RNase H and replication of ColE1 DNA in Escherichia coli

Amber mutations within the rnh (RNase H) gene of Escherichia coli K-12 were isolated by selecting for bacteria capable of replicating in a sup+ background replication-defective cer-6 mutant of the ColE1 replicon. The cer-6 mutation is an alteration of one base pair located 160 nucleotides upstream of the unique replication origin of this plasmid. Subsequently, we determined the DNA alterations present within these mutants. ColE1 DNA replicated in rnh(Am) recA cells, indicating that (i) RNase H, which has been shown to be absolutely required for in vitro initiation of ColE1 DNA replication, is dispensable in vivo, and (ii) ColE1 replication in the absence of RNase H is not dependent on "stable DNA replication," which has been reported to be an alternative mode of chromosomal DNA replication. Another class of bacterial mutations was also isolated. These mutations, named herB, suppressed cer-6 replication in rnh+ bacteria. herB mutations mapped close to the polA gene on the E. coli chromosome and increased the activity of DNA polymerase I. These findings suggest that when the DNA polymerase I has an opportunity to initiate DNA synthesis before RNase H acts, the replication-defective cer-6 mutant or the wild-type ColE1 replicates in E. coli.     

RecA protein acts at the initiation of stable DNA replication in rnh mutants of Escherichia coli K-12.

Escherichia coli rnh mutants lacking RNase H activity are capable of recA+-dependent DNA replication in the absence of concomitant protein synthesis (stable DNA replication). In rnh dnaA::Tn10 and rnh delta oriC double mutants in which the dnaA+-dependent initiation of DNA replication at oriC is completely blocked, the recA200 mutation encoding a thermolabile RecA protein renders both colony formation and DNA synthesis of these mutants temperature sensitive. To determine which stage of DNA replication (initiation, elongation, or termination) was blocked, we analyzed populations of these mutant cells incubated at 30 or 42 degrees C in the presence or absence of chloramphenicol (CM) by dual-parameter (DNA-light scatter) flow cytometry. Incubation at 30 degrees C in the presence of CM resulted in cells with a continuum of DNA content up to seven or more chromosome equivalents per cell. The cultures which had been incubated at 42 degrees C in the absence or presence of CM consisted of cells with integral numbers of chromosomes per cell. It is concluded that active RecA protein is required specifically for the initiation of stable DNA replication.     

RNase H eliminates R‐loops that disrupt DNA replication but is nonessential for efficient DSB repair

In Saccharomyces cerevisiae, genome stability depends on RNases H1 and H2, which remove ribonucleotides from DNA and eliminate RNA–DNA hybrids (R‐loops). In Schizosaccharomyces pombe, RNase H enzymes were reported to process RNA–DNA hybrids produced at a double‐strand break (DSB) generated by I‐PpoI meganuclease. However, it is unclear if RNase H is generally required for efficient DSB repair in fission yeast, or whether it has other genome protection roles. Here, we show that S. pombe rnh1? rnh201? cells, which lack the RNase H enzymes, accumulate R‐loops and activate DNA damage checkpoints. Their viability requires critical DSB repair proteins and Mus81, which resolves DNA junctions formed during repair of broken replication forks. “Dirty” DSBs generated by ionizing radiation, as well as a “clean” DSB at a broken replication fork, are efficiently repaired in the absence of RNase H. RNA–DNA hybrids are not detected at a reparable DSB formed by fork collapse. We conclude that unprocessed R‐loops collapse replication forks in rnh1? rnh201? cells, but RNase H is not generally required for efficient DSB repair.     

Either bacteriophage T4 RNase H or Escherichia coli DNA polymerase I is essential for phage replication.

