Recombination-dependent concatemeric plasmid replication.

The replication of covalently closed circular supercoiled (form I) DNA in prokaryotes is generally controlled at the initiation level by a rate-limiting effector. Once initiated, replication proceeds via one of two possible modes (theta or sigma replication) which do not rely on functions involved in DNA repair and general recombination. Recently, a novel plasmid replication mode, leading to the accumulation of linear multigenome-length plasmid concatemers in both gram-positive and gram-negative bacteria, has been described. Unlike form I DNA replication, an intermediate recombination step is most probably involved in the initiation of concatemeric plasmid DNA replication. On the basis of structural and functional studies, we infer that recombination-dependent plasmid replication shares important features with phage late replication modes and, in several aspects, parallels the synthesis of plasmid concatemers in phage-infected cells. The characterization of the concatemeric plasmid replication mode has allowed new insights into the mechanisms of DNA replication and recombination in prokaryotes.     

Bacteriophage T7 DNA packaging. I. Plasmids containing a T7 replication origin and the T7 concatemer junction are packaged into transducing particles during phage infection

Bacteriophage T7 DNA is a linear duplex molecule with a 160 base-pair direct repeat (terminal redundancy) at its ends. During replication, large DNA concatemers are formed, which are multimers of the T7 genome linked head to tail through recombination at the terminal redundancy. We define the sequence that results from this recombination, a mature right end joined to the left end of T7 DNA, as the concatemer junction. To study the processing and packaging of T7 concatemers into phage particles, we have cloned the T7 concatemer junction into a plasmid vector. This plasmid is efficiently (at least 15 particles/infected cell) packaged into transducing particles during a T7 infection. These transducing particles can be separated from T7 phage by sedimentation to equilibrium in CsCl. The packaged plasmid DNA is a linear concatemer of about 40 x 10(3) base-pairs with ends at the expected T7 DNA sequences. Thus, the T7 concatemer junction sequence on the plasmid is recognized for processing and packaging by the phage system. We have identified a T7 DNA replication origin near the right end of the T7 genome that is necessary for efficient plasmid packaging. The origin, which is associated with a T7 RNA polymerase promoter, causes amplification of the plasmid DNA during T7 infection. The amplified plasmid DNA sediments very rapidly and contains large concatemers, which are expected to be good substrates for the packaging reaction. When cloned in pBR322, a sequence containing only the mature right end of T7 DNA is sufficient for efficient packaging. Since this sequence does not contain DNA to the right of the site where a mature T7 right end is formed, it was expected that right ends would not form on this DNA. In fact, with this plasmid the right end does not form at the normal T7 sequence but is instead formed within the vector. Apparently, the T7 packaging system can also recognize a site in pBR322 DNA to produce an end for packaging. This site is not recognized solely by a "headful" mechanism, since there can be considerable variation in the amount of DNA packaged (32 x 10(3) to 42 x 10(3) base-pairs). Furthermore, deletion of this region from the vector DNA prevents packaging of the plasmid. The end that is formed in vector DNA is somewhat heterogeneous. About one-third of the ends are at a unique site (nucleotide 1712 of pBR322), which is followed by the sequence 5'-ATCTGT-3'. This sequence is also found adjacent to the cut made in a T7 DNA concatemer to produce a normal T7 right end.     

Recombination-dependent replication of plasmids during bacteriophage T4 infection

