DNA replication initiation: mechanisms and regulation in bacteria

In all organisms, multi-subunit replicases are responsible for the accurate duplication of genetic material during cellular division. Initiator proteins control the onset of DNA replication and direct the assembly of replisomal components through a series of precisely timed protein-DNA and protein-protein interactions. Recent structural studies of the bacterial protein DnaA have helped to clarify the molecular mechanisms underlying initiator function, and suggest that key structural features of cellular initiators are universally conserved. Moreover, it appears that bacteria use a diverse range of regulatory strategies dedicated to tightly controlling replication initiation; in many cases, these mechanisms are intricately connected to the activities of DnaA at the origin of replication. This Review presents an overview of both the mechanism and regulation of bacterial DNA replication initiation, with emphasis on the features that are similar in eukaryotic and archaeal systems.     

Telomere Structure,Replication and Length Maintenance

Telomeres are the termini of linear eukaryotic chromosomes consisting of tandem repeats of DNA and proteins that bind to these repeat sequences. Telomeres ensure the complete replication of chromosome ends, impart protection to ends from nucleolytic degradation, end-to-end fusion, and guide the localization of chromosomes within the nucleus. In addition, a combination of genetic, biochemical, and molecular biological approaches have implicated key roles for telomeres in diverse cellular processes such as regulation of gene expression, cell division, cell senescence, and cancer. This review focuses on recent advances in our understanding of the organization of telomeres, telomere replication, proteins that bind telomeric DNA, and the establishment of telomere length equilibrium.     

Six amino acids determine the sequence-specific DNA binding and replication specificity of the initiator proteins of the pT181 family.

The replication of pT181 and related plasmids of Staphylococcus aureus proceeds by a rolling circle mechanisms. The initiator proteins encoded by the plasmids of the pT181 family have sequence-specific DNA binding and topoisomerase activities. These proteins nick one strand of the DNA at the origin of replication. The free 3'-hydroxyl end at the nick is then used as a primer for the replication of the leading strand of the DNA. Although these initiator proteins are highly homologous, they show specificity in DNA binding and replication for their cognate DNAs. In this study, we have generated hybrid initiator proteins and studied their various biochemical activities in vitro. Our results show that 6 amino acids are sufficient to determine the DNA binding and replication specificities of such initiator proteins.     

Identification of replication factor C from Saccharomyces cerevisiae: a component of the leading-strand DNA replication complex.

A number of proteins have been isolated from human cells on the basis of their ability to support DNA replication in vitro of the simian virus 40 (SV40) origin of DNA replication. One such protein, replication factor C (RFC), functions with the proliferating cell nuclear antigen (PCNA), replication protein A (RPA), and DNA polymerase delta to synthesize the leading strand at a replication fork. To determine whether these proteins perform similar roles during replication of DNA from origins in cellular chromosomes, we have begun to characterize functionally homologous proteins from the yeast Saccharomyces cerevisiae. RFC from S. cerevisiae was purified by its ability to stimulate yeast DNA polymerase delta on a primed single-stranded DNA template in the presence of yeast PCNA and RPA. Like its human-cell counterpart, RFC from S. cerevisiae (scRFC) has an associated DNA-activated ATPase activity as well as a primer-template, structure-specific DNA binding activity. By analogy with the phage T4 and SV40 DNA replication in vitro systems, the yeast RFC, PCNA, RPA, and DNA polymerase delta activities function together as a leading-strand DNA replication complex. Now that RFC from S. cerevisiae has been purified, all seven cellular factors previously shown to be required for SV40 DNA replication in vitro have been identified in S. cerevisiae.     

Mechanisms to control rereplication and implications for cancer

Recent advances in the replication field have highlighted how the replication initiator proteins are negatively regulated by inhibitor proteins and ubiquitin-mediated degradation in mammalian cells to prevent rereplication. When these regulatory pathways go awry, uncontrolled rereplication ensues and a G2/M checkpoint is evoked to prevent cellular death. Many components of the checkpoints activated by rereplicaton are important for cancer prevention by facilitating DNA damage repair processes. The pathways that prevent rereplication themselves have also recently been implicated in preventing tumorigenesis. Studies from patient tumors, genetically altered mice, and mammalian cell culture suggest that deregulation of replication licensing proteins results in an increase in aneuploidy, chromosomal fusions, and DNA breaks. These studies provide a framework to address how regulators of replication function to maintain genomic stability.     

