腺相关病毒Rep78蛋白抑制乙型肝炎病毒复制的体外研究

目的 研究腺相关病毒(adeno-associated virus,AAV)Rep78蛋白对乙型肝炎病毒(HBV)复制的抑制作用及机制.方法 将土拨鼠肝炎病毒(WHV)全基因组DNA从质粒中酶切回收,线状DNA重新连接呈环状.用脂质体Fugene 6体外转染至HepG2细胞,同时共同转染含有Rep78的质粒AAVdl52-91.5 d后收获细胞DNA,Southern blot检测WHV DNA复制.以含有HBV全长的质粒为模板,PCR法分别扩增出HBV-S、C和X基因全长.以凝胶电泳阻滞实验(EMSA)检测Rep78与HBV-S、C和X的结合.结果 Southern blot结果表明,AAV-Rep78可以明显抑制WHV病毒在HepG2细胞中的复制,并呈剂量依赖关系.EMSA结果显示,Rep78蛋白在体外能够与HBV-S、C和X的DNA结合,其中与HBV-C的结合最强而且有剂量依赖关系.此外,这种Rep78蛋白与HBV-C DNA结合可以被特异性的Rep78抗体阻滞,形成超结合带.结论 AAV-Rep78可以抑制HBV DNA的复制,其机制可能在于Rep78蛋白结合并抑制了HBV-C基因.     

Strand-Specific Supercoiled DNA-Protein Relaxation Complexes: Comparison of the Complexes of Bacterial Plasmids ColE1 and ColE2

Certain bacterial plasmids can be isolated as unique complexes of supercoiled circular DNA and protein. These complexes are distinguished by the conversion of the supercoiled DNA to the relaxed or open-circular DNA form upon treatment with ionic detergents, proteases, or alkali. This report demonstrates that the open-circular DNA resulting from the pronase-induced relaxation of the complexes of colicinogenic factors E(1) (ColE(1)) and E(2) (ColE(2)) possesses a strand-specific break. In each case this break is found in the heavy strand of the DNA as defined by CsCl centrifugation in the presence of poly(U,G). In addition, the ColE(1) and ColE(2) complexes exhibit certain properties that are plasmid specific. Heat treatment, and to a lesser extent pronase treatment, inactivates the ColE(2) complex, making it insensitive to agents that formerly were capable of inducing relaxation (conversion of the DNA to the open-circular form). In contrast, the ColE(1) complex is not inactivated by these treatments. The potential role of these strand-specific relaxation complexes in DNA replication is discussed.     

Plant virus DNA replication processes in Agrobacterium: insight into the origins of geminiviruses?

Agrobacterium tumefaciens, a bacterial plant pathogen, when transformed with plasmid constructs containing greater than unit length DNA of tomato leaf curl geminivirus accumulates viral replicative form DNAs indistinguishable from those produced in infected plants. The accumulation of the viral DNA species depends on the presence of two origins of replication in the DNA constructs and is drastically reduced by introducing mutations into the viral replication-associated protein (Rep or C1) ORF, indicating that an active viral replication process is occurring in the bacterial cell. The accumulation of these viral DNA species is not affected by mutations or deletions in the other viral open reading frames. The observation that geminivirus DNA replication functions are supported by the bacterial cellular machinery provides evidence for the theory that these circular single-stranded DNA viruses have evolved from prokaryotic episomal replicons.     

Rolling-circle replication of the plasmid pKYM isolated from a gram-negative bacterium.

Plasmid pKYM isolated from a Gram-negative bacterium encodes a Rep protein that is essential for plasmid replication. A comparison of Rep protein from pKYM to Rep proteins encoded by other plasmids shows that it has homology to Rep proteins of the pUB110 plasmid family from Gram-positive bacteria. These plasmids replicate by a rolling-circle mechanism in which a tyrosine residue in the Rep protein acts as the acceptor for the 5' end of the single-strand break introduced by the Rep protein. A Tyr----Phe substitution in the pKYM Rep protein abolishes its activity. Strand-specific single-stranded circular plasmid DNA can be recovered from the cells carrying pKYM and thus we propose that the plasmid pKYM replicates by a rolling-circle mechanism.     

Biochemical construction of specific chimeric plasmids from ColE1 DNA and unfractionated Escherichia coli DNA.