The replication of plasmids containing fragments of the T4 genome, but no phage replication origins, was analyzed as a possible model for phage secondary (recombination-dependent) replication initiation. The replication of such plasmids after T4 infection was reduced or eliminated by mutations in several phage genes (uvsY, uvsX, 46, 59, 39, and 52) that have previously been shown to be involved in secondary initiation. A series of plasmids that collectively contain about 60 kilobase pairs of the T4 genome were tested for replication after T4 infection. With the exception of those known to contain tertiary origins, every plasmid replicated in a uvsY-dependent fashion. Thus, there is no apparent requirement for an extensive nucleotide sequence in the uvsY-dependent plasmid replication. However, homology with the phage genome is required since the plasmid vector alone did not replicate after phage infection. The products of plasmid replication included long concatemeric molecules with as many as 35 tandem copies of plasmid sequence. The production of concatemers indicates that plasmid replication is an active process and not simply the result of passive replication after the integration of plasmids into the phage genome. We conclude that plasmids with homology to the T4 genome utilize the secondary initiation mechanism of the phage. This simple model system should be useful in elucidating the molecular mechanism of recombination-dependent DNA synthesis in phage T4.     

Small Staphylococcus aureus plasmids are transduced as linear multimers that are formed and resolved by replicative processes

The molecular processes involved in the transduction of small staphylococcal plasmids by a generalized transducing phage, phi 11, have been analysed. The plasmids are transduced in the form of linear concatemers containing only plasmid DNA; plasmid-initiated replication is required for their generation but additive interplasmid recombination is not. Concatemers are probably generated by the interaction of one or more phage functions with replicating plasmid DNA. Insertion of any restriction fragment of the phage into the plasmid causes an approximately 10(5)-fold increase in transduction frequency, regardless of the size or genetic content of the fragment. The resulting transducing particles (Hft particles) contain mostly pure linear concatemers composed of tandem repeats of the plasmid::phage chimera, and their production requires active plasmid-initiated replication. The high frequency of transduction is a consequence of homologous recombination between the linear chimeric and phage concatemers, which has the effect of introducing an efficient pac site into the former. Following introduction into lysogenic recipient bacteria, the transducing DNA is first converted to the supercoiled form, then processed to monomers by a mechanism that requires the active participation of the plasmid replication system.     

Rolling-circle replication of mitochondrial DNA in the higher plant Chenopodium album (L.).

The mitochondrial genomes of higher plants are larger and more complex than those of all other groups of organisms. We have studied the in vivo replication of chromosomal and plasmid mitochondrial DNAs prepared from a suspension culture and whole plants of the dicotyledonous higher plant Chenopodium album (L.). Electron microscopic studies revealed sigma-shaped, linear, and open circular molecules (subgenomic circles) of variable size as well as a minicircular plasmid of 1.3 kb (mp1). The distribution of single-stranded mitochondrial DNA in the sigma structures and the detection of entirely single-stranded molecules indicate a rolling-circle type of replication of plasmid mp1 and subgenomic circles. About half of the sigma-like molecules had tails exceeding the lengths of the corresponding circle, suggesting the formation of concatemers. Two replication origins (nicking sites) could be identified on mpl by electron microscopy and by a new approach based on the mapping of restriction fragments representing the identical 5' ends of the tails of sigma-like molecules. These data provide, for the first time, evidence for a rolling-circle mode of replication in the mitochondria of higher plants.     

Atypical location of double-strand origin of replication (nic site) on the plasmid pGA1 from Corynebacterium glutamicum

The double-strand origin of replication (dso) of the rolling-circle-replicating (RC) plasmid pGA1 from Corynebacterium glutamicum was analyzed using the runoff DNA synthesis assay. The site- and strand-specific breakage of double-stranded plasmid DNA, representing the nic site of dso, was localized precisely within the sequence 5'-CTGG decreases AT-3' in the distal part of the pGA1 rep gene. This location of dso differs from the dso positions found on other RC plasmids and is in agreement with the classification of the plasmid pGA1 into a new group of RC plasmids.     

Structure and role of the terminal repeats of Epstein-Barr virus in processing and packaging of virion DNA.

