Regulation of chromosome replication

S-Cdk-dependent phosphorylation of Sld2 essential for chromosomal DNA replication in budding yeast

Cyclin-dependent protein kinases (Cdks) in eukaryotic cells work as a key enzyme at various points in the cell cycle. At the onset of S phase, active S-phase Cdks (S-Cdks) are essential for chromosomal DNA replication. Although several replication proteins are phosphorylated in a Cdk-dependent manner, the biological effects of phosphorylation of these proteins on the activation of DNA replication have not been elucidated. Here we show that Sld2 (ref. 4) (also known as Drc1; ref. 5), one of the replication proteins of budding yeast (Saccharomyces cerevisiae), is phosphorylated in S phase in an S-Cdk-dependent manner, and mutant Sld2 lacking all the preferred Cdk phosphorylation sites (All-A) is defective in chromosomal DNA replication. Moreover, the complex that contains, at least, Sld2 and Dpb11 (ref. 6) (the Sld2-Dpb11 complex) is formed predominantly in S phase; the All-A protein is defective in this complex formation. Because this complex is suggested to be essential for chromosomal DNA replication, it seems likely that S-Cdk positively regulates formation of the Sld2-Dpb11 complex and, consequently, chromosomal DNA replication.

Analysis of Cdc6 function in the assembly of mammalian prereplication complexes

Eukaryotic DNA replication requires the previous formation of a prereplication complex containing the ATPase Cdc6 and the minichromosome maintenance (Mcm) complex. Although considerable insight has been gained from in vitro studies and yeast genetics, the functional analysis of replication proteins in intact mammalian cells has been lacking. We have made use of adenoviral vectors to express normal and mutant forms of Cdc6 in quiescent mammalian cells to assess function. We demonstrate that Cdc6 expression alone is sufficient to induce a stable association of endogenous Mcm proteins with chromatin in serum-deprived cells where cyclin-dependent kinase (cdk) activity is low. Moreover, endogenous Cdc6 is sufficient to load Mcm proteins onto chromatin in the absence of cdk activity in p21-arrested cells. Cdc6 synergizes with physiological levels of cyclin E/Cdk2 to induce semiconservative DNA replication in quiescent cells whereas cyclin A/Cdk2 is unable to collaborate with Cdc6. Cdc6 that cannot be phosphorylated by cdks is fully capable of inducing Mcm chromatin association and replication. Mutation of the Cdc6 ATP-binding site severely impairs the ability of Cdc6 to induce Mcm chromatin loading and reduces its ability to induce replication. Nevertheless, the ATPase domain of Cdc6 in the absence of the noncatalytic amino terminus is not sufficient for either Mcm chromatin loading or DNA replication, indicating a requirement for this domain of Cdc6.

Synthesis and turn-over of the replicative Cdc6 protein during the HeLa cell cycle

The human replication protein Cdc6p is translocated from its chromatin sites to the cytoplasm during the replication phase (S phase) of the cell cycle. However, the amounts of Cdc6p on chromatin remain high during S phase implying either that displaced Cdc6p can rebind to chromatin, or that Cdc6p is synthesized de novo. We have performed metabolic labeling experiments and determined that [35S]methionine is incorporated into Cdc6p at similar rates during the G1 phase and the S phase of the cell cycle. Newly synthesized Cdc6p associates with chromatin. Pulse-chase experiments show that chromatin-bound newly synthesized Cdc6p has a half life of 2-4 h. The results indicate that, once bound to chromatin, pulse-labeled new Cdc6p behaves just as old Cdc6p: it dissociates and eventually disappears from the nucleus. The data suggest a surprisingly dynamic behaviour of Cdc6p in the HeLa cell cycle.