Bacteriophage T4 rnh encodes an RNase H that removes ribopentamer primers from nascent DNA chains during synthesis by the T4 multienzyme replication system in vitro (H. C. Hollingsworth and N. G. Nossal, J. Biol. Chem. 266:1888-1897, 1991). This paper demonstrates that either T4 RNase HI or Escherichia coli DNA polymerase I (Pol I) is essential for phage replication. Wild-type T4 phage production was not diminished by the polA12 mutation, which disrupts coordination between the polymerase and the 5'-to-3' nuclease activities of E. coli DNA Pol I, or by an interruption in the gene for E. coli RNase HI. Deleting the C-terminal amino acids 118 to 305 from T4 RNase H reduced phage production to 47% of that of wild-type T4 on a wild-type E. coli host, 10% on an isogenic host defective in RNase H, and less than 0.1% on a polA12 host. The T4 rnh(delta118-305) mutant synthesized DNA at about half the rate of wild-type T4 in the polA12 host. More than 50% of pulse-labelled mutant DNA was in short chains characteristic of Okazaki fragments. Phage production was restored in the nonpermissive host by providing the T4 rnh gene on a plasmid. Thus, T4 RNase H was sufficient to sustain the high rate of T4 DNA synthesis, but E. coli RNase HI and the 5'-to-3' exonuclease of Pol I could substitute to some extent for the T4 enzyme. However, replication was less accurate in the absence of the T4 RNase H, as judged by the increased frequency of acriflavine-resistant mutations after infection of a wild-type host with the T4 rnh (delta118-305) mutant.     

The impact of lagging strand replication mutations on the stability of CAG repeat tracts in yeast

We have examined the stability of long tracts of CAG repeats in yeast mutants defective in enzymes suspected to be involved in lagging strand replication. Alleles of DNA ligase (cdc9-1 and cdc9-2) destabilize CAG tracts in the stable tract orientation, i.e., when CAG serves as the lagging strand template. In this orientation nearly two-thirds of the events recorded in the cdc9-1 mutant were tract expansions. While neither DNA ligase allele significantly increases the frequency of tract-length changes in the unstable orientation, the cdc9-1 mutant produced a significant number of expansions in tracts of this orientation. A mutation in primase (pri2-1) destabilizes tracts in both the stable and the unstable orientations. Mutations in a DNA helicase/deoxyribonuclease (dna2-1) or in two RNase H activities (rnh1Delta and rnh35Delta) do not have a significant effect on CAG repeat tract stability. We interpret our results in terms of the steps of replication that are likely to lead to expansion and to contraction of CAG repeat tracts.     

Nucleotide sequences required for a ColE1-type plasmid to replicate in Escherichia coli cells with or without RNase H

To elucidate the replication mechanism of a ColE1-type plasmid in RNase H-deficient (rnh-) strains of Escherichia coli, we constructed plasmid derivatives that deleted the whole, or a part, of the 5'-AAAAA-3' sequence (positions -3 to +2) that acts as the origin of replication in vivo and in vitro in the presence of RNase H. The activity of plasmid replication in rnh+ cells was found to be reduced by alterations of the AAAAA sequence. The activity could be restored when the derivatives, retaining the upstream sequence down to -8, regained a sequence containing at least two A residues in the region from -3 to +2. By contrast, replication in rnh- cells was maintained at high levels even when the deletion included the AAAAA sequence and extended up to position -7. The activity in rnh- cells decreased as deletions proceeded to -8 and further up to -17, and was abolished completely by further upward deletions. We concluded that in rnh- cells the plasmid replicates by a mechanism that operates only when RNase H is inactive. This RNase H-sensitive replication in rnh- cells seems to require the RNA-DNA hybrid formation that is also required for RNase H-dependent replication in rnh+ cells. The hybrid formation probably contributes by unwinding a portion of DNA from which replication can be initiated.     

Mismatch repair-independent tandem repeat sequence instability resulting from ribonucleotide incorporation by DNA polymerase ε