The linear virion Epstein-Barr virus (EBV) DNA is terminated at both ends by a variable number of direct, tandemly arranged terminal repeats (TRs) which are approximately 500 bp in size The number of TRs at each terminus can vary. After infection of host cells, the EBV DNA circularizes via the TRs by an unknown mechanism, and replication of the viral DNA during the lytic phase of the EBV life cycle leads to large DNA concatemers which need to be cleaved into virion DNA units, eventually. This cleavage event occurs at an unknown locus within the TRs of EBV, which are the cis-acting elements essential for cleavage of the concatemers and encapsidation of the virion DNA. To investigate the mechanism of DNA processing during genome circularization and cleavage of concatemeric DNA, the genomic termini of EBV were cloned, sequenced, and analyzed by direct labeling of the virion DNA. Both termini ended with identical 11-bp elements; the right end has acquired an additional 9-bp stretch that seemed to originate from the leftmost unique sequences. The left terminus is blunt, whereas the right terminus appears to have a 3' single-base extension. In a transient packaging assay, a single terminal repeat was found to be sufficient for encapsidation of plasmid DNA, and mutagenesis of the TR element defined a region of 159 bp, including the 11-bp element, which is essential for packaging. These results indicate that the genomic termini of EBV are not generated by a simple cut of a hypothetical terminase. The mechanism for cleavage of concatemers seems to involve recombination events.     

The role of bacteriophage T7 exonuclease (gene 6) in genetic recombination and production of concatemers

Genetic analysis reported here shows that bacteriophage T7 exonuclease (gene 6) is necessary for intragenic and intergenic recombination in several areas of the T7 genetic map. This supports our previous conclusion (Lee & Miller, 1974) that the enzyme is necessary for T7 molecular recombination.Results of sucrose gradient analysis show that DNA concatemers are formed when both the T7 exonuclease (gene 6) and the T7 endonuclease (gene 3) are absent. Further results show that concatemers cannot be maintained in the absence of the exonuclease unless the endonuclease is also eliminated. Therefore, concatemers are formed by a process other than normal phage recombination. Selective defects in the recombination system do interfere with the stability of concatemers, however.     

Repair of Double-Strand Breaks in Bacteriophage T4 by a Mechanism That Involves Extensive DNA Replication

We investigated double-strand break (dsb) repair in bacteriophage T4 using a physical assay that involves a plasmid substrate with two inverted DNA segments. A dsb introduced into one repeat during a T4 infection induces efficient dsb repair using the second repeat as a template. This reaction is characterized by the following interesting features. First, the dsb induces a repair reaction that is directly coupled to extensive plasmid replication; the repaired/replicated product is in the form of long plasmid concatemers. Second, repair of the dsb site is frequently associated with exchange of flanking DNA. Third, the repair reaction is absolutely dependent on the products of genes uvsX, uvsY, 32, 46, and 59, which are also required for phage genomic recombination-dependent DNA replication. Fourth, the coupled repair/replication reaction is only partly dependent on endonuclease VII (gp49), suggesting that either another Holliday-junction-cleaving activity or an alternate resolution pathway is active during T4 infections. Because this repair reaction is directly coupled to extensive replication, it cannot be explained by the SZOSTAK et al. model. We present and discuss a model for the coupled repair/replication reaction, called the extensive chromosome replication model for dsb repair.     

Unique features of the mitochondrial rolling circle-plasmid mp1 from the higher plant Chenopodium album (L.).

We analyzed the structure and replication of the mitochondrial (mt) circular DNA plasmid mp1 (1309 bp) from the higher plant Chenopodium album(L.). Two dimensional gel electrophoresis (2DE) revealed the existence of oligomers of up to a decamer in addition to the prevailing monomeric form. The migration behavior of cut replication intermediates during 2DE was consistent with a rolling circle (RC) type of replication. We detected entirely single-stranded (ss) plasmid copies hybridizing only with one of the two DNA strands. This result indicates the occurence of an asymmetric RC replication mechanism. mp1 has, with respect to its replication, some unique features compared with bacterial RC plasmids. We identified and localized a strand-specific nicking site (origin of RC replication) on the plasmid by primer extension studies. Nicks in the plasmid were found to occur at any one of six nucleotides (TAAG/GG) around position 735 of the leading strand. This sequence shows no homology to origin motifs from known bacterial RC replicons. mp1 is the first described RC plasmid in a higher plant.     

Recombination associated with replication of malarial mitochondrial DNA.

Mitochondrial DNA of the malarial parasite Plasmodium falciparum comprises approximately 20 copies per cell of a 6 kb genome, arranged mainly as polydisperse linear concatemers. In synchronous blood cultures, initiation of mtDNA replication coincides with the start of the 4-5 doublings in nuclear DNA that mark the reproductive phase of the erythrocytic cycle. We show that mtDNA replication coincides with a recombination process reminiscent of the replication mechanism used by certain bacteriophages and plasmids. The few circular forms of mtDNA which are also present do not replicate by a theta mechanism, but are themselves the product of recombination, and we propose they undergo rolling circle activity to generate the linear concatemers.     

Equimolar generation of the four possible arrangements of adjacent L components in herpes simplex virus type 1 replicative intermediates.

Herpes simplex virus type 1 (HSV-1) replication generates high-molecular-weight intermediates containing branched DNA and concatemers carrying adjacent genomes with inverted L components. We have studied replicative intermediates generated by (i) wild-type HSV-1; (ii) 5dl1.2, an ICP27 null mutant which fails to synthesize normal amounts of DNA and late proteins; (iii) RBMu3, a mutant containing a deletion in the inverted repeats which fails to generate genomic isomers; and (iv) amplicon plasmids and vectors which contain no inverted sequences. Replication intermediates were analyzed by pulsed-field gel electrophoresis, after restriction enzyme digestion of infected-cell DNA, followed by blot hybridization. DNA fragments were statistically quantified after phosphorimaging. We observed that (i) the four possible configurations of L components of two adjacent genomes in the concatemers are present at equimolar amounts at any time during virus replication, (ii) ICP27 is not required for inversions or for branched DNA to occur, and (iii) replication intermediates of both RBMu3 mutant and amplicon plasmids or vectors do contain branched structures, although the concatemers they generate contain no inversions. These data indicate that inversions are generated by a mechanism intrinsically linked to virus DNA replication, most likely homologous recombination between inverted repeats. Branched structures are detected in all replicating molecules, including those that do not invert, suggesting that they are constitutively linked to virus DNA synthesis. Our results are consistent with the notion that the four HSV-1 genomic isomers are generated by alternative cleavage frames of replication concatemers containing equimolar amounts of L-component inversions.     

Interconversion of replication and recombination structures: implications for terminal repeats and concatemers

Replication and recombination structures can be interconverted by branch-migration. Using this simple concept a novel mechanism is proposed for generating concatemers through an initial single-strand DNA invasion into a duplex. Only DNAs with terminal repeats can form concatemers, and Herpes Simplex Virus DNA replication is considered in detail. The model is more parsimonious than other models such as Watson's for concatemer formation.     

高温链霉菌质粒pTSC2的测序分析和滚环复制方式的鉴定

从猪粪堆肥中分离到一株编号为X3-3的可以在50℃高温生长的链霉菌菌株,该菌株含有一个约7kb的环型质粒pTSC2。【目的】克隆、测序和分析pTSC2,以及鉴定质粒的复制方式。【方法】利用分段克隆和引物延伸获得pTSC2的全序列,利用多序列比对寻找复制元件rep、dso和sso,利用中性转移和Southern杂交检测复制中间体。【结果】克隆和测序获得了全长为7516bp的pTSC2序列,预测编码8种蛋白,其中4种蛋白与链霉菌滚环复制的质粒pIJ101中负责复制和接合转移的蛋白非常相似。pTSC2的复制元件rep、dso和sso也与pIJ101的相似。克隆、转化变铅青链霉菌ZX7以及高温链霉菌2C证明了rep和dso为复制所必需元件。Southern杂交检测到pTSC2复制过程中积累了大量的单链DNA。【结论】高温链霉菌质粒pTSC2以滚环方式进行复制。这是首次在高温链霉菌中克隆和测序质粒,以及鉴定其复制方式。     