Sensitivity of the origin decision point to specific inhibitors of cellular signaling and metabolism

Chinese hamster ovary (CHO) cells become committed to initiate DNA replication at specific sites within the dihydrofolate reductase (DHFR) locus at a discrete point during G1 phase, the origin decision point (ODP). To better understand the requirements for passage through the ODP, we evaluated the ability of various inhibitors of G1-phase progression to prevent passage through the ODP. Of several protein kinase inhibitors tested, only inhibitors of cyclin-dependent kinase (cdk) activity (roscovitine, olomoucine) prevented passage through the ODP. Inhibitors of MAP kinase (PD98059), PKA (KT5720), PKG (KT5823), as well as inhibition of integrin-mediated signaling by preventing cell adhesion, all arrested cells in the post-ODP stages of G1 phase. Intriguingly, inhibitors of proteasome-dependent proteolysis (MG132, ALLN, lactacystin) and transcription (DRB, alpha-amanitin, actinomycin D) also inhibited passage through the ODP, whereas inhibition of protein synthesis (cycloheximide) had no effect on the ODP. Cross-checking each inhibitor for its affect on transcription revealed that the ODP could be uncoupled from transcription; MG132 and lactacystin did not inhibit transcription, and KT5720 was a potent inhibitor of transcription. Importantly, cells that were arrested upstream of the ODP with either roscovitine or lactacystin contained functional prereplication complexes (pre-RCs), supporting previous findings that pre-RC formation is not sufficient for origin specification. These results demonstrate that specification of the DHFR origin is independent of growth signaling mechanisms and does not require G1-phase synthesis of a protein regulator such as a cyclin or Dbf4/ASK1, positioning the ODP after pre-RC formation but prior to the activation of the known S-phase promoting kinases.

Essential role of MCM proteins in premeiotic DNA replication

A critical event in eukaryotic DNA replication involves association of minichromosome maintenance (MCM2-7) proteins with origins, to form prereplicative complexes (pre-RCs) that are competent for initiation. The ability of mutants defective in MCM2-7 function to complete meiosis had suggested that pre-RC components could be irrelevant to premeiotic S phase. We show here that MCM2-7 proteins bind to chromatin in fission yeast cells preparing for meiosis and during premeiotic S phase in a manner suggesting they in fact are required for DNA replication in the meiotic cycle. This is confirmed by analysis of a degron mcm4 mutant, which cannot carry out premeiotic DNA replication. Later in meiosis, Mcm4 chromatin association is blocked between meiotic nuclear divisions, presumably accounting for the absence of a second round of DNA replication. Together, these results emphasize similarity between replication mechanisms in mitotic and meiotic cell cycles.

Xenopus Mcm10 binds to origins of DNA replication after Mcm2-7 and stimulates origin binding of Cdc45

Current models suggest that the replication initiation factor Mcm10 is required for association of Mcm2-7 with origins of replication to generate the prereplicative complex (pre-RC). Here we report that Xenopus Mcm10 (XMcm10) is not required for origin binding of XMcm2-7. Instead, the chromatin binding of XMcm10 at the onset of DNA replication requires chromatin-bound XMcm2-7, and it is independent of Cdk2 and Cdc7. In the absence of XMcm10, XCdc45 binding, XRPA binding, and initiation-dependent plasmid supercoiling are blocked. Therefore, XMcm10 performs its function after pre-RC assembly and before origin unwinding. As one of the earliest known pre-RC activation steps, chromatin binding of XMcm10 is an attractive target for regulation by cell cycle checkpoints.

Drosophila minichromosome maintenance 6 is required for chorion gene amplification and genomic replication

Duplication of the eukaryotic genome initiates from multiple origins of DNA replication whose activity is coordinated with the cell cycle. We have been studying the origins of DNA replication that control amplification of eggshell (chorion) genes during Drosophila oogenesis. Mutation of genes required for amplification results in a thin eggshell phenotype, allowing a genetic dissection of origin regulation. Herein, we show that one mutation corresponds to a subunit of the minichromosome maintenance (MCM) complex of proteins, MCM6. The binding of the MCM complex to origins in G1 as part of a prereplicative complex is critical for the cell cycle regulation of origin licensing. We find that MCM6 associates with other MCM subunits during amplification. These results suggest that chorion origins are bound by an amplification complex that contains MCM proteins and therefore resembles the prereplicative complex. Lethal alleles of MCM6 reveal it is essential for mitotic cycles and endocycles, and suggest that its function is mediated by ATP. We discuss the implications of these findings for the role of MCMs in the coordination of DNA replication during the cell cycle.

S phase and G2 arrests induced by topoisomerase I poisons are dependent on ATR kinase function

ATR, a human phosphatidylinositol 3-kinase-related kinase, is an important component of the cellular response to DNA damage. In the present study, we evaluated the role of ATR in modulating the response of cells to S phase-associated DNA double-stranded breaks induced by topoisomerase poisons. Prolonged exposure to low doses of the topoisomerase I poison topotecan (TPT) resulted in S phase slowing because of diminished DNA synthesis at late-firing replicons. In contrast, brief TPT exposure, as well as prolonged exposure to the topoisomerase II poison etoposide, resulted in subsequent G(2) arrest. These responses were associated with phosphorylation of the checkpoint kinase Chk1. The cell cycle responses and phosphorylation of Chk1 were markedly diminished by forced overexpression of a dominant negative, kinase-inactive allele of ATR. In contrast, deficiency of the related kinase ATM had no effect on these events. The loss of ATR-dependent checkpoint function sensitized GM847 human fibroblasts to the cytotoxic effects of the topoisomerase I poisons TPT and 7-ethyl-10-hydroxycamptothecin, as assessed by inhibition of colony formation, increased trypan blue uptake, and development of apoptotic morphological changes. Expression of kdATR also sensitized GM847 cells to the cytotoxic effects of prolonged low dose etoposide and doxorubicin, albeit to a smaller extent. Collectively, these results not only suggest that ATR is important in responding to the replication-associated DNA damage from topoisomerase poisons, but also support the view that ATM and ATR have unique roles in activating the downstream kinases that participate in cell cycle checkpoints.

Mammalian nuclei become licensed for DNA replication during late telophase

Mcm 2-7 are essential replication proteins that bind to chromatin in mammalian nuclei during late telophase. Here, we have investigated the relationship between Mcm binding, licensing of chromatin for replication, and specification of the dihydrofolate reductase (DHFR) replication origin. Approximately 20% of total Mcm3 protein was bound to chromatin in Chinese hamster ovary (CHO) cells during telophase, while an additional 25% bound gradually and cumulatively throughout G1-phase. To investigate the functional significance of this binding, nuclei prepared from CHO cells synchronized at various times after metaphase were introduced into Xenopus egg extracts, which were either immunodepleted of Mcm proteins or supplemented with geminin, an inhibitor of the Mcm-loading protein Cdt1. Within 1 hour after metaphase, coincident with completion of nuclear envelope formation, CHO nuclei were fully competent to replicate in both of these licensing-defective extracts. However, sites of initiation of replication in each of these extracts were found to be dispersed throughout the DHFR locus within nuclei isolated between 1 to 5 hours after metaphase, but became focused to the DHFR origin within nuclei isolated after 5 hours post-metaphase. Importantly, introduction of permeabilized post-ODP, but not pre-ODP, CHO nuclei into licensing-deficient Xenopus egg extracts resulted in the preservation of a significant degree of DHFR origin specificity, implying that the previously documented lack of specific origin selection in permeabilized nuclei is at least partially due to the licensing of new initiation sites by proteins in the Xenopus egg extracts. We conclude that the functional association of Mcm proteins with chromatin (i.e. replication licensing) in CHO cells takes place during telophase, several hours prior to the specification of replication origins at the DHFR locus.

Loss of heterozygosity as a predictor to map tumor suppressor genes in cancer: molecular basis of its occurrence

High frequency of chromosomal deletions elicited as losses of heterozygosity is a hallmark of genomic instability in cancer. Functional losses of tumor suppressor genes caused by loss of heterozygosity at defined regions during clonal selection for growth advantage define the minimally lost regions as their likely locations on chromosomes. Loss of heterozygosity is elicited at the molecular or cytogenetic level as a deletion, a gene conversion, single or double homologous and nonhomologous mitotic recombinations, a translocation, chromosome breakage and loss, chromosomal fusion or telomeric end-to-end fusions, or whole chromosome loss with or without accompanying duplication of the retained chromosome. Because of the high level of specificity, loss of heterozygosity has recently become invaluable as a marker for diagnosis and prognosis of cancer. The molecular defects for the occurrence of loss of heterozygosity are derived from disabled caretaker genes, which protect the integrity of DNA, or chromosome segregator genes, which mediate faithful chromosome disjunction.

Mammalian Orc1 protein is selectively released from chromatin and ubiquitinated during the S-to-M transition in the cell division cycle

Previous studies have shown that changes in the affinity of the hamster Orc1 protein for chromatin during the M-to-G(1) transition correlate with the activity of hamster origin recognition complexes (ORCs) and the appearance of prereplication complexes at specific sites. Here we show that Orc1 is selectively released from chromatin as cells enter S phase, converted into a mono- or diubiquitinated form, and then deubiquitinated and re-bound to chromatin during the M-to-G(1) transition. Orc1 is degraded by the 26S proteasome only when released into the cytosol, and peptide additions to Orc1 make it hypersensitive to polyubiquitination. In contrast, Orc2 remains tightly bound to chromatin throughout the cell cycle and is not a substrate for ubiquitination. Since the concentration of Orc1 remains constant throughout the cell cycle, and its half-life in vivo is the same as that of Orc2, ubiquitination of non-chromatin-bound Orc1 presumably facilitates the inactivation of ORCs by sequestering Orc1 during S phase. Thus, in contrast to yeast (Saccharomyces cerevisiae and Schizosaccharomyces pombe), mammalian ORC activity appears to be regulated during each cell cycle through selective dissociation and reassociation of Orc1 from chromatin-bound ORCs.

Genome-wide distribution of ORC and MCM proteins in S. cerevisiae: high-resolution mapping of replication origins

DNA replication origins are fundamental to chromosome organization and duplication, but understanding of these elements is limited because only a small fraction of these sites have been identified in eukaryotic genomes. Origin Recognition Complex (ORC) and minichromosome maintenance (MCM) proteins form prereplicative complexes at origins of replication. Using these proteins as molecular landmarks for origins, we identified ORC- and MCM-bound sites throughout the yeast genome. Four hundred twenty-nine sites in the yeast genome were predicted to contain replication origins, and approximately 80% of the loci identified on chromosome X demonstrated origin function. A substantial fraction of the predicted origins are associated with repetitive DNA sequences, including subtelomeric elements (X and Y') and transposable element-associated sequences (long terminal repeats). These findings identify the global set of yeast replication origins and open avenues of investigation into the role(s) ORC and MCM proteins play in chromosomal architecture and dynamics.

DNA replication. Genomic views of genome duplication

DNA replication is initiated at numerous origins of replication (oris) within the chromosomes. In a pair of ambitious studies, two groups have used different techniques to pinpoint the locations of all of the oris throughout the yeast genome at different times during S phase (Raghuraman et al., Wyrick et al.). Stillman, in his Perspective, compares and contrasts the different methods and their findings, and speculates on the value of combining these techniques to look at oris in the human genome.

Strong minor groove base conservation in sequence logos implies DNA distortion or base flipping during replication and transcription initiation

The sequence logo for DNA binding sites of the bacteriophage P1 replication protein RepA shows unusually high sequence conservation ( approximately 2 bits) at a minor groove that faces RepA. However, B-form DNA can support only 1 bit of sequence conservation via contacts into the minor groove. The high conservation in RepA sites therefore implies a distorted DNA helix with direct or indirect contacts to the protein. Here I show that a high minor groove conservation signature also appears in sequence logos of sites for other replication origin binding proteins (Rts1, DnaA, P4 alpha, EBNA1, ORC) and promoter binding proteins (sigma(70), sigma(D) factors). This finding implies that DNA binding proteins generally use non-B-form DNA distortion such as base flipping to initiate replication and transcription.

Site-specific DNA binding of the Schizosaccharomyces pombe origin recognition complex is determined by the Orc4 subunit

The mechanism by which origin recognition complexes (ORCs) identify replication origins was investigated using purified Orc proteins from Schizosaccharomyces pombe. Orc4p alone bound tightly and specifically to several sites within S. pombe replication origins that are genetically required for origin activity. These sites consisted of clusters of A or T residues on one strand but were devoid of either alternating A and T residues or GC-rich sequences. Addition of a complex consisting of Orc1, -2, -3, -5, and -6 proteins (ORC-5) altered neither Orc4p binding to origin DNA nor Orc4p protection of specific sequences. ORC-5 alone bound weakly and nonspecifically to DNA; strong binding required the presence of Orc4p. Under these conditions, all six subunits remained bound to chromatin isolated from each phase of the cell division cycle. These results reveal that the S. pombe ORC binds to multiple, specific sites within replication origins and that site selection, at least in vitro, is determined solely by the Orc4p subunit.

The Schizosaccharomyces pombe origin recognition complex interacts with multiple AT-rich regions of the replication origin DNA by means of the AT-hook domains of the spOrc4 protein

The interaction between an origin sequence and the origin recognition complex (ORC), which is highly conserved in eukaryotes, is critical for the initiation of DNA replication. In this report, we have examined the interaction between the Schizosaccharomyces pombe (sp) autonomously replicating sequence 1 (ars1) and the spORC. For this purpose, we have purified the spORC containing all six subunits, a six-subunit complex containing the N-terminal-deleted spOrc4 subunit (spORC(Delta N-Orc4)), and the spOrc4 subunit by using the baculovirus expression system. Wild-type spORC showed sequence-specific binding to ars1, and the spOrc4 protein alone showed the same DNA-binding properties as wild-type spORC. In contrast, the spORC(Delta N-Orc4) and the Delta N-spOrc4p alone did not bind significantly to ars1. These findings indicate that the N-terminal domain of the spOrc4 protein that contains multiple AT-hook motifs is essential for the ars1-binding activity. DNA-binding competition assays with fragments of ars1 and DNase I footprinting studies with full-length ars1 revealed that the spORC interacted with several AT-rich sequence regions of ars1. These DNA-binding properties of spORC correlate with the previously determined sequence requirements of the S. pombe ars1. These studies indicate that because of its unique Orc4 subunit, S. pombe uses a mechanism to recognize its origins different from that used by Saccharomyces cerevisiae.

Biochemical activities associated with mouse Mcm2 protein

Mcm2, a member of the Mcm2-7 protein family essential for the initiation of DNA replication, has several biochemical activities including the ability to inhibit the Mcm4,6,7 helicase. In this study, we characterized the activities associated with Mcm2 and determined the region required for them. It was found that Mcm2 deleted at an amino-terminal portion is able to bind to an Mcm4,6,7 hexameric complex and to inhibit its DNA helicase activity. The same deletion mutant of Mcm2 and the carboxyl-terminal half of Mcm2 were both able to bind to Mcm4, suggesting that the carboxyl-half of Mcm2 binds to Mcm4 to disassemble the Mcm4,6,7 hexamer. Phosphorylation of Mcm2,4,6,7 complexes with Cdc7 kinase showed that the amino-terminal region of Mcm2 is required for the phosphorylation, and it contains major Cdc7-mediated phosphorylation sites. We also found that Mcm2 itself can assemble a nucleosome-like structure in vitro in the presence of H3/H4 histones. The amino-terminal region of Mcm2 was required for the activity where a histone-binding domain is located. Finally, we identified a region required for the nuclear localization of Mcm2. The function of Mcm2 is discussed based on these biochemical characteristics.

Redundant control of rereplication in fission yeast

The initiation of DNA replication at replication origins in eukaryotic cells is tightly controlled to ensure that the genome is duplicated only once each cell cycle. We present evidence that in fission yeast, independent regulation of two essential components of the initiation complex, Cdc18 and Cdt1, contributes to the prevention of reinitiation of DNA replication. Cdc18 is negatively controlled by cyclin-dependent kinase (CDK) phosphorylation, but low level expression of a mutant form of Cdc18 lacking CDK phosphorylