Structure and function of Cdc6/Cdc18: implications for origin recognition and checkpoint control

Cdc6/Cdc18 is a conserved and essential component of prereplication complexes. The 2.0 A crystal structure of an archaeal Cdc6 ortholog, in conjunction with a mutational analysis of the homologous Cdc18 protein from Schizosaccharomyces pombe, reveals novel aspects of Cdc6/Cdc18 function. Two domains of Cdc6 form an AAA+-type nucleotide binding fold that is observed bound to Mg.ADP. A third domain adopts a winged-helix fold similar to known DNA binding modules. Sequence comparisons show that the winged-helix domain is conserved in Orc1, and mutagenesis data demonstrate that this region of Cdc6/Cdc18 is required for function in vivo. Additional mutational analyses suggest that nucleotide binding and/or hydrolysis by Cdc6/Cdc18 is required not only for progression through S phase, but also for maintenance of checkpoint control during S phase.

Mechanism of Rep-mediated adeno-associated virus origin nicking

The single-stranded adeno-associated virus type 2 (AAV) genome is flanked by terminal repeats (TRs) that fold back on themselves to form hairpinned structures. During AAV DNA replication, the TRs are nicked by the virus-encoded Rep proteins at the terminal resolution site (trs). This origin function apparently requires three sequence elements, the Rep binding element (RBE), a small palindrome that comprises a single tip of an internal hairpin within the TR (RBE'), and the trs. Previously, we determined the sequences at the trs required for Rep-mediated cleavage and demonstrated that the trs endonuclease reaction occurs in two discrete steps. In the first step, the Rep DNA helicase activity unwinds the TR, thereby extruding a stem-loop structure at the trs. In the second step, Rep transesterification activity cleaves the trs. Here we investigate the contribution of the RBE and RBE' during this process. Our data indicate that Rep is tethered to the RBE in a specific orientation during trs nicking. This orientation appears to align Rep on the AAV TR, allowing specific nucleotide contacts with the RBE' and directing nicking to the trs. Accordingly, alterations in the polarity or position of the RBE relative to the trs greatly inhibit Rep nicking. Substitutions within the RBE' also reduce Rep specific activity, but to a lesser extent. Interestingly, Rep interactions with the RBE and RBE' during nicking seem to be functionally distinct. Rep contacts with the RBE appear necessary for both the DNA helicase and trs cleavage steps of the endonuclease reaction. On the other hand, RBE' contacts seem to be required primarily for TR unwinding and formation of the trs stem-loop structure, not cleavage. Together, these results suggest a model of Rep interaction with the AAV TR during origin nicking through a tripartite cleavage signal comprised of the RBE, the RBE', and the trs.

Reconstitution of an ATM-dependent checkpoint that inhibits chromosomal DNA replication following DNA damage

Cell cycle checkpoints lead to the inhibition of cell cycle progression following DNA damage. A cell-free system derived from Xenopus eggs has been established that reconstitutes the checkpoint pathway inhibiting DNA replication initiation. DNA containing double-strand breaks inhibits replication initiation in a dose-dependent manner. Upon checkpoint activation, a prereplicative complex is assembled that contains ORC, Cdc6, Cdc7, and MCM proteins but lacks Cdc45. The checkpoint is ATM dependent. Cdk2/CyclinE acts downstream of ATM and is downregulated by Cdk2 phosphorylation on tyrosine 15. Cdk2AF/CyclinE is refractory to checkpoint signaling, and Cdc25A overrides the checkpoint and restores DNA replication. This report provides the description of a DNA damage checkpoint pathway that prevents the onset of S phase independently of the transcriptional function of p53 in a vertebrate organism.

Initiation of eukaryotic DNA replication: conservative or liberal?

The mechanism for initiation of eukaryotic DNA replication is highly conserved: the proteins required to initiate replication, the sequence of events leading to initiation, and the regulation of initiation are remarkably similar throughout the eukaryotic kingdom. Nevertheless, there is a liberal attitude when it comes to selecting initiation sites. Differences appear to exist in the composition of replication origins and in the way proteins recognize these origins. In fact, some multicellular eukaryotes (the metazoans) can change the number and locations of initiation sites during animal development, revealing that selection of initiation sites depends on epigenetic as well as genetic parameters. Here we have attempted to summarize our understanding of this process, to identify the similarities and differences between single cell and multicellular eukaryotes, and to examine the extent to which origin recognition proteins and replication origins have been conserved among eukaryotes. Published 2000 Wiley-Liss, Inc.

Characterization of the DNA replication module of bacteriophage A2 and use of its origin of replication as a defense against infection during milk fermentation by Lactobacillus casei

Adjacent to the lysis/lysogeny cassette of the A2 phage genome lies a stretch of over 8 kb, which contains a series of genes probably involved in DNA replication. Fifteen open reading frames (orfs) were identified, 13 of which are encoded on the main coding strand and only two on the complementary strand. Database searches and comparative analyses allowed the identification of an open reading frame (orf455) that shows similarity with DNA helicases and contains a variant zinc-finger motif known from the phage T7 helicase/primase. Orf770 showed similarity to putative plasmid and phage DNA primases. Downstream of orf770 is a noncoding 258-bp region rich in direct and inverted repeats, which specifically binds to proteins whose synthesis is induced during phage infection. When present in a plasmid, this region can direct a partial bacteriophage resistance phenotype due to interference with phage DNA replication, both under laboratory conditions and during milk fermentation. It is deduced that this stretch contains the origin of replication of phage A2.

Central role for cdc45 in establishing an initiation complex of DNA replication in Xenopus egg extracts

BACKGROUND

In eukaryotes, chromosomal DNA is licensed to be replicated through the sequential loading of the origin recognition complex, Cdc6 and mini-chromosome maintenance protein complex (MCM) onto chromatin. However, how the replication machinery is assembled onto the licensed chromatin during initiation of replication is poorly understood.

RESULTS

Using Xenopus egg extracts, we have investigated the role of Cdc45 in the loading of various replication proteins onto chromatin at the onset of S phase, and found that Cdc45, which required MCM for its loading, was essential for the sequential loading of replication protein A (RPA), DNA polymerase alpha and proliferating cell nuclear antigen (PCNA) onto chromatin. The assembly of DNA polymerase epsilon onto chromatin required Cdc45 but did not require DNA polymerase alpha. Analysis of nuclease-digested chromatin fractions shows that Cdc45 formed a stable complex with either MCM or DNA polymerase alpha on chromatin.

