken-cell footprints: nuclease treatment of ethanol-permeabilized bacteria reveals an initiation-like nucleoprotein complex in stationary phase replication origins.

The nucleoprotein complex formed on oriC, the Escherichia coli replication origin, is dynamic. During the cell cycle, high levels of the initiator DnaA and a bending protein, IHF, bind to oriC at the time of initiation of DNA replication, while binding of Fis, another bending protein, is reduced. In order to probe the structure of nucleoprotein complexes at oriC in more detail, we have developed an in situ footprinting method, termed drunken-cell footprinting, that allows enzymatic DNA modifying reagents access to intracellular nucleoprotein complexes in E.coli, after a brief exposure to ethanol. With this method, we observed in situ binding of Fis to oriC in exponentially growing cells, and binding of IHF to oriC in stationary cells, using DNase I and Bst NI endonuclease, respectively. Increased binding of DnaA to oriC in stationary phase was also noted. Because binding of DnaA and IHF results in unwinding of oriC in vitro, P1 endonuclease was used to probe for intracellular unwinding of oriC. P1 cleavage sites, localized within the 13mer unwinding region of oriC ', were dramatically enhanced in stationary phase on wild-type origins, but not on mutant versions of oriC unable to unwind. These observations suggest that most oriC copies become unwound during stationary phase, forming an initiation-like nucleoprotein complex.     

The DnaA box R4 in the minimal oriC is dispensable for initiation of Escherichia coli chromosome replication.

We have developed a genetic system with which to replace oriC+ on the Escherichia coli chromosome with modified oriC sequences constructed on plasmids. Using this system we have demonstrated that chromosomal oriC can tolerate the insertion of a 2 kb fragment at the HindIII site between DnaA boxes R3 and R4, whereas the same insertion completely inactivates cloned oriC. We have further found that although R4 is essential for the origin activity of cloned oriC, cells carrying a deletion of R4 in chromosomal oriC are viable. These results indicate that the oriC sequence necessary for initiation of chromosome replication is different from the so-called minimal oriC that was determined with cloned oriC. Flow cytometric analyses have revealed that these oriC mutations confer the initiation asynchrony phenotype. Introduction of the R4 deletion into a fis::kan mutant, which lacks the DNA bending protein FIS, renders the mutant cells inviable.     

Loss of Hda activity stimulates replication initiation from I-box, but not R4 mutant origins in Escherichia coli

Initiation of chromosome replication in Escherichia coli is limited by the initiator protein DnaA associated with ATP. Within the replication origin, binding sites for DnaA associated with ATP or ADP (R boxes) and the DnaA^ATP specific sites (I-boxes, τ-boxes and 6-mer sites) are found. We analysed chromosome replication of cells carrying mutations in conserved regions of oriC . Cells carrying mutations in DnaA-boxes I2, I3, R2, R3 and R5 as well as FIS and IHF binding sites resembled wild-type cells with respect to origin concentration. Initiation of replication in these mutants occurred in synchrony or with slight asynchrony only. Furthermore, lack of Hda stimulated initiation in all these mutants. The DnaA^ATP containing complex that leads to initiation can therefore be formed in the absence of several of the origin DnaA binding sites including both DnaA^ATP specific I-boxes. However, competition between I-box mutant and wild-type origins , revealed a positive role of I-boxes on initiation. On the other hand, mutations affecting DnaA-box R4 were found to be compromised for initiation and could not be augmented by an increase in cellular DnaA^ATP/DnaA^ADP ratio. Compared with the sites tested here, R4 therefore seems to contribute to initiation most critically.     

副溶血弧菌拟核相关蛋白H-NS间接抑制VP1687-1686的启动子区转录

为了探讨副溶血性弧菌拟核相关蛋白H-NS对Ⅲ型分泌系统(T3SS) VP1687-1686基因位点的转录调控,本研究提取副溶血弧菌hns突变株(Δhns)和野生株(WT)的总RNA,采用引物延伸实验研究靶基因的转录起始位点,并根据产物的丰度判断H-NS对靶基因的调控关系;采用实时定量RT-PCR研究靶基因mRNA在WT和Δhns中转录丰度,以判定H-NS对靶基因的转录调控关系;将靶基因启动子区域DNA序列克隆至lacZ基因上游,将重组质粒转入WT和Δhns中,得到相应的LacZ菌株,通过LacZ报告基因融合实验研究H-NS对靶基因的调控关系;用PCR扩增靶基因的启动子区DNA序列,并纯化His-H-NS蛋白,通过凝胶阻滞实验(EMSA)研究His-H-NS是否对靶基因启动子区具有直接的结合作用。研究结果显示,T3SS的VP1687-1686只含有一个转录起始位点,位于翻译起始位点上游82 bp处,且H-NS能够抑制其转录活性,但不能直接结合到VP1687-1686区的启动子区。另外,H-NS对calR的转录无调控作用,His-H-NS也不能结合到其启动子区。本研究的结果初步说明,H-NS能够间接抑制VP1687-1686的转录,该抑制机制与CalR无关联。