A series of chimeric plasmids was constructed using colicinigenic factor E1 (ColE1) DNA as the replicon and DNA fragments carrying the galactose or tryptophan operons from E. coli. Restriction endonuclease EcoRI digests of ColE1 DNA and various DNAs containing the trp or gal operons were joined by T4 polynucleotide ligase [polynucleotide synthetase (ATP), poly(deoxyribonucleotide):poly(deoxyribonucleotide) ligase (AMP-forming), EC 6.5.1.1]. Chimeric plasmids carrying the desired genes were selected after transformation of Trp- or Gal- cells with ligated DNA. By using this method, we constructed ColE1-gal and ColE1-trp chimeric plasmids in which the source of the bacterial gal and trp operons was an unfractionated EcoRI digest of total E. coli DNA. The frequency of recovery of such chimeric plasmids is 10 to 20 colonies per mug of ligated DNA used in the transformation step. The method utilized in this report for constructing specific chimeric plasmids from total E. coli DNA is very simple. It requires only endonuclease R-EcoRI and T4 polynucleotide ligase, both of which are commercially available. The yield of transformants suggests that this method will be useful for cloning and amplifying a wide variety of functionally defined genes from E. coli and other prokaryotic organisms.     

Autonomous replication of plasmids bearing monkey DNA origin-enriched sequences.

Twelve clones of origin-enriched sequences (ORS) isolated from early replicating monkey (CV-1) DNA were examined for transient episomal replication in transfected CV-1, COS-7, and HeLa cells. Plasmid DNA was isolated at time intervals after transfection and screened by the Dpn I resistance assay or by the bromodeoxyuridine substitution assay to differentiate between input and replicated DNA. We have identified four monkey ORS (ORS3, -8, -9, and -12) that can support plasmid replication in mammalian cells. This replication is carried out in a controlled and semiconservative manner characteristic of mammalian replicons. ORS replication was most efficient in HeLa cells. Electron microscopy showed ORS8 and ORS12 plasmids of the correct size with replication bubbles. Using a unique restriction site in ORS12, we have mapped the replication bubble within the monkey DNA sequence.     

Replication of plasmids from Staphylococcus aureus in Escherichia coli.

Plasmid pBR322 derives from plasmid ColE1 and does not replicate in Escherichia coli strains lacking DNA polymerase I. Hybrids between pBR322 and a plasmid isolated from Staphylococcus aureus, pC194, replicate in such E. coli strains, provided that the pC194 replication region is intact. Inactivation of the pBR322 replication region does not interfere with the replication of hybrids in E. coli. Hybrids between pBR322 and two other plasmids from S. aureus, pT127 and pUB112, and replicate at the restrictive temperature in E. coli having thermosensitive DNA polymerase I. Similar hybrids involving pC221 and pHV400, plasmids from S. aureus and Bacillus subtilis, respectively, do not replicate under such conditions. These results show that some plasmids from a Gram-positive bacterium, S. aureus, can replicate in a Gram-negative one, E. coli.     

Cloning, isolation, and characterization of replication regions of complex plasmid genomes.

EcoRI endonuclease-generated DNA fragments carrying replication regions of the F'lac and R6-5 plasmids have been cloned and isolated, using as a selection vehicle a nonreplicating ampicillin-resistance DNA fragment derived from a Staphylococcus aureus plasmid. Heteroduplex analysis of the constructed plasmid chimeras and the parent replicons has localized the cloned R6-5 replication region to a DNA segment between kilobase pair coordinates 1.0 and 88.0 on the R6-5 map. Physical proximity between the plasmid replication functions and the locus governing plasmid incompatibility has been shown for both parent replicons. The cloning method reported appears to be generally applicable for the identification and isolation of replication regions of a variety of complex genomes.     

Replication of an origin-containing derivative of plasmid RK2 dependent on a plasmid function provided in trans

pRK212.2, a derivative of the broad host range plasmid RK2, contains two EcoRI cleavage fragments, A and B, neither of which can replicate by itself in Escherichia coli. Fragment A (41.7 kilobases), but not fragment B (14.4 kilobases), can be cloned by insertion into the unrelated plasmids mini-F and ColE1. Fragment B contains the origin of replication and the ampicillin-resistance determinant of RK2. Transformation of E. coli cells containing the mini-F-fragment A hybrid plasmid with fragment B DNA results in the recircularization and replication of fragment B as a nonmobilizable plasmid (pRK2067) with the copy number and incompatibility properties of RK2. Fragment B cannot be cloned in the absence of fragment A because the latter fragment suppresses a function, specified by fragment B, that results in loss of host cell viability. A small segment (2.4 kilobases) of fragment B that contains the RK2 origin of replication but no longer affects host cell growth in the absence of fragment A had been cloned previously by insertion into a ColE1 plasmid. This hybrid plasmid, designated pRK256, will replicate in E. coli polA mutants only when a fragment A-bearing helper plasmid is present. These results demonstrate that the potentially lethal function specified by fragment B of RK2 is not necessary for replication and that at least one trans-acting function is directly involved in RK2 replication.     