CONCLUSIONS

These results demonstrate a central role for Cdc45 in activation of the licensed chromatin to form replication complexes at the onset of S phase, and suggest that Cdc45 has a dual role in the initiation of DNA replication: the unwinding of DNA and the recruiting of DNA polymerases onto DNA.

Identification and chromosomal localization of murine ORC3, a new member of the mouse origin recognition complex

A new member of the murine origin recognition complex (ORC) related to Saccharomyces cerevisiae ORC3 has been cloned. Transcription of ORC3 is not suppressed in mouse NIH3T3 fibroblasts made quiescent by serum starvation. The transcription level of the ORC3 gene is constantly high in all phases of the cell cycle. Murine ORC3 protein contains a putative nuclear localization signal and a non-basic helix-loop-helix motif. Both motifs are conserved in eukaryotes. A potential dimerization partner of ORC3p in the murine ORC complex is ORC1p which also contains an HLH motif. This HLH motif is also highly conserved in all eukaryotic ORC1 proteins. Comparison of murine ORC3p with other ORC3-related proteins shows high amino acid homology and motif conservation leading to the conclusion that ORC3p is part of the initiation machinery conserved in eukaryotes. The mouse ORC3 gene Orc3 was assigned to mouse chromosome 4A3 by fluorescence in situ hybridization (FISH) analysis.

XCDT1 is required for the assembly of pre-replicative complexes in Xenopus laevis

In eukaryotic cells, chromosomal DNA replication begins with the formation of pre-replication complexes at replication origins. Formation and maintenance of pre-replication complexes is dependent upon CDC6 (ref. 1), a protein which allows assembly of MCM2-7 proteins, which are putative replicative helicases. The functional assembly of MCM proteins into chromatin corresponds to replication licensing. Removal of these proteins from chromatin in S phase is crucial in origins firing regulation. We have identified a protein that is required for the assembly of pre-replication complexes, in a screen for maternally expressed genes in Xenopus. This factor (XCDT1) is a relative of fission yeast cdt1, a protein proposed to function in DNA replication, and is the first to be identified in vertebrates. Here we show, using Xenopus in vitro systems, that XCDT1 is required for chromosomal DNA replication. XCDT1 associates with pre-replicative chromatin in a manner dependent on ORC protein and is removed from chromatin at the time of initiation of DNA synthesis. Immunodepletion and reconstitution experiments show that XCDT1 is required to load MCM2-7 proteins onto pre-replicative chromatin. These findings indicate that XCDT1 is an essential component of the system that regulates origins firing during S phase.

Selective activation of pre-replication complexes in vitro at specific sites in mammalian nuclei

As the first step in determining whether or not pre-replication complexes are assembled at specific sites along mammalian chromosomes, nuclei from G(1)-phase hamster cells were incubated briefly in Xenopus egg extract in order to initiate DNA replication. Most of the nascent DNA consisted of RNA-primed DNA chains 0.5 to 2 kb in length, and its origins in the DHFR gene region were mapped using both the early labeled fragment assay and the nascent strand abundance assay. The results revealed three important features of mammalian replication origins. First, Xenopus egg extract can selectively activate the same origins of bi-directional replication (e.g. ori-beta) and (beta') that are used by hamster cells in vivo. Previous reports of a broad peak of nascent DNA centered at ori-(beta/(beta)' appeared to result from the use of aphidicolin to synchronize nuclei and from prolonged exposure of nuclei to egg extracts. Second, these sites were not present until late G(1)-phase of the cell division cycle, and their appearance did not depend on the presence of Xenopus Orc proteins. Therefore, hamster pre-replication complexes appear to be assembled at specific chromosomal sites during G(1)-phase. Third, selective activation of ori-(beta) in late G(1)-nuclei depended on the ratio of Xenopus egg extract to nuclei, revealing that epigenetic parameters such as the ratio of initiation factors to DNA substrate could determine the number of origins activated.

Sequence requirements for plasmid nuclear import

The nuclear envelope is a major barrier for nuclear uptake of plasmids and represents one of the most significant unsolved problems of nonviral gene delivery. We have previously shown that the nuclear entry of plasmid DNA is sequence-specific, requiring a 366-bp fragment containing the SV40 origin of replication and early promoter. In this report, we show that, although fragments throughout this region can support varying degrees of nuclear import, the 72-bp repeats of the SV40 enhancer facilitate maximal transport. The functions of the promoter and the origin of replication are not needed for nuclear localization of plasmid DNA. In contrast to the import activity of the SV40 enhancer, two other strong promoter and enhancer sequences, the human cytomegalovirus (CMV) immediate-early promoter and the Rous sarcoma virus LTR, were unable to direct nuclear localization of plasmids. The inability of the CMV promoter to mediate plasmid nuclear import was confirmed by measurement of the CMV promoter-driven expression of green fluorescent protein (GFP) in microinjected cells. At times before cell division, as few as 3 to 10 copies per cell of cytoplasmically injected plasmids containing the SV40 enhancer gave significant GFP expression, while no expression was obtained with more than 1000 copies per cell of plasmids lacking the SV40 sequence. However, the levels of expression were the same for both plasmids after cell division in cytoplasmically injected cells and at all times in nuclear injected cells. Thus, the inclusion this SV40 sequence in nonviral vectors may greatly increase their ability to be transported into the nucleus, especially in nondividing cells.

The dnaA gene region of Mycobacterium avium and the autonomous replication activities of its 5' and 3' flanking regions

A 3.9 kb DNA fragment containing the dnaA gene region of Mycobacterium avium was cloned and its nucleotide sequence was determined. Nucleotide sequence analyses indicated that this region encodes three genes in the order rpmH (ribosomal protein L34), dnaA (the putative initiator protein) and dnaN (the beta subunit of DNA polymerase III). The intergenic regions between the rpmH-dnaA and dnaA-dnaN genes were found to contain several putative DnaA boxes, 9 nt long DnaA protein recognition sequences. A DNA fragment containing the 3' but not the 5' flanking region of the M. avium dnaA gene when cloned in Escherichia coli plasmids, which are otherwise non-replicative in mycobacteria, exhibited autonomous replication activity in M. avium but not in Mycobacterium bovis BCG and Mycobacterium smegmatis. The 5' flanking region of dnaA, on the other hand, exhibited autonomous replication activity in M. bovis BCG but not in M. avium and M. smegmatis. The implications of these results for the understanding of the M. avium oriC replication initiation process are discussed.

Interactions of Epstein-Barr virus origins of replication with nuclear matrix in the latent and in the lytic phases of viral infection

Eukaryotic DNA is organized into domains or loops generated by the attachment of chromatin fibers to the nuclear matrix via specific regions called scaffold or matrix attachment regions. The role of these regions in DNA replication is currently under investigation since they have been found in close association with origins of replication. Also, viral DNA sequences, containing the origins of replication, have been found attached to the nuclear matrix. To investigate the functional role of this binding we have studied, in Raji cells, the interaction between Epstein-Barr virus (EBV) origins of replication and the nuclear matrix in relation to the viral cycle of infection. We report here that both the latent (ori P) and the lytic (ori Lyt) EBV origins of replication are attached to the nuclear matrix, the first during the latent cycle of infection and the second after induction of the lytic cycle. These findings suggest that the binding of the origins of replication with the nuclear matrix modulates viral replication and expression in the two different phases of infection.

Activation of dormant origins of DNA replication in budding yeast

Eukaryotic genomes often contain more potential replication origins than are actually used during S phase. The molecular mechanisms that prevent some origins from firing are unknown. Here we show that dormant replication origins on the left arm of budding yeast chromosome III become activated when both passive replication through them is prevented and the Mec1/Rad53 checkpoint that blocks late-origin firing is inactivated. Under these conditions, dormant origins fire very late relative to other active origins. These experiments show that some dormant replication origins are competent to fire during S phase and that passage of a replication fork through such origins can inactivate them.

Escherichia coli SeqA protein affects DNA topology and inhibits open complex formation at oriC

Chromosome replication in Escherichia coli is initiated by the DnaA protein. Binding of DnaA to the origin, oriC, followed by formation of an open complex are the first steps in the initiation process. Based on in vivo studies the SeqA protein has been suggested to function negatively in the initiation of replication, possibly by inhibiting open complex formation. In vitro studies have shown that SeqA inhibits oriC-dependent replication. Here we show by KMnO(4) probing that SeqA inhibits open complex formation. The inhibition was not caused by prevention of DnaA binding to the oriC plasmids, indicating that SeqA prevented strand separation in oriC either directly, by interacting with the AT-rich region, or indirectly, by changing the topology of the oriC plasmids. SeqA was found to restrain the negative supercoils of the oriC plasmid. In comparison with the effect of HU on plasmid topology, SeqA seemed to act more cooperatively. It is likely that the inhibition of open complex formation is caused by the effect of SeqA on the topology of the plasmids. SeqA also restrained the negative supercoils of unmethylated oriC plasmids, which do not bind SeqA specifically, suggesting that the effect on topology is not dependent on binding of SeqA to a specific sequence in oriC.

Identification and functional analysis of a putative non-hr origin of DNA replication from the Spodoptera littoralis type B multinucleocapsid nucleopolyhedrovirus

A putative non-hr origin of DNA replication was identified in the Spodoptera littoralis multinucleocapsid nucleopolyhedrovirus (SpliNPV) genome by transient replication assays. The putative SpliNPV ori was mapped to the PstI-J fragment between 75.1-77.9 map units in the SpliNPV genome. While the DNA sequence of the putative SpliNPV ori aligned with regions within the non-hr oris of Autographa californica, Orgyia pseudotsugata and Spodoptera exigua multinucleocapsid nucleopolyhedroviruses, it has limited DNA sequence identity with these elements. The sequence of the putative SpliNPV non-hr ori fragment contains a unique distribution of imperfect palindromes, multiple direct repeats and putative transcription factor-binding sites. Transient expression assays indicated that the putative SpliNPV ori fragment repressed SpliNPV lef-3 promoter-mediated luciferase reporter gene expression. However, the putative SpliNPV ori fragment itself was capable of directing luciferase expression in the absence of a recognizable baculovirus promoter element in an orientation-independent fashion, suggesting that DNA sequence motifs within its sequence can activate transcription. Gel mobility shift analyses confirmed that proteins within nuclear extracts from both uninfected and virus-infected cells bound with specificity to the putative SpliNPV ori fragment.

Initiation of DNA replication in eukaryotes: questioning the origin

Although proteins involved in DNA replication in yeast have counterparts in multicellular organisms, the definition of an origin of DNA replication and its control in higher eukaryotes might obey to different rules. Origins of DNA replication that are site-specific have been found, supporting the notion that specific DNA regions are used to initiate DNA synthesis along metazoan chromosomes. However, the notion that specific sequences will define origins is still being debated. The variety and complexity of transcriptional programs that have to be regulated in multicellular organisms may impose a plasticity that would not be compatible with a fixed origin simply defined at the sequence level. Such a plasticity would be essential to developmental programs where the control of DNA replication could be more integrated to the control of gene expression than in unicellular eukaryotes.

Universal replication biases in bacteria

Analysis of 15 complete bacterial chromosomes revealed important biases in gene organization. Strong compositional asymmetries between the genes lying on the leading versus lagging strands were observed at the level of nucleotides, codons and, surprisingly, amino acids. For some species, the bias is so high that the sole knowledge of a protein sequence allows one to predict with almost no errors whether the gene is transcribed from one strand or the other. Furthermore, we show that these biases are not species specific but appear to be universal. These findings may have important consequences in our understanding of fundamental biological processes in bacteria, such as replication fidelity, codon usage in genes and even amino acid usage in proteins.

DnaA proteins of Escherichia coli and Bacillus subtilis: coordinate actions with single-stranded DNA-binding protein and interspecies inhibition during open complex formation at the replication origins

DnaA-mediated unwinding of the AT-rich region in the replication origins of Escherichia coli and Bacillus subtilis was analysed in vitro with and without single-stranded DNA-binding protein (SSB). In the presence of SSB, the unwound region was larger by a defined number of base pairs. Although the overall structure of the origins is very different, the size and structure of the unwound region were similar. The unwinding reaction at oriC of one organism was inhibited by DnaA protein of the other bacterium. Similarly, hybrid DnaA proteins with swapped DNA-binding domains were inactive and inhibitory to 'open complex' formation at both origins. We suggest that the inhibition is due to inactive mixed complexes.

The replication inhibition activity of the WT1 tumor suppressor protein resides in its N-terminal 298 amino acid region, and does not require specific binding of the protein to the replication origin sequence

Using the simian virus 40 replication origin as the model, it was reported previously that the Wilms' tumor suppressor protein WT1 can inhibit DNA replication. In the present study, we found that a hybrid protein (termed GAL4-WT1AE Z) consisting of the DNA-binding domain of the yeast transcription factor GAL4 fused in-frame with the N-terminal 298 amino acid (aa) transcriptional regulatory region of WT1 retained the ability to inhibit replication. The hybrid protein and the full-length WT1 inhibited replication without regard to the presence or absence of their binding sites in the replication origin region, indicating that inhibition of replication by the proteins does not require their specific binding to the origin region. The inhibition efficiency of the hybrid protein was the same as that of WT1, indicating that the replication inhibition activity resides in the N-terminal 298 aa region, and that the C-terminal zinc finger-containing DNA-binding domain of WT1 is functionally dispensable for this effect.

[Is the replicon model applicable to higher eukaryotes?]

Thirty-five years ago, the Replicon model was proposed by Jacob, Brenner and Cuzin to explain the regulation of the Escherichia coli DNA replication. In this model, a genetic element, the replicator, would function as a target for a positive-acting initiator protein to drive the initiation of replication. This simple idea has been extremely useful in providing a framework to explain how the initiation of DNA replication occurs in all organisms. The identification of autonomously replicating sequences (ARSs) in budding yeast was the first extension of the Replicon model to eukaryotic chromosomes. In the higher eukaryotes, many biochemically defined replication start sites have been identified; nevertheless there is little genetic data indicating that these sites contain DNA sequences that are essential for replication. Moreover, in early Xenopus or Drosophila embryos, specific DNA sequences are not required either for initiating DNA replication or for preventing rereplication within a single cell cycle. This apparently fundamental difference between replicators in yeast and metazoan embryos may be more superficial than initially thought. In fact, during the past several years, an eukaryotic initiator conserved from yeast to man and also present in embryonic cells, the origin recognition complex (ORC), has been characterized, suggesting that the initiation mechanism should be essentially the same in prokaryotes and eukaryotes. In addition, the efficient once-per-cell-cycle replication of DNA is ensured in eukaryotes by a simple two-step mechanism in which the assembly of stable prereplicative complexes (PreRCs) at origins precedes and is temporally separated from the firing of these origins. Regulation of this process by cyclin-dependent kinases ensures that when origins fire, the cell is no longer competent to form new PreRCs. Now, it is important to understand how these complexes are remodeled or disassembled during replication initiation to trigger the transition from a stable origin-bound complex to a mobile replication machine.

Bacteriophage T4 initiates bidirectional DNA replication through a two-step process

Two-dimensional gel analysis of the bacteriophage T4 ori(uvsY) region revealed a novel "comet" on the Y arc. This comet contains simple Y molecules in which the branch points map to the ori(uvsY) transcript region. The comet depends on the the origin and DNA synthesis and is abolished by a mutation that reduces replication without affecting transcription. These results argue that the branched molecules are intermediates in replication initiation. A transcriptional terminator, cloned just downstream of the origin promoter, shortened the tail of the comet. Therefore, the location of the transcript determines the DNA branch points. We conclude that the comet DNA consists of intermediates in which unidirectional replication has been triggered by priming from the RNA of the origin R loop.

Effects of purified SeqA protein on oriC-dependent DNA replication in vitro

In vivo studies suggest that the Escherichia coli SeqA protein modulates replication initiation in two ways: by delaying initiation and by sequestering newly replicated origins from undergoing re-replication. As a first approach towards understanding the biochemical bases for these effects, we have examined the effects of purified SeqA protein on replication reactions performed in vitro on an oriC plasmid. Our results demonstrate that SeqA directly affects the biochemical events occurring at oriC. First, SeqA inhibits formation of the pre-priming complex. Secondly, SeqA can inhibit replication from an established pre-priming complex, without disrupting the complex. Thirdly, SeqA alters the dependence of the replication system on DnaA protein concentration, stimulating replication at low concentrations of DnaA. Our data suggest that SeqA participates in the assembly of initiation-competent complexes at oriC and, at a later stage, influences the behaviour of these complexes.

Polar localization of the replication origin and terminus in Escherichia coli nucleoids during chromosome partitioning

We show the intracellular localization of the Escherichia coli replication origin (oriC) and chromosome terminus during the cell division cycle by FISH. In newborn cells, oriC is localized at the old-pole-proximal nucleoid border and the terminus at the new-pole-proximal nucleoid border. One copy of replicated oriC migrates rapidly to the opposite nucleoid border. These oriC copies are retained at both nucleoid borders, remaining at a constant distance from each cell pole. The terminus segment migrates from the nucleoid border to midcell and is retained there until the terminus is duplicated. The origin, terminus and other DNA regions show three migration patterns during active partitioning of daughter chromosomes.

Transformation abrogates an early G1-phase arrest point required for specification of the Chinese hamster DHFR replication origin

The origin decision point (ODP) was originally identified as a distinct point during G1-phase when Chinese hamster ovary (CHO) cell nuclei experience a transition that is required for specific recognition of the dihydrofolate reductase (DHFR) origin locus by Xenopus egg extracts. Passage of cells through the ODP requires a mitogen-independent protein kinase that is activated prior to restriction point control. Here we show that inhibition of an early G1-phase protein kinase pathway by the addition of 2-aminopurine (2-AP) prior to the ODP arrests CHO cells in G1-phase. Transformation with simian virus 40 (SV40) abrogated this arrest point, resulting in the entry of cultured cells into S-phase in the presence of 2-AP and a disruption of the normal pattern of initiation sites at the DHFR locus. Cells treated with 2-AP after the ODP initiated replication specifically within the DHFR origin locus. Transient exposure of transformed cells to 2-AP during the ODP transition also disrupted origin choice, whereas non-transformed cells arrested in G1-phase and then passed through a delayed ODP after removal of 2-AP from the medium. We conclude that mammalian cells have many potential sites at which they can initiate replication. Normally, events occurring during the early G1-phase ODP transition determine which of these sites will be the preferred initiation site. However, if chromatin is exposed to S-phase-promoting factors prior to this transition, mammalian cells, like Xenopus and Drosophila embryos, can initiate replication without origin specification.