Evidence for a direct association of hMRE11 with the human mismatch repair protein hMLH1

In both mitotic and meiotic processes, cellular surveillance of the integrity of genetic information transmission from parental cells to their subsequent generations is carried out by a network of proteins primarily involved in cell-cycle regulation, DNA replication, DNA repair, and chromosome segregation. Within this context, the mammalian MRE11 represents an essential multifunctional protein that promotes repair of DNA double-strand breaks and plays a role in the signaling of DNA damage response. Mutations in human hMRE11 gene could contribute to the rare "AT-like" disorder. However, at present time the functional roles of hMRE11 in these cellular processes are elusive. In the current study, we provide evidence that hMRE11 interacts physically with the mismatch repair protein hMLH1 through yeast two-hybrid analysis. In addition, we show that recombinant hMRE11 and hMLH1 proteins interact when these two proteins are coexpressed in bacterial cells, and both proteins can be co-immunoprecipitated from human cell extracts. Furthermore, hMRE11 and hMLH1 display similar expression patterns when examined with a human normal/tumor DNA array. Together, these data suggest that hMRE11 and hMLH1 might act in a co-operative fashion during DNA damage detection, signaling, and repair.     

E1 initiator DNA binding specificity is unmasked by selective inhibition of non-specific DNA binding

Initiator proteins are critical components of the DNA replication machinery and mark the site of initiation. This activity probably requires highly selective DNA binding; however, many initiators display modest specificity in vitro. We demonstrate that low specificity of the papillomavirus E1 initiator results from the presence of a non-specific DNA-binding activity, involved in melting, which masks the specificity intrinsic to the E1 DNA-binding domain. The viral factor E2 restores specificity through a physical interaction with E1 that suppresses non-specific binding. We propose that this arrangement, where one DNA-binding activity tethers the initiator to ori while another alters DNA structure, is a characteristic of other viral and cellular initiator proteins. This arrangement would provide an explanation for the low selectivity observed for DNA binding by initiator proteins.     

Roles of Escherichia coli heat shock proteins DnaK, DnaJ and GrpE in mini-F plasmid replication

Summary A subset of Escherichia coli heat shock proteins, DnaK, DnaJ and GrpE were shown to be required for replication of mini-F plasmid. Strains of E. coli K12 carrying a missense mutation or deletion in the dnaK, dnaJ, or grpE gene were virtually unable to be transformed by mini-F DNA at the temperature (30° C) that permits cell growth. When excess amounts of the replication initiator protein (repE gene product) of mini-F were provided by means of a multicopy plasmid carrying repE, these mutant bacteria became capable of supporting mini-F replication under the same conditions. However, the copy number of a high copy number mini-F plasmid was reduced in these mutant bacteria as compared with the wild type in the presence of excess RepE protein. Furthermore, mini-F plasmid mutants that produce altered initiator protein and exhibit a very high copy number were able to replicate in strains deficient in any of the above heat shock proteins. These results indicate that the subset of heat shock proteins (DnaK, DnaJ and GrpE) play essential roles that help the functioning of the RepE initiator protein in mini-F DNA replication.     

AAA+ ATPases in the initiation of DNA replication

All cellular organisms and many viruses rely on large, multi-subunit molecular machines, termed replisomes, to ensure that genetic material is accurately duplicated for transmission from one generation to the next. Replisome assembly is facilitated by dedicated initiator proteins, which serve to both recognize replication origins and recruit requisite replisomal components to the DNA in a cell-cycle coordinated manner. Exactly how imitators accomplish this task, and the extent to which initiator mechanisms are conserved among different organisms have remained outstanding issues. Recent structural and biochemical findings have revealed that all cellular initiators, as well as the initiators of certain classes of double-stranded DNA viruses, possess a common adenine nucleotide-binding fold belonging to the ATPases Associated with various cellular Activities (AAA+) family. This review focuses on how the AAA+ domain has been recruited and adapted to control the initiation of DNA replication, and how the use of this ATPase module underlies a common set of initiator assembly states and functions. How biochemical and structural properties correlate with initiator activity, and how species-specific modifications give rise to unique initiator functions, are also discussed.     