High-frequency transformation of yeast by plasmids containing the cloned yeast ARG4 gene

Hybrid ColE1 plasmids, containing cloned DNA from the yeast ARG4 region [e.g., pYe(arg4)1], transform yeast arg4 mutants to ARG4(+) with a frequency of 10(-4) (about 10(3) transformants per mug of plasmid DNA) and can replicate autonomously without integrating into the yeast genome. The yeast transformants are genetically unstable when grown on nonselective medium, but can be readily grown and maintained on minimal medium lacking arginine. The existence of unintegrated replicating plasmid DNA in the yeast transformants was demonstrated by Southern gel hybridization and by transformation of Escherichia coli argH mutants with DNA preparations from yeast transformants and subsequent recovery of intact plasmid DNA from the bacterial transformants. Plasmid DNAs recovered from the E. coli-yeast-E. coli "shuttle" remain essentially unchanged, as judged by DNA restriction fragment patterns. Some plasmid mutations leading to increased efficiency of expression of the ARG4 gene in E. coli do not appear to affect expression of the cloned ARG4 gene in yeast. Appropriate derivatives of these ARG4 plasmids are of potential usefulness as vectors for cloning genes in yeast and for studying the mechanism of yeast DNA replication.     

Construction of a novel plasmid-phage hybrid: use of the hybrid to demonstrate ColE1 DNA replication in vivo in the absence of a ColE1-specified protein.

A hybrid bacteriophage, P420, was constructed in vitro; it contains part of bacteriophage P4 and a 3.6-kilobase derivative of plasmid ColE1. In Escherichia coli, the plasmid-phage hybrid can exist as a stable plasmid or can be packaged into infective bacteriophage particles. Replication of P420, directed by the ColE1 replicon, was found to occur after P420 phage infection of E. coli cells that had been incubated in the presence of chloramphenicol. Replication began without a lag period and resulted in the synthesis of covalently closed circles of P420 DNA. Like ColE1 DNA replication but unlike that of P4, replication was dependent on DNA polymerase I and was sensitive to rifampicin. The presence of a resident ColE1 plasmid in the infected cells resulted in an inhibition of the replication of the incoming P420 DNA. These results indicate that ColE1 does not require a plasmid-coded protein to replicate its DNA in vivo and demonstrate the utility of P4 bacteriophage for coupling bacteriophage properties to a plasmid replicon.     

Identification of two Escherichia coli factor Y effector sites near the origins of replication of the plasmids (ColE1 and pBR322.

The Escherichia coli replication factor Y has been characterized as a phi X174 (+) strand specific DNA-dependent phosphohydrolase. In conjunction with other E. coli replication proteins, factor Y is involved in the formation of heterogeneous primers that are elongated by the E. coli DNA polymerase III elongation machinery. We report here that the heat-denatured DNAs of plasmids pBR322 and ColE1 serve as effectors for the hydrolysis of ATP by factor Y. The DNA sequences of pBR322 responsible for factor Y effector activity have been localized. Two separate regions of the pBR322 chromosome support Y ATPase activity. These sequences are near the replication origin and are located on opposite DNA strands.     

Plasmid ColE1 as a Molecular Vehicle for Cloning and Amplification of DNA

DNA fragments obtained from EcoRI endonuclease digestion of bacteriophage varphi80pt190 (trp(+)) and the plasmid ColE1 were covalently joined with polynucleotide ligase. Transformation of Escherichia coli trp(-) strains to tryptophan independence with the recombined DNA selected for reconstituted ColE1 plasmids containing the tryptophan operon and the varphi80 immunity region. Similarly, an EcoRI endonuclease generated fragment of plasmid pSC105 DNA containing the genetic determinant of kanamycin resistance was inserted into the ColE1 plasmid and recovered in E. coli. The plasmids containing the trp operon (ColE1-trp) and the kanamycin resistance gene were maintained under logarithmic growth conditions at a level of 25-30 copies per cell and accumulate to the extent of several hundred copies per cell in the presence of chloramphenicol. Cells carrying the ColE1-trp plasmid determined the production of highly elevated levels of trp operon-specific mRNA and tryptophan biosynthetic enzymes.     

Replication deficiencies in priA mutants of Escherichia coli lacking the primosomal replication n'' protein.

The priA gene of Escherichia coli encodes the protein that initiates assembly of the promosome, the entity essential for the replication of phage phi X174 and ColE1-like plasmids in vitro. We have prepared a null priA mutant to assess its role in vivo in replication of phages, plasmids, and the host chromosome. Extracts of this mutant are inert in the initial conversion of the phi X174 viral strand to the duplex form, confirming the absence of the PriA activity. In vivo, the priA mutant fails to produce phi X174 phage and, remarkably, is unable to maintain plasmids that depend on the E. coli chromosome origin as well as those of ColE1. Deficiencies in cell growth and cell division are also manifest.     