The human papillomavirus type 18 (HPV18) replication protein E1 is a transcriptional activator when interacting with HPV18 E2

The human papillomavirus type 18 E1 and E2 proteins are both required for the initiation of viral DNA replication. Whereas E2 is the major viral transcription regulator, E1 is the replication initiator protein. They interact with each other and with the origin sequences to initiate viral DNA replication. We show that the HPV18 E1 and E2 proteins, when bound to an origin sequence cloned upstream of a heterologous promoter, synergistically activate transcription. This synergy required binding of E2 to at least two binding sites, but was partially independent of E1 binding to the origin of replication. Transcriptional activation was observed even in the absence of replication of the target DNA. Only homologous E1 and E2 proteins binding to homologous origin sequences from BPV1 or HPV18 viruses could synergistically activate transcription. We show that the HPV18 E1 protein can activate transcription when targeted to the DNA by fusion of the complete polypeptide with the BPV1 E2 C-terminus dimerization/DNA binding domain, implying that HPV18 E1 is an intrinsic transcriptional activator, though less potent than E2. The interaction between E1 and E2 may form a transcriptionally active complex during initiation of viral DNA replication.

Topoisomerase I stimulates SV40 T antigen-mediated DNA replication and inhibits T antigen's ability to unwind DNA at nonorigin sites

We have previously found that purified SV40 T antigen and topoisomerase I (topo I) bind to one another in vitro. In this report, we determined the effects of human topo I on T antigen-mediated DNA replication and investigated whether it altered T antigen's biochemical activities. Topo I stimulates DNA replication and especially increases the amounts of finished circular molecules. This protein had no effect on T antigen's ability to bind, distort, or unwind the origin of replication. However, unwinding of DNA by T antigen was strongly inhibited by topo I when it was initiated at sites other than the origin. We demonstrate that the presence of T antigen binding sites in DNA interfere with inhibition of unwinding by topo I. These results indicate that topo I may increase the specificity of unwinding by inhibiting the reaction at non-origin sites. Fragments of T antigen that bind to topo I abrogate topo I's inhibition of non-origin-dependent unwinding, indicating that topo I inhibits unwinding through a direct interaction with T antigen. We propose a model whereby T antigen and topo I function together at the origin to specifically unwind it and initiate DNA replication.

Developmental regulation of MCM replication factors in Xenopus laevis

At the midblastula transition (MBT) during Xenopus laevis development, zygotic transcription begins [1], and the rapid, early cleavage cycles are replaced by cell-division cycles that lengthen and acquire G (gap) phases [2] and checkpoints [3-5]. This cell-cycle remodeling may result from either a loss of maternal products, the transcription of zygotic genes, or the replacement of maternal proteins by zygotic gene products. We have identified an example of the third possibility: distinct maternal and zygotic genes encoding a member of the minichromosome maintenance (MCM) protein family. The mcm genes were identified in yeast by mutations that blocked replication of artificial chromosomes or perturbed the G1/S transition in the cell cycle [6,7]. In Xenopus eggs, the MCM2-MCM7 proteins assemble as multimeric complexes at chromosomal origins of replication [8-14]. The sequential, cell-cycle-dependent assembly of the origin replication complex (ORC), CDC6 protein and the MCM complex at origins of replication ensures that DNA replicates only once per cell cycle [15,16]. The periodic association of the MCM complex with chromatin may be regulated via phosphorylation by cyclin-dependent kinases (Cdks) [11]. We have cloned the first example of a developmentally regulated mcm gene, zygotic mcm6 (zmcm6), expressed only after gastrulation when the cell cycle is remodeled. The zMCM6 protein assembles into MCM complexes and differs from maternal MCM6 (mMCM6) in having a carboxy-terminal extension and a consensus cyclin-Cdk phosphorylation site. There may also be maternal-zygotic pairs of other MCMs. These data suggest that MCMs are critical for cell-cycle remodeling during early Xenopus development.

Cell cycle-dependent duplication and bidirectional migration of SeqA-associated DNA-protein complexes in E. coli

Using immunofluorescence microscopy, we have found that SeqA protein, a regulator of replication initiation, is localized as discrete fluorescent foci in E. coli wild-type cells. Surprisingly, SeqA foci were observed also in an oriC deletion mutant. Statistical analysis revealed that a SeqA focus is localized at midcell in newborn cells. The SeqA focus is duplicated and tethered at midcell until an FtsZ ring is formed. Subsequently, these foci migrate in opposite directions toward cell quarter sites and remain tethered there until the cell divides. The cell cycle-dependent bidirectional migration of SeqA-DNA complexes is quite different from the migration pattern of oriC Dna copies. MukB protein is required for correct localization of SeqA complexes by an unknown mechanism.

Chromosome and low copy plasmid segregation in E. coli: visual evidence for distinct mechanisms

We have investigated DNA segregation in E. coli by inserting multiple lac operator sequences into the chromosome near the origin of replication (oriC), in the hisC gene, a terminus marker, and into plasmids P1 and F. Expression of a GFP-LacI fusion protein allowed visualization of lac operator localization. oriC was shown to be specifically localized at or near the cell poles, and when duplicated, one copy moved to the site of new pole formation near the site of cell division. In contrast, P1 and F localized to the cell center and on duplication appeared to move rapidly to the quarter positions in the cell. Our analysis suggests that different active processes are involved in movement and localization of the chromosome and of the two plasmids during segregation.

Direct evidence for active segregation of oriC regions of the Bacillus subtilis chromosome and co-localization with the SpoOJ partitioning protein

We have developed methods for labelling regions of the Bacillus subtilis chromosome with the nucleotide analogue 5-bromodeoxyuridine (BrdU) and for subcellular visualization of the labelled DNA. Examination of oriC-labelled chromosomes in outgrowing spores has provided direct evidence for active segregation of sister chromosomes. Co-immunodetection of Spo0J and BrdU-labelled DNA has directly confirmed the expected close association between this chromosome partitioning protein and the oriC region of the chromosome. The results provide further support for the notion that bacterial cells use an active mitotic-like mechanism to segregate their chromosomes.

The replication origin decision point is a mitogen-independent, 2-aminopurine-sensitive, G1-phase event that precedes restriction point control

At a distinct point during G1 phase (the origin decision point [ODP]), Chinese hamster ovary (CHO) cell nuclei experience a transition (origin choice) that is required for specific recognition of the dihydrofolate reductase (DHFR) origin locus by Xenopus egg extracts. We have investigated the relationship between the ODP and progression of CHO cells through G1 phase. Selection of the DHFR origin at the ODP was rapidly inhibited by treatment of early G1-phase cells with the protein kinase inhibitor 2-aminopurine (2-AP). Inhibition of the ODP required administration of 2-AP at least 3 h prior to phosphorylation of the retinoblastoma tumor suppressor protein (Rb) and the restriction point (R point). Cells deprived of either serum or isoleucine from metaphase throughout early G1 phase acquired the capacity to replicate in Xenopus egg extract (replication licensing) and subsequently passed through the ODP on the same schedule as cells cultured in complete growth medium. After growth arrest at the R point with hypophosphorylated Rb protein, serum- or isoleucine-deprived cells experienced a gradual loss of replication licensing. However, recognition of the DHFR origin by Xenopus egg cytosol remained stable in growth-arrested cells until the point at which all nuclei had lost the capacity to initiate replication. These results provide evidence that the ODP requires a mitogen-independent protein kinase that is activated after replication licensing and prior to R-point control.

Crystal structure of a pol alpha family replication DNA polymerase from bacteriophage RB69

The 2.8 A resolution crystal structure of the bacteriophage RB69 gp43, a member of the eukaryotic pol alpha family of replicative DNA polymerases, shares some similarities with other polymerases but shows many differences. Although its palm domain has the same topology as other polymerases, except rat DNA polymerase beta, one of the three carboxylates required for nucleotidyl transfer is located on a different beta strand. The structures of the fingers and thumb domains are unrelated to all other known polymerase structures. The editing 3'-5' exonuclease domain of gp43 is homologous to that of E. coli DNA polymerase I but lies on the opposite side of the polymerase active site. An extended structure-based alignment of eukaryotic DNA polymerase sequences provides structural insights that should be applicable to most eukaryotic DNA polymerases.

A role for Cdk2 kinase in negatively regulating DNA replication during S phase of the cell cycle

Using cell-free extracts made from Xenopus eggs, we show that cdk2-cyclin E and A kinases play an important role in negatively regulating DNA replication. Specifically, we demonstrate that the cdk2 kinase concentration surrounding chromatin in extracts increases 200-fold once the chromatin is assembled into nuclei. Further, we find that if the cdk2-cyclin E or A concentration in egg cytosol is increased 16-fold before the addition of sperm chromatin, the chromatin fails to initiate DNA replication once assembled into nuclei. This demonstrates that cdk2-cyclin E or A can negatively regulate DNA replication. With respect to how this negative regulation occurs, we show that high levels of cdk2-cyclin E do not block the association of the protein complex ORC with sperm chromatin but do prevent association of MCM3, a protein essential for replication. Importantly, we find that MCM3 that is prebound to chromatin does not dissociate when cdk2-cyclin E levels are increased. Taken together our results strongly suggest that during the embryonic cell cycle, the low concentrations of cdk2-cyclin E present in the cytosol after mitosis and before nuclear formation allow proteins essential for potentiating DNA replication to bind to chromatin, and that the high concentration of cdk2-cyclin E within nuclei prevents MCM from reassociating with chromatin after replication. This situation could serve, in part, to limit DNA replication to a single round per cell cycle.

Genome replication in early mouse embryos follows a defined temporal and spatial order

The spatial and temporal organisation of replication sites during early mouse embryogenesis was analysed using high resolution confocal and video fluorescence microscopy. The results show that distinct replication patterns occur in the transcriptionally inactive pronuclei of 1-cell embryos as well as in the transcriptionally active nuclei from 2- and 16/32-cell embryos. This indicates that specific chromatin regions are replicated at different times during S-phase and provides the first evidence that mechanisms controlling the temporal and spatial replication of DNA are already present in the haploid pronuclei of the mammalian zygote. Furthermore the data demonstrate that the male and female pronuclei in one-cell embryos replicate their genomes asynchronously. Finally, we observe changes in the dynamics of embryonic genome replication during early development which correlate with gross chromatin structure transitions detected at the electron microscope level. Taken together these results indicate that DNA synthesis in the mouse zygote follows a defined four-dimensional order which may evolve during development and differentiation.

Replication of minichromosomes in a host in which chromosome replication is random

Minichromosomes are plasmids with the origin of chromosome replication, oriC, as their only origin of replication. In Escherichia coli, minichromosomes are compatible with the chromosome and replicate in a cell-cycle-specific manner at the same time as oriC located on the chromosome initiates replication. In int strains, oriC has been inactivated and replaced by a plasmid origin. Because plasmids control their own replication, chromosome replication is uncoupled from the normal cell-cycle control and is random with respect to the cell cycle in the int strains. We have used an intP1 strain to address the question of whether minichromosome replication is coupled to the replication of the chromosome or is governed by cell-cycle-specific signals. Minichromosome replication was analysed by density-shift experiments and found not to be random in the randomly replicating intP1 host. This suggests that the cell-cycle-specific control functions of oriC replication are operating also in the intP1 strain.