Characterization of a cryptic plasmid from Bacillus sphaericus strain LP1-G

A cryptic plasmid from Bacillus sphaericus strain LP1-G, designated as pLG, was sequenced and characterized. It was an 11,066bp circular molecule, with G+C content of 37%. The plasmid pLG was predicted to encode 23 putative ORFs, and ORF 21 shared the highest identity with Rep of pGI1 and pBMB9741, members of rolling-circle replication (RCR) pC194-family. Sequence analysis revealed a pC194-type double strand origin (dso) and a single strand origin (sso) like sequence located upstream and downstream of ORF 21, respectively. Moreover, Mung bean nuclease analysis and Southern hybridization confirmed the existence of single stranded DNA (ssDNA) intermediates, indicating that pLG belongs to the RCR pC194-family. Accumulation of multiple ssDNA intermediates in native strain LP1-G and decline of ssDNA and supercoiled DNA in rifampicin-treated strain implied that a special mechanism might be employed by pLG. Furthermore, the copy number of pLG in its original host was determined and about 58 copies of the plasmid exist in each cell. Subcloning and transformation experiments proved that the minimal replicon of pLG was within a 1.6-kb fragment, which was composed of rep gene and dso. These data are a good basis for the understanding of replication mechanisms and genetics of this B. sphaericus plasmid.     

The level of the pUB110 replication initiator protein is autoregulated, which provides an additional control for plasmid copy number.

Plasmids control their copy number by limiting the amount of the initiator for DNA replication. The plasmid pUB110 initiator protein is termed RepU. Expression of the pUB110 repU gene is controlled by two antisense RNAs that interfere with repU mRNA translation. Genetic evidence suggests that Rep protein levels may be regulated by additional uncharacterized mechanisms. The repU gene product was radiolabeled and purified by monitoring the radioactive label. RepU overproduction was performed in cells containing the plasmid leading strand replication origin (dso), to allow for a putative inactivation of RepU. Polypeptides with apparent molecular masses of 42 (RepU*) and 39 (RepU) kDa were purified, both having the N-terminal sequence expected for the repU gene. The RepU/RepU* protein mixture bound specifically to dso. At low protein concentrations, about six RepU/RepU* protomers bound to the dso region. At higher concentrations, an extended nucleoprotein complex was formed. The promoter for the repU gene was localized downstream of the dso region. The results suggest that the extended RepU/RepU*-dso DNA complex interferes with repU promoter utilization. This provides an additional copy number control by limiting RepU concentration. Our results suggest that during replication the RepU protein might be converted into an inactive RepU-RepU* hetero-oligomer, further limiting the amount of RepU protein available for replication initiation.     

Plasmid models for bacteriophage T4 DNA replication: requirements for fork proteins.

Bacteriophage T4 DNA replication initiates from origins at early times of infection and from recombinational intermediates as the infection progresses. Plasmids containing cloned T4 origins replicate during T4 infection, providing a model system for studying origin-dependent replication. In addition, recombination-dependent replication can be analyzed by using cloned nonorigin fragments of T4 DNA, which direct plasmid replication that requires phage-encoded recombination proteins. We have tested in vivo requirements for both plasmid replication model systems by infecting plasmid-containing cells with mutant phage. Replication of origin and nonorigin plasmids strictly required components of the T4 DNA polymerase holoenzyme complex. Recombination-dependent plasmid replication also strictly required the T4 single-stranded DNA-binding protein (gene product 32 [gp32]), and replication of origin-containing plasmids was greatly reduced by 32 amber mutations. gp32 is therefore important in both modes of replication. An amber mutation in gene 41, which encodes the replicative helicase of T4, reduced but did not eliminate both recombination- and origin-dependent plasmid replication. Therefore, gp41 may normally be utilized for replication of both plasmids but is apparently not required for either. An amber mutation in gene 61, which encodes the T4 RNA primase, did not eliminate either recombination- or origin-dependent plasmid replication. However, plasmid replication was severely delayed by the 61 amber mutation, suggesting that the protein may normally play an important, though nonessential, role in replication. We deleted gene 61 from the T4 genome to test whether the observed replication was due to residual gp61 in the amber mutant infection. The replication phenotype of the deletion mutant was identical to that of the amber mutant. Therefore, gp61 is not required for in vivo T4 replication. Furthermore, the deletion mutant is viable, demonstrating that the gp61 primase is not an essential T4 protein.     