During DNA synthesis in vitro using dNTP and rNTP concentrations present in vivo, yeast replicative DNA polymerases α, δ and ? (Pols α, δ and ?) stably incorporate rNTPs into DNA. rNTPs are also incorporated during replication in vivo, and they are repaired in an RNase H2-dependent manner. In strains encoding a mutator allele of Pol ? (pol2-M644G), failure to remove rNMPs from DNA due to deletion of the RNH201 gene encoding the catalytic subunit of RNase H2, results in deletion of 2-5 base pairs in short repetitive sequences. Deletion rates depend on the orientation of the reporter gene relative to a nearby replication origin, suggesting that mutations result from rNMPs incorporated during replication. Here we demonstrate that 2-5 base pair deletion mutagenesis also strongly increases in rnh201Δ strains encoding wild type DNA polymerases. As in the pol2-M644G strains, the deletions occur at repetitive sequences and are orientation-dependent, suggesting that mismatches involving misaligned strands arise that could be subject to mismatch repair. Unexpectedly however, 2-5 base pair deletion rates resulting from loss of RNH201 in the pol2-M644G strain are unaffected by concomitant loss of MSH3, MSH6, or both. It could be that the mismatch repair machinery is unable to repair mismatches resulting from unrepaired rNMPs incorporated into DNA by M644G Pol ?, but this possibility is belied by the observation that Msh2-Msh6 can bind to a ribonucleotide-containing mismatch. Alternatively, following incorporation of rNMPs by M644G Pol ? during replication, the conversion of unrepaired rNMPs into mutations may occur outside the context of replication, e.g., during the repair of nicks resulting from rNMPs in DNA. The results make interesting predictions that can be tested.     

Isolation of RNase H genes that are essential for growth of Bacillus subtilis 168

Two genes encoding functional RNase H (EC 3.1.26.4) were isolated from a gram-positive bacterium, Bacillus subtilis 168. Two DNA clones exhibiting RNase H activities both in vivo and in vitro were obtained from a B. subtilis DNA library. One (28.2 kDa) revealed high similarity to Escherichia coli RNase HII, encoded by the rnhB gene. The other (33.9 kDa) was designated rnhC and encodes B. subtilis RNase HIII. The B. subtilis genome has an rnhA homologue, the product of which has not yet shown RNase H activity. Analyses of all three B. subtilis genes revealed that rnhB and rnhC cannot be simultaneously inactivated. This observation indicated that in B. subtilis both the rnhB and rnhC products are involved in certain essential cellular processes that are different from those suggested by E. coli rnh mutation studies. Sequence conservation between the rnhB and rnhC genes implies that both originated from a single ancestral RNase H gene. The roles of bacterial RNase H may be indicated by the single rnhC homologue in the small genome of Mycoplasma species.     

Concatemer formation of ColE1-type plasmids in mutants of Escherichia coli lacking RNase H activity

rnh mutants harboring pBR322 were found to contain several slowly migrating DNA species when examined by agarose gel electrophoresis. The plasmid DNA from rnh mutants included large molecules, i.e. plasmids two, three or four times the size of a single plasmid unit. That this DNA contained concatemeric plasmid joined in a head-to-tail fashion was determined by digestion with restriction endonucleases that cleaved the monomeric plasmid DNA at a unique site. This treatment resulted in migration of the plasmid DNA at a mobility identical to that of linearized monomeric plasmid by agarose gel electrophoresis. This was confirmed by electron microscopy. Plasmid concatemer formation was detected with several high-copy-number (relaxed type) plasmids but not with low-copy-number (stringent) plasmids. Concatemer formation was dependent on RecA+ and RecF+ functions since several recA and recF mutations abolished concatemer formation. ColE1-type plasmids were previously shown to replicate in rnh mutants in the absence of DNA polymerase I (PolI) activity. This DNA PolI-independent plasmid replication was also examined for its dependence on the recF and recA gene products. rnh- polA(Ts) recF- strains were efficiently transformed with these plasmids at 30 degrees C and 42 degrees C, indicating the presence of DNA PolI-independent replication under recF- conditions. The presence or absence of plasmid replication in rnh- polA- recA(Ts) strains was also examined by measuring the increase in total amounts of plasmid. The results indicated that DNA PolI-independent replication occurred in these triple mutants at 42 degrees C as well as at 30 degrees C. It was concluded that the recombination event giving rise to concatemer formation was not essential for DNA PolI-independent replication in rnh mutants.     