Depletion of cellular pre-replication complex factors results in increased human cytomegalovirus DNA replication

Although HCMV encodes many genes required for the replication of its DNA genome, no HCMV-encoded orthologue of the origin binding protein, which has been identified in other herpesviruses, has been identified. This has led to speculation that HCMV may use other viral proteins or possibly cellular factors for the initiation of DNA synthesis. It is also unclear whether cellular replication factors are required for efficient replication of viral DNA during or after viral replication origin recognition. Consequently, we have asked whether cellular pre-replication (pre-RC) factors that are either initially associated with cellular origin of replication (e.g. ORC2), those which recruit other replication factors (e.g. Cdt1 or Cdc6) or those which are subsequently recruited (e.g. MCMs) play any role in the HCMV DNA replication. We show that whilst RNAi-mediated knock-down of these factors in the cell affects cellular DNA replication, as predicted, it results in concomitant increases in viral DNA replication. These data show that cellular factors which initiate cellular DNA synthesis are not required for the initiation of replication of viral DNA and suggest that inhibition of cellular DNA synthesis, in itself, fosters conditions which are conducive to viral DNA replication.     

Replication and recombination of herpes simplex virus DNA

Replication of herpes simplex virus takes place in the cell nucleus and is carried out by a replisome composed of six viral proteins: the UL30-UL42 DNA polymerase, the UL5-UL8-UL52 helicase-primase, and the UL29 single-stranded DNA-binding protein ICP8. The replisome is loaded on origins of replication by the UL9 initiator origin-binding protein. Virus replication is intimately coupled to recombination and repair, often performed by cellular proteins. Here, we review new significant developments: the three-dimensional structures for the DNA polymerase, the polymerase accessory factor, and the single-stranded DNA-binding protein; the reconstitution of a functional replisome in vitro; the elucidation of the mechanism for activation of origins of DNA replication; the identification of cellular proteins actively involved in or responding to viral DNA replication; and the elucidation of requirements for formation of replication foci in the nucleus and effects on protein localization.     

AAA+ ATPases in the Initiation of DNA Replication

All cellular organisms and many viruses rely on large, multi-subunit molecular machines, termed replisomes, to ensure that genetic material is accurately duplicated for transmission from one generation to the next. Replisome assembly is facilitated by dedicated initiator proteins, which serve to both recognize replication origins and recruit requisite replisomal components to the DNA in a cell-cycle coordinated manner. Exactly how imitators accomplish this task, and the extent to which initiator mechanisms are conserved among different organisms have remained outstanding issues. Recent structural and biochemical findings have revealed that all cellular initiators, as well as the initiators of certain classes of double-stranded DNA viruses, possess a common adenine nucleotide-binding fold belonging to the ATPases Associated with various cellular Activities (AAA+) family. This review focuses on how the AAA+ domain has been recruited and adapted to control the initiation of DNA replication, and how the use of this ATPase module underlies a common set of initiator assembly states and functions. How biochemical and structural properties correlate with initiator activity, and how species-specific modifications give rise to unique initiator functions, are also discussed.     

Heat shock proteins DnaJ, DnaK, and GrpE stimulate P1 plasmid replication by promoting initiator binding to the origin.

Binding of the P1-encoded protein RepA to the origin of P1 plasmid replication is essential for initiation of DNA replication and for autoregulatory repression of the repA promoter. Previous studies have shown defects in both initiation and repression in hosts lacking heat shock proteins DnaJ, DnaK, and GrpE and have suggested that these proteins play a role in the RepA-DNA binding required for initiation and repression. In this study, using in vivo dimethyl sulfate footprinting, we have confirmed the roles of the three heat shock proteins in promoting RepA binding to the origin. The defects in both activities could be suppressed by increasing the concentration of wild-type RepA over the physiological level. We also isolated RepA mutants that were effective initiators and repressors without requiring the heat shock proteins. These data suggest that the heat shock proteins facilitate both repression and initiation by promoting only the DNA-binding activity of RepA. In a similar plasmid, F, initiator mutants that confer heat shock protein independence for replication were also found, but they were defective for repression. We propose that the initiator binding involved in repression and the initiator binding involved in initiation are similar in P1 but different in F.     

Activation of SV40 DNA replication in vitro by cellular protein phosphatase 2A.