Mismatch repair in Escherichia coli enhances instability of (CTG)n triplet repeats from human hereditary diseases.

Long CTG triplet repeats which are associated with several human hereditary neuromuscular disease genes are stabilized in ColE1-derived plasmids in Escherichia coli containing mutations in the methyl-directed mismatch repair genes (mutS, mutL, or mutH). When plasmids containing (CTG)180 were grown for about 100 generations in mutS, mutL, or mutH strains, 60-85% of the plasmids contained a full-length repeat, whereas in the parent strain only about 20% of the plasmids contained the full-length repeat. The deletions occur only in the (CTG)180 insert, not in DNA flanking the repeat. While many products of the deletions are heterogeneous in length, preferential deletion products of about 140, 100, 60, and 20 repeats were observed. We propose that the E. coli mismatch repair proteins recognize three-base loops formed during replication and then generate long single-stranded gaps where stable hairpin structures may form which can be bypassed by DNA polymerase during the resynthesis of duplex DNA. Similar studies were conducted with plasmids containing CGG repeats; no stabilization of these triplets was found in the mismatch repair mutants. Since prokaryotic and human mismatch repair proteins are similar, and since several carcinoma cell lines which are defective in mismatch repair show instability of simple DNA microsatellites, these mechanistic investigations in a bacterial cell may provide insights into the molecular basis for some human genetic diseases.     

Expression of a DNA strand initiation sequence of ColE1 plasmid in a single-stranded DNA phage.

In order to investigate initiation of H-strand (lagging strand) replication of the plasmid ColE1, the origin region fragment (Hae II-E) of ColE1 was inserted into the intergenic region of filamentous DNA phage M13 and cloned. A site capable of promoting DNA strand initiation on a single-stranded DNA template has been detected on the L-strand (leading strand) of the cloned fragment. The site, named rri-1 rifampicin-resistant initiation), directs conversion of chimeric phage single-stranded DNA to parental replicative form in the presence of rifampicin, which blocks the function of the complementary strand origin of M13. The function of rri-1 is dependent on both the dnaG and dnaB gene products. It is postulated that rri-1 might be an initiation site for synthesis of the lagging DNA strand during unidirectional replication of ColE1 DNA.     

Escherichia coli mutants suppressing replication-defective mutations of the ColE1 plasmid.

Mutants of Escherichia coli K-12 have been isolated that suppress cer mutants, ColE1 mutants that are unable to replicate as the plasmid. These host suppressors were designated her, for host factor affecting ColE1 replication. Each her suppressor showed a characteristic pattern of suppression depending on the cer mutation used for selecting the mutant bacteria. One of the suppressors, named herA, that suppressed cer6, a single-base-pair alteration 160 base pairs upstream of the ColE1 replication origin, was genetically identified as an alteration of the rnh gene (RNase H). HerA was recessive to its wild-type allele. RNase H activity of herA cell extracts was defective. Conversely, rnh mutants that were isolated independently of ColE1 replication supported replication of cer6 DNA. Some rnh mutants manifested the HerA phenotype only above a certain transition temperature, and their RNase H activity was found to be temperature sensitive. Therefore, replication of cer6 DNA in vivo is sensitive to RNase H activity. Under the conditions that suppressed cer6, the wild-type colE1 replicon replicated normally. Then, ColE1 replication in vivo proceeds in the absence of RNase H activity, which has been shown to be required for in vitro replication of the DNA.     

Transfer of pheromone-inducible plasmids between Enterococcus faecalis in the Syrian hamster gastrointestinal tract.

Pheromone-responsive plasmids are common to Enterococcus faecalis, transfer at high frequency in vitro, and carry cytolysin and other gene products implicated in the pathogenesis of enterococcal infection. A Syrian hamster model of enterococcal intestinal overgrowth was used to test for transfer of three isogenic plasmids differing in conjugative and cytolytic phenotypes. Transconjugants were found in 8 (44%) of 18 and 6 (35%) of 17 hamsters given donor strains containing cytolytic (pAM714) and noncytolytic (pAM771) pheromone-responsive plasmids. Of the 14 hamsters from which transconjugants were isolated from stool, 9 (64%) had transconjugants 1 day after donor strain inoculation. The frequency of transfer (mean +/- SD) for pAM714 and pAM771 was 1.4 +/- 2.2 x 10(-1) and 2.9 +/- 4.2 x 10(-2) transconjugants/donor, respectively (P > .20). Transconjugants were not recovered from hamsters receiving a cytolytic, nonconjugative plasmid (pAM930; transfer frequency < 2 x 10(-5) transconjugants/donor). Pheromone-responsive plasmid transfer between E. faecalis strains occurs at high frequency in the gastrointestinal tract of hamsters and may be one means by which enterococcal resistance and virulence factors disseminate.