Amplified Rnase H Activity in Escherichia coli B/R Increases Sensitivity to Ultraviolet Radiation

Strains of E. coli B/r transformed with the plasmid pSK760 were found to be sensitized to inactivation by ultraviolet radiation (UV) and to have elevated levels of RNase H activity. Strains transformed with the carrier vector pBR322 or the plasmid pSK762C derived from pSK760 but with an inactivated rnh gene were not sensitized. UV-inactivation data for strains having known defects in DNA repair and transformed with pSK760 suggested an interference by RNase H of postreplication repair: uvrA cells were strongly sensitized, wild-type and uvrA recF cells were moderately sensitized and recA cells were not sensitized; and minimal medium recovery was no longer apparent in sensitized uvrA cells. Biochemical studies showed that post-UV DNA synthesis was sensitized and that the smaller amounts of DNA synthesized after irradiation, while of normal reduced size as indicated by sedimentation position in alkaline sucrose gradients, did not shift to a larger size (more rapidly sedimenting) upon additional incubation. We suggest an excess level of RNase H interferes with reinitiation of DNA synthesis on damaged templates to disturb the normal pattern of daughter strand gaps and thereby to inhibit postreplication repair.     

The DNA replication fork blocked at the Ter site may be an entrance for the RecBCD enzyme into duplex DNA.

In Escherichia coli, eight kinds of chromosome-derived DNA fragments (named Hot DNA) were found to exhibit homologous recombinational hotspot activity, with the following properties. (i) The Hot activities of all Hot DNAs were enhanced extensively under RNase H-defective (rnh) conditions. (ii) Seven Hot DNAs were clustered at the DNA replication terminus region on the E. coli chromosome and had Chi activities (H. Nishitani, M. Hidaka, and T. Horiuchi, Mol. Gen. Genet. 240:307-314, 1993). Hot activities of HotA, -B, and -C, the locations of which were close to three DNA replication terminus sites, the TerB, -A, and -C sites, respectively, disappeared when terminus-binding (Tau or Tus) protein was defective, thereby suggesting that their Hot activities are termination event dependent. Other Hot groups showed termination-independent Hot activities. In addition, at least HotA activity proved to be dependent on a Chi sequence, because mutational destruction of the Chi sequence on the HotA DNA fragment resulted in disappearance of the HotA activity. The HotA activity which had disappeared was reactivated by insertion of a new, properly oriented Chi sequence at the position between the HotA DNA and the TerB site. On the basis of these observations and positional and orientational relationships between the Chi and the Ter sequences, we propose a model in which the DNA replication fork blocked at the Ter site provides an entrance for the RecBCD enzyme into duplex DNA.     

Mutational spectrum analysis of RNase H(35) deficient Saccharomyces cerevisiae using fluorescence-based directed termination PCR

Mutational spectrum analysis has become an informative genetic tool to understand those protein functions involved in mutation avoidance pathways since specific types of mutations are often associated with particular protein defects involved in DNA replication and repair. In this study, we describe a novel, fluorescence-based procedure for direct determination of deletions and insertions with 100% accuracy. We performed two complementary directed termination PCR with near infrared dye-labeled primers, followed by visualization of termination fragments using an automated Li-cor DNA sequencer. This method is used for rapid analysis of mutational spectra generated in nuclease-defective strains of Saccharomyces cerevisiae to elucidate the role of RNase H(35) in RNA primer removal during DNA replication and in mutation avoidance. Strains deficient in RNH35 displayed a distinct spontaneous mutation spectrum of deletions characterized by a unique 4 bp deletion in a lys2-Bgl allele. This was in sharp contrast to strains deficient in rad27 that displayed duplication mutations. Further analysis of mutations in a rnh35/rad27 double mutant revealed a mixed spectrum. These results indicate that RNase H(35) may participate in a redundant pathway in Okazaki fragment processing and that mutational spectra caused by protein deficiencies may be more intermediate-specific than pathway-specific.     

Effects of modulation of RNase H production on the recovery of DNA synthesis following UV-irradiation in Escherichia coli

The requirements for the recovery of DNA synthesis in UV-irradiated Escherichia coli were analysed in strains having varied levels of RNase H and RecA protein. We have previously shown (Khidhir et al. 1985) that the recovery of DNA synthesis in E. coli following UV treatment is an inducible SOS function requiring protein synthesis. We proposed that this reflected the need for the synthesis of specific induced replisome reactivation factor(s) for recovery. In this study we now show that recovery of DNA synthesis can in fact take place in the absence of protein synthesis in a mutant lacking RNase H and having high (constitutive) levels of RecA protein. We also show that expression of rnh is inhibited during the SOS response in recA+ but not in a recA- strain. The results are discussed in relation to the mechanism of recovery of DNA synthesis following UV irradiation in E. coli.