Coordinate binding of ATP and origin DNA regulates the ATPase activity of the origin recognition complex

The Origin Recognition Complex (ORC) is a six-protein assembly that specifies the sites of DNA replication initiation in S. cerevisiae. Origin recognition by ORC requires ATP. Here, we demonstrate that two subunits, Orc1p and Orc5p, bind ATP and that Orc1p also hydrolyzes ATP. ATP binding and hydrolysis by Orc1p are both regulated by origin DNA in a sequence-specific manner. ATP binding to Orc1p, but not ATP hydrolysis, is responsible for the ATP dependence of the ORC-origin interaction, indicating that ATP is a cofactor that locks ORC on origin DNA. These data demonstrate that occupancy of the Orc1p ATP-binding site has a profound effect on ORC function and that ATP hydrolysis by Orc1p has the potential to drive transitions between different functional states of ORC.

The iteron bases and spacers of the P1 replication origin contain information that specifies the formation of a complex structure involved in initiation

The origin of replication of the P1 plasmid contains five direct, imperfect repeats (iterons) of a 19 bp sequence that binds the P1-encoded RepA initiator protein. RepA binding to these iterons triggers origin initiation and represses transcription from the repA promoter that is nested within the iterons. The origin iterons were replaced with ligated oligonucleotides that insert five perfect 19 bp repeats with identical spacer sequences. This eliminates the natural variation in the iteron and spacer sequences and removes the repA promoter. The reconstructed origin is functional, showing that the repA promoter is not essential for origin function. The method used to make the reconstructed origin allows substitution of identical iterons with altered sequence or spacer length. Single changes of conserved iteron bases gave reduced or non-existent origin activity, as did an increase in spacer length. Like the wild type, most of these mutant arrays retain avid primary binding activity for the RepA protein. However, although the wild-type arrays readily form a mature complex in which all iterons are saturated, the most replication-defective mutants were completely unable to do this, even at very high RepA concentrations. It appears that iteron spacing and contacts involving at least three of the conserved iteron bases play an important role in the assembly of the mature structure in which all sites are occupied. A model is presented in which an allosteric interaction between the DNA site and protein is needed for the saturated, mature complex required for initiation.

Role of interactions between the origin recognition complex and SIR1 in transcriptional silencing

Transcriptional silencing of the HM mating-type loci in the yeast Saccharomyces cerevisiae is caused by the localized formation of an altered chromatin structure, analogous to heterochromatin in higher eukaryotes. Silencing depends on cis-acting sequences, termed silencers, as well as several trans-acting factors, including histones H4 and H3, proteins RAP1 and ABF1, and the four SIR proteins (SIR1-4). Each of the four HM silencers contains an autonomously replicating sequence (ARS) to which the origin replication complex (ORC) binds. This six-protein complex is required for initiation of DNA replication, as well as for silencing. Efficient establishment of the silenced state requires both passage through the S phase of the cell cycle and SIR1 protein. Previous experiments suggested that SIR1 might be localized to the silencers by binding to ORC and/or RAP1. Here we report that SIR1 can bind directly to ORC1, the largest of the ORC subunits, and that targeting of SIR1 to ORC1 at a silencer is sufficient to establish a silenced state.

Replication origins in eukaroytes

Recent experiments in budding yeast and Xenopus have provided new insights into the regulation of eukaroytic DNA replication. The multi-subunit origin recognition complex plays a key role in initiation, remaining bound at origins of replication during most of the cell cycle. Early in the cell cycle, Cdc6 and the Mcm proteins 'reset' chromatin for another round of DNA replication. Cyclin-dependent kinases appear to play a dual role, both in activating replication origins and blocking the formation of new pre-replicative complexes; thus limiting replication to once per cell cycle.

A DNA structure is required for geminivirus replication origin function

The genome of the geminivirus tomato golden mosaic virus (TGMV) consists of two single-stranded circular DNAs, A and B, that replicate through a rolling-circle mechanism in nuclei of infected plant cells. The TGMV origin of replication is located in a conserved 5' intergenic region and includes at least two functional elements: the origin recognition site of the essential viral replication protein, AL1, and a sequence motif with the potential to form a hairpin or cruciform structure. To address the role of the hairpin motif during TGMV replication, we constructed a series of B-component mutants that resolved sequence changes from structural alterations of the motif. Only those mutant B DNAs that retained the capacity to form the hairpin structure replicated to wild-type levels in tobacco protoplasts when the viral replication proteins were provided in trans from a plant expression cassette. In contrast, the same B DNAs replicated to significantly lower levels in transient assays that included replicating, wild-type TGMV A DNA. These data established that the hairpin structure is essential for TGMV replication, whereas its sequence affects the efficiency of replication. We also showed that TGMV AL1 functions as a site-specific endonuclease in vitro and mapped the cleavage site to the loop of the hairpin. In vitro cleavage analysis of two TGMV B mutants with different replication phenotypes indicated that there is a correlation between the two assays for origin activity. These results suggest that the in vivo replication results may reflect structural and sequence requirements for DNA cleavage during initiation of rolling-circle replication.

S-phase-promoting cyclin-dependent kinases prevent re-replication by inhibiting the transition of replication origins to a pre-replicative state

BACKGROUND

DNA replication and mitosis are triggered by activation of kinase complexes, each made up of a cyclin and a cyclin-dependent kinase (Cdk). It had seemed possible that the association of Cdks with different classes of cyclins specifies whether S phase (replication) or M phase (mitosis) will occur. The recent finding that individual B-type cyclins (encoded by the genes CLB1-CLB6) can have functions in both processes in the budding yeast Saccharomyces cerevisiae casts doubt on this notion.

RESULTS

S. cerevisiae strains lacking C1b1-C1b4 undergo DNA replication once but fail to enter mitosis. We have isolated mutations in two genes, SIM1 and SIM2 (SIM2 is identical to SEC72), which allow such cells to undergo an extra round of DNA replication without mitosis. The Clb5 kinase, which promotes S phase, remains active during the G2-phase arrest of cells of the parental strain, but its activity declines rapidly in sim mutants. Increased expression of the CLB5 gene prevents re-replication. Thus, a cyclin B-kinase that promotes DNA replication in G1-phase cells can prevent re-replication in G2-phase cells. Inactivation of C1b kinases by expression of the specific C1b-Cdk1 inhibitor p40SIC1 is sufficient to induce a prereplicative state at origins of replication in cells blocked in G2/M phase by nocodazole. Re-activation of C1b-Cdk1 kinases induces a second round of DNA replication.