We have made use of the cell-free SV40 DNA replication system to identify and characterize cellular proteins required for efficient DNA synthesis. One such protein, replication protein C (RP-C), was shown to be involved with SV40 large T antigen in the early stages of viral DNA replication in vitro. We demonstrate here that RP-C is identical to the catalytic subunit of cellular protein phosphatase 2A (PP2Ac). The purified protein dephosphorylates specific phosphoamino acid residues in T antigen, consistent with the hypothesis that SV40 DNA replication is regulated by modulating the phosphorylation state of the viral initiator protein. We also show that purified RP-C/PP2Ac preferentially stimulates SV40 DNA replication in extracts from early G1 phase cells. This finding suggests that the activity of a cellular factor that influences the net phosphorylation state of T antigen is cell cycle dependent.     

Methanosarcina acetivorans flap endonuclease 1 activity is inhibited by a cognate single-stranded-DNA-binding protein

The oligonucleotide/oligosaccharide-binding (OB) fold is central to the architecture of single-stranded- DNA-binding proteins, which are polypeptides essential for diverse cellular processes, including DNA replication, repair, and recombination. In archaea, single-stranded DNA-binding proteins composed of multiple OB folds and a zinc finger domain, in a single polypeptide, have been described. The OB folds of these proteins were more similar to their eukaryotic counterparts than to their bacterial ones. Thus, the archaeal protein is called replication protein A (RPA), as in eukaryotes. Unlike most organisms, Methanosarcina acetivorans harbors multiple functional RPA proteins, and it was our interest to determine whether the different proteins play different roles in DNA transactions. Of particular interest was lagging-strand DNA synthesis, where recently RPA has been shown to regulate the size of the 5' region cleaved during Okazaki fragment processing. We report here that M. acetivorans RPA1 (MacRPA1), a protein composed of four OB folds in a single polypeptide, inhibits cleavage of a long flap (20 nucleotides) by M. acetivorans flap endonuclease 1 (MacFEN1). To gain a further insight into the requirement of the different regions of MacRPA1 on its inhibition of MacFEN1 endonuclease activity, N-terminal and C-terminal truncated derivatives of the protein were made and were biochemically and biophysically analyzed. Our results suggested that MacRPA1 derivatives with at least three OB folds maintained the properties required for inhibition of MacFEN1 endonuclease activity. Despite these interesting observations, further biochemical and genetic analyses are required to gain a deeper understanding of the physiological implications of our findings.     

Role of individual monomers of a dimeric initiator protein in the initiation and termination of plasmid rolling circle replication

Plasmids of the pT181 family encode initiator proteins that act as dimers during plasmid rolling circle (RC) replication. These initiator proteins bind to the origin of replication through a sequence-specific interaction and generate a nick at the origin that acts as the primer for RC replication. Previous studies have demonstrated that the initiator proteins contain separate DNA binding and nicking-closing domains, both of which are required for plasmid replication. The tyrosine residue at position 191 of the initiator RepC protein of pT181 is known to be involved in nicking at the origin. We have generated heterodimers of RepC that consist of different combinations of wild type, DNA binding, and nicking mutant monomers to identify the role of each of the two monomers in RC replication. One monomer with DNA binding activity was sufficient for the targeting of the initiator to the origin, and the presence of Tyr-191 in one monomer was sufficient for the initiation of replication. On the other hand, a dimer consisting of one monomer defective in DNA binding and the other defective in origin nicking failed to initiate replication. Our results demonstrate that the monomer that promotes sequence-specific binding to the origin must also nick the DNA to initiate replication. Interestingly, whereas Tyr-191 of the initiator was required for nicking at the origin to initiate replication, it was dispensable for termination, suggesting that alternate amino acids in the initiator may promote termination but not initiation.     

泛素化介导的非蛋白质降解功能

泛素因标记被26 S蛋白酶体降解的蛋白质而著名．然而近几年发现,泛素作用远不止此,不仅具有参与蛋白质降解这一重要“传统作用”,还起着比先前想象更多变的、更精美的细胞调控作用,是非常重要的细胞过程的多层面调节因子,具有许多重要的非蛋白质降解功能,包括DNA损伤修复、DNA复制、信号传导、转录调节、膜运输、胞吞、蛋白激酶活化、染色质重塑和病毒芽殖．这些功能涉及多聚泛素化和单泛素化及多泛素化．因此,泛素化异常可能涉及疾病的发生和发展．对这些功能的了解可以拓展人们对泛素的认识,有助于对多种细胞过程的深入理解,也有助于相关新药的研发．