The HSV-1 Exonuclease, UL12, Stimulates Recombination by a Single Strand Annealing Mechanism

Production of concatemeric DNA is an essential step during HSV infection, as the packaging machinery must recognize longer-than-unit-length concatemers; however, the mechanism by which they are formed is poorly understood. Although it has been proposed that the viral genome circularizes and rolling circle replication leads to the formation of concatemers, several lines of evidence suggest that HSV DNA replication involves recombination-dependent replication reminiscent of bacteriophages λ and T4. Similar to λ, HSV-1 encodes a 5′-to-3′ exonuclease (UL12) and a single strand annealing protein [SSAP (ICP8)] that interact with each other and can perform strand exchange in vitro. By analogy with λ phage, HSV may utilize viral and/or cellular recombination proteins during DNA replication. At least four double strand break repair pathways are present in eukaryotic cells, and HSV-1 is known to manipulate several components of these pathways. Chromosomally integrated reporter assays were used to measure the repair of double strand breaks in HSV-infected cells. Single strand annealing (SSA) was increased in HSV-infected cells, while homologous recombination (HR), non-homologous end joining (NHEJ) and alternative non-homologous end joining (A-NHEJ) were decreased. The increase in SSA was abolished when cells were infected with a viral mutant lacking UL12. Moreover, expression of UL12 alone caused an increase in SSA, which was completely eliminated when a UL12 mutant lacking exonuclease activity was expressed. UL12-mediated stimulation of SSA was decreased in cells lacking the cellular SSAP, Rad52, and could be restored by coexpressing the viral SSAP, ICP8, indicating that an SSAP is also required. These results demonstrate that UL12 can specifically stimulate SSA and that either ICP8 or Rad52 can function as an SSAP. We suggest that SSA is the homology-mediated repair pathway utilized during HSV infection.     

Replication, Integration, and Packaging of Plasmid DNA following Cotransfection with Baculovirus Viral DNA

Infection-dependent replication assays have been used to identify numerous putative origins of baculovirus replication. However, plasmid DNA, when cotransfected into insect cells with Autographa californica multinucleocapsid nucleopolyhedrovirus (AcMNPV) DNA, replicates independently of any viral sequence in cis (11). Cotransfection of transfer plasmids and baculovirus DNA is a common procedure used in generating recombinant viruses and in measuring the level of gene expression in transient-expression assays. We have examined the fate of a series of vector plasmids in cotransfection experiments. The data reveal that these plasmids replicate following cotransfection and the replication of plasmid DNA is not due to acquisition of viral putative origin sequences. The conformation of plasmid DNA replicating in the cotransfected cells was analyzed and found to exist as high-molecular-weight concatemers. Ten to 25% of the replicated plasmid DNA was integrated into multiple locations on the viral genome and was present in progeny virions following serial passage. Sequence analysis of plasmid-viral DNA junction sites revealed no homologous or conserved sequences in the proximity of the integration sites, suggesting that nonhomologous recombination was involved during the integration process. These data suggest that while a rolling-circle mechanism could be used for baculovirus DNA replication, recombination may also be involved in this process. Plasmid integration may generate large deletions of the viral genome, suggesting that the process of DNA replication in baculovirus may be prone to generation of defective genomes.