CONCLUSIONS

We propose that S-phase-promoting cyclin B--Cdk complexes prevent re-replication during S, G2 and M phases by inhibiting the transition of replication origins to a pre-replicative state. This model can explain both why origins 'fire' only once per S phase and why S phase is dependent on completion of the preceding M phase.

E. coli SeqA protein binds oriC in two different methyl-modulated reactions appropriate to its roles in DNA replication initiation and origin sequestration

The seqA gene negatively modulates replication initiation at the E. coli origin, oriC. seqA is also essential for sequestration, which acts at oriC and the dnaA promoter to ensure that replication initiation occurs exactly once per chromosome per cell cycle. Initiation is promoted by full methylation of GATC sites clustered in oriC; sequestration is specific to the hemimethylated forms generated by replication. SeqA protein purification and DNA binding are described. SeqA interacts with fully methylated oriC strongly and specifically. This reaction requires multiple molecules of SeqA and determinants throughout oriC, including segments involved in open complex formation. SeqA interacts more strongly with hemimethylated DNA; in this case, oriC and non-oriC sequences are bound similarly. Also, binding of hemimethylated oriC by membrane fractions is due to SeqA. Direct interaction of SeqA protein with the replication origin is likely to be involved in both replication initiation and sequestration.

Changes in the subcellular localization of replication initiation proteins and cell cycle proteins during G1- to S-phase transition in mammalian cells

DNA replication in eukaryotic cells is restricted to the S-phase of the cell cycle. In a cell-free replication model system, using SV40 origin-containing DNA, extracts from G1 cells are inefficient in supporting DNA replication. We have undertaken a detailed analysis of the subcellular localization of replication proteins and cell cycle regulators to determine when these proteins are present in the nucleus and therefore available for DNA replication. Cyclin A and cdk2 have been implicated in regulating DNA replication, and may be responsible for activating components of the DNA replication initiation complex on entry into S-phase. G1 cell extracts used for in vitro replication contain the replication proteins RPA (the eukaryotic single-stranded DNA binding protein) and DNA polymerase alpha as well as cdk2, but lack cyclin A. On localizing these components in G1 cells we find that both RPA and DNA polymerase alpha are present as nuclear proteins, while cdk2 is primarily cytoplasmic and there is no detectable cyclin A. An apparent change in the distribution of these proteins occurs as the cell enters S-phase. Cyclin A becomes abundant and both cyclin A and cdk2 become localized to the nucleus in S-phase. In contrast, the RPA-34 and RPA-70 subunits of RPA, which are already nuclear, undergo a transition from the uniform nuclear distribution observed during G1, and now display a distinct punctate nuclear pattern. The initiation of DNA replication therefore most likely occurs by modification and activation of these replication initiation proteins rather than by their recruitment to the nuclear compartment.

Localization of the start sites of lagging-strand replication of rolling-circle plasmids from gram-positive bacteria

A number of small, multicopy plasmids from Gram-positive bacteria replicate by an asymmetric rolling-circle mechanism. Previous studies with several of these plasmids have identified a palindromic sequence, SSOA, that acts as the single-strand origin (SSO) for the replication of the lagging-strand DNA. Although not all the SSOA sequences share DNA sequence homology, they are structurally very similar. We have used an in vitro system to study the lagging-strand replication of several plasmids from Gram-positive bacteria using the SSOA sequences of pT181, pE194 and pSN2 as representative of three different groups of Staphylococcus aureus plasmids. In addition, we have investigated the lagging-strand replication of the pUB110 plasmid that contains an alternative single-strand origin, SSOU. Our results confirm that RNA polymerase is involved in lagging-strand synthesis from both SSOA and SSOU-type lagging-strand origins. Interestingly, while initiation of lagging-strand DNA synthesis of pUB110 occurred predominantly at a single position within SSOU, replication of pT181, pSN2 and pE194 plasmids initiated at multiple positions from SSOA.

In vivo evidence for the involvement of anionic phospholipids in initiation of DNA replication in Escherichia coli

In vitro, anionic phospholipids can reactivate inactivated DnaA protein, which is essential for initiation of DNA replication at the oriC site of Escherichia coli [Sekimizu, K. & Kornberg, A. (1988) J. Biol. Chem. 263, 7131-7135]. Mutations in the pgsA gene (encoding phosphatidylglycerophosphate synthase) limit the synthesis of the major anionic phospholipids and lead to arrest of cell growth. We report herein that a mutation in the rnhA gene (encoding RNase H) that bypasses the need for the DnaA protein through induction of constitutive stable DNA replication [Kogoma, T. & von Meyenburg, K. (1983) EMBO J. 2, 463-468] also suppressed the growth arrest phenotype of a pgsA mutant. The maintenance of plasmids dependent on an oriC site for replication, and therefore DnaA protein, was also compromised under conditions of limiting anionic phospholipid synthesis. These results provide support for the involvement of anionic phospholipids in normal initiation of DNA replication at oriC in vivo by the DnaA protein.

Importance of the replication origin sequestration in cell division of Escherichia coli

The DNA adenine methyltransferase of Escherichia coli methylates adenines at GATC sequences. The mutant deficient in this methylase has no apparent deficiency in the cell division process in spite of the absence of both synchrony in initiations of chromosomal DNA replication and sequestration of replication origin (oriC) at hemimethylated state. However, the dam mutant cannot resume cell division after hyperosmotic shock differing from the wild-type strain. This inhibition is not provoked by induction of the cell division inhibitor, SfiA protein. Although the FtsZ protein is present in the dam mutant in a reduced amount compared to wild-type, the quantitative difference of this protein is not the main reason of division arrest provoked by hyperosmotic shock. This observation supports the idea of oriC-membrane interaction playing a role both in chromosome partitioning and cell division as predicted by replicon theory.

Eukaryotic replication origins: control in space and time

Replication origins facilitate the choreography of genome duplication by acting as targets for regulatory mechanisms. Eukaryotic cells control the efficiency and the time of origin activity. In addition, origins that have been replicated are prevented from doing so twice in the same cell cycle. In this review we will examine the mechanisms that may be used to control these processes, and discuss the role of replication in regulating transcription.