RNase H and replication of ColE1 DNA in Escherichia coli

Strand specificity of ribonucleotide excision repair in Escherichia coli

In Escherichia coli, replication of both strands of genomic DNA is carried out by a single replicase-DNA polymerase III holoenzyme (pol III HE). However, in certain genetic backgrounds, the low-fidelity TLS polymerase, DNA polymerase V (pol V) gains access to undamaged genomic DNA where it promotes elevated levels of spontaneous mutagenesis preferentially on the lagging strand. We employed active site mutants of pol III (pol IIIα_S759N) and pol V (pol V_Y11A) to analyze ribonucleotide incorporation and removal from the E. coli chromosome on a genome-wide scale under conditions of normal replication, as well as SOS induction. Using a variety of methods tuned to the specific properties of these polymerases (analysis of lacI mutational spectra, lacZ reversion assay, HydEn-seq, alkaline gel electrophoresis), we present evidence that repair of ribonucleotides from both DNA strands in E. coli is unequal. While RNase HII plays a primary role in leading-strand Ribonucleotide Excision Repair (RER), the lagging strand is subject to other repair systems (RNase HI and under conditions of SOS activation also Nucleotide Excision Repair). Importantly, we suggest that RNase HI activity can also influence the repair of single ribonucleotides incorporated by the replicase pol III HE into the lagging strand.

Phage Lambda P protein: trans-activation, inhibition phenotypes and their suppression

The initiation of bacteriophage λ replication depends upon interactions between the oriλ DNA site, phage proteins O and P, and E. coli host replication proteins. P exhibits a high affinity for DnaB, the major replicative helicase for unwinding double stranded DNA. The concept of P-lethality relates to the hypothesis that P can sequester DnaB and in turn prevent cellular replication initiation from oriC. Alternatively, it was suggested that P-lethality does not involve an interaction between P and DnaB, but is targeted to DnaA. P-lethality is assessed by examining host cells for transformation by ColE1-type plasmids that can express P, and the absence of transformants is attributed to a lethal effect of P expression. The plasmid we employed enabled conditional expression of P, where under permissive conditions, cells were efficiently transformed. We observed that ColE1 replication and plasmid establishment upon transformation is extremely sensitive to P, and distinguish this effect from P-lethality directed to cells. We show that alleles of dnaB protect the variant cells from P expression. P-dependent cellular filamentation arose in ΔrecA or lexA[Ind^-] cells, defective for SOS induction. Replication propagation and restart could represent additional targets for P interference of E. coli replication, beyond the oriC-dependent initiation step.

R-Loop in the replication origin of human mitochondrial DNA is resolved by RecG, a Holliday junction-specific helicase

Stable RNA-DNA hybrids (R-loops) prime the initiation of replication in Escherichia coli cells. The R-loops are resolved by Escherichia coli RecG protein, a Holliday junction specific helicase. A stable RNA-DNA hybrid formation in the mitochondrial D-loop region is also implicated in priming the replication of mitochondrial DNA. Consistent with this hypothesis, the 3' ends of the mitochondrial R-loop formed by in vitro transcription are located close to the initiation sites of the mitochondrial DNA replication. This mitochondrial R-loop is resolved by RecG in a dose-dependent manner. Since the resolution by RecG requires ATP, the resolution is dependent on the helicase activity of RecG. A linear RNA-DNA heteroduplex is not resolved by RecG, suggesting that RecG specifically recognizes the higher structure of the mitochondrial R-loop. This is the first example that R-loops of an eukaryotic origin is sensitive to a junction-specific helicase. The resolution of the mitochondrial R-loop by RecG suggests that the replication-priming R-loops have a common structural feature recognized by RecG.

Replication and control of circular bacterial plasmids

An essential feature of bacterial plasmids is their ability to replicate as autonomous genetic elements in a controlled way within the host. Therefore, they can be used to explore the mechanisms involved in DNA replication and to analyze the different strategies that couple DNA replication to other critical events in the cell cycle. In this review, we focus on replication and its control in circular plasmids. Plasmid replication can be conveniently divided into three stages: initiation, elongation, and termination. The inability of DNA polymerases to initiate de novo replication makes necessary the independent generation of a primer. This is solved, in circular plasmids, by two main strategies: (i) opening of the strands followed by RNA priming (theta and strand displacement replication) or (ii) cleavage of one of the DNA strands to generate a 3'-OH end (rolling-circle replication). Initiation is catalyzed most frequently by one or a few plasmid-encoded initiation proteins that recognize plasmid-specific DNA sequences and determine the point from which replication starts (the origin of replication). In some cases, these proteins also participate directly in the generation of the primer. These initiators can also play the role of pilot proteins that guide the assembly of the host replisome at the plasmid origin. Elongation of plasmid replication is carried out basically by DNA polymerase III holoenzyme (and, in some cases, by DNA polymerase I at an early stage), with the participation of other host proteins that form the replisome. Termination of replication has specific requirements and implications for reinitiation, studies of which have started. The initiation stage plays an additional role: it is the stage at which mechanisms controlling replication operate. The objective of this control is to maintain a fixed concentration of plasmid molecules in a growing bacterial population (duplication of the plasmid pool paced with duplication of the bacterial population). The molecules involved directly in this control can be (i) RNA (antisense RNA), (ii) DNA sequences (iterons), or (iii) antisense RNA and proteins acting in concert. The control elements maintain an average frequency of one plasmid replication per plasmid copy per cell cycle and can "sense" and correct deviations from this average. Most of the current knowledge on plasmid replication and its control is based on the results of analyses performed with pure cultures under steady-state growth conditions. This knowledge sets important parameters needed to understand the maintenance of these genetic elements in mixed populations and under environmental conditions.

Transcription and initiation of ColE1 DNA replication in Escherichia coli K-12

By S1 nuclease protection mapping, we characterized RNA transcripts and nascent ColE1 DNA synthesized in wild-type Escherichia coli cells after infection with lambda-mini-ColE1 hybrid bacteriophages. Transcription of the RNA II region of ColE1 DNA in vivo starts mostly from the RNA II promoter, which was identified by in vitro experiments, and ends at or near the ori site. Synthesis of the leading strand of ColE1 DNA was found to start at the ori site. Nevertheless, the molar ratio of the nascent DNA to the synthesized transcripts ending at the ori site was less than 0.05. In bacterial rnh mutants whose RNase H activities were less than 0.06% of that of the wild type, transcription patterns, as well as nascent DNA synthesis, were still similar to those in rnh+ cells. However, in bacteria whose rnh gene was interrupted by insertion of a drug resistance gene, the number of transcripts ending at the ori site was much reduced and that of transcripts reading through the ori site was definitely increased relative to that observed in wild-type bacteria. These results suggested that cleavage of the RNA transcript at the ori site in vivo is dependent on RNase H activity, as demonstrated in the in vitro system, but most of the cleaved RNA is unable to prime initiation of ColE1 DNA synthesis efficiently.

Ribonucleases H of retroviral and cellular origin

Ribonucleases H (RNases H) are enzymes which catalyse the hydrolysis of the RNA-strand of an RNA-DNA hybrid. Retroviral reverse transcriptases possess RNase H activity in addition to their RNA- as well as DNA-dependent DNA-polymerizing activity. These enzymes transcribe the viral single stranded RNA-genome into double stranded DNA, which then can be handled by the host cell like one of its own genes. Various, sometimes highly repeated, sequences related to retroviruses and like these encompassing two separate domains, one of which potentially codes for a DNA polymerizing, the other for an RNase H activity, are found in genomes of uninfected cells. In addition proteins coded for by cellular genes (e.g. from E. coli and from yeast) are known, which exhibit RNase H activity, the biological function of which is not fully understood. In the light of these facts the question of whether retroviral RNases H could be promising targets for antiviral drugs is discussed.

Replication of plasmids in gram-negative bacteria

Replication of plasmid deoxyribonucleic acid (DNA) is dependent on three stages: initiation, elongation, and termination. The first stage, initiation, depends on plasmid-encoded properties such as the replication origin and, in most cases, the replication initiation protein (Rep protein). In recent years the understanding of initiation and regulation of plasmid replication in Escherichia coli has increased considerably, but it is only for the ColE1-type plasmids that significant biochemical data about the initial priming reaction of DNA synthesis exist. Detailed models have been developed for the initiation and regulation of ColE1 replication. For other plasmids, such as pSC101, some hypotheses for priming mechanisms and replication initiation are presented. These hypotheses are based on experimental evidence and speculative comparisons with other systems, e.g., the chromosomal origin of E. coli. In most cases, knowledge concerning plasmid replication is limited to regulation mechanisms. These mechanisms coordinate plasmid replication to the host cell cycle, and they also seem to determine the host range of a plasmid. Most plasmids studied exhibit a narrow host range, limited to E. coli and related bacteria. In contrast, some others, such as the IncP plasmid RK2 and the IncQ plasmid RSF1010, are able to replicate in nearly all gram-negative bacteria. This broad host range may depend on the correct expression of the essential rep genes, which may be mediated by a complex regulatory mechanism (RK2) or by the use of different promoters (RSF1010). Alternatively or additionally, owing to the structure of their origin and/or to different forms of their replication initiation proteins, broad-host-range plasmids may adapt better to the host enzymes that participate in initiation. Furthermore, a broad host range can result when replication initiation is independent of host proteins, as is found in the priming reaction of RSF1010.

Isolation and characterization of herC, a mutation of Escherichia coli affecting maintenance of ColE1

Two modes of ColE1 DNA replication are known, one dependent on RNase H, and the other RNase H independent. The cer114 mutant of the ColE1 replicon is defective in both modes and carries a single base pair alteration 95 bp upstream of the replication origin. An Escherichia coli mutant which restored maintenance of the cer114 replicon was isolated. This host suppressor mutant is defective in RNase H and carries a herC mutation located at 62 min of the E. coli chromosome. The herC mutation is recessive to its wild-type allele and supports maintenance of the mutant replicon in the absence of RNase H. The herC mutation alone conferred cold-sensitive growth, suggesting that the herC gene product is essential for cell growth. The 1832 bp E. coli DNA fragment, containing the wild-type allele of the herC mutation, was cloned and an open reading frame for the HerC protein was determined.

Transcriptional activation of ColE1 DNA synthesis by displacement of the nontranscribed strand

Plasmid ColE1 can replicate using RNAase H and DNA polymerase I. However, it can also replicate in the absence of these enzymes. In this case, formation of a persistent hybrid between a transcript (RNA II) and the DNA indirectly activates subsequent DNA synthesis, instead of providing a primer as it does in the presence of these enzymes. To activate DNA synthesis, a certain length is required for the hybridized region and the region of minimum length cannot include a palindrome. These results show that the single-stranded region of DNA displaced by the hybridization is responsible for the activation. A single-stranded region was identified on the nontranscribed strand by its enhanced reactivity to dimethyl sulfate. The necessary length for the single-stranded region is at least 40 nucleotides. The region probably provides a site for initial binding of a helicase that further unwinds the template DNA for initiation of DNA synthesis.

Multiple mechanisms for initiation of ColE1 DNA replication: DNA synthesis in the presence and absence of ribonuclease H

A transcript (RNA II) of plasmid ColE1 that hybridizes with the template DNA is cleaved by RNAase H and used as a primer by DNA polymerase I. However, the plasmid can replicate in bacteria lacking both enzymes, apparently using a different mechanism of initiation of replication. Here we report in vivo and in vitro studies on initiation of DNA replication in the presence or absence of either or both enzymes. Hybridization of RNA II with the template DNA is always required for initiation. Hybridized RNA II is cleaved by RNAase H to form a primer or used as a primer without cleavage by RNAase H. Hybridization also creates a single-stranded region on the nontranscribed strand that can serve as a template for synthesis of the lagging strand in a reaction that does not require DNA polymerase I. Lagging strand synthesis terminates 17 nucleotides upstream of the normal replication origin, forcing unidirectional replication.

A temperature-dependent pBR322 copy number mutant resulting from a Tn5 position effect

In the process of randomly mutagenizing a recombinant pBR322 clone with transposon Tn5, a high copy number plasmid mutant, pLO88, has been isolated. The copy number phenotype of pLO88 is observed only at elevated temperatures, greater than or equal to 37 degrees C, and is due to the precise position of a Tn5 insertion. Nucleotide sequence of the Tn5-pBR322 junction reveals that Tn5-88 has inserted into an open reading frame that codes for a 63 amino acid protein previously shown to negatively regulate pBR322 plasmid copy number. By deleting portions of the Tn5 it is shown that the copy number phenotype is due not only to the insertion of Tn5 in pBR322 but also to the requirement that some Tn5 sequences remain intact. It appears that an outwardly directed Tn5 promoter initiates the synthesis of a transcript (RNA X) that interferes with the normal repressor RNA (RNA I)-primer RNA (RNA II) interaction at elevated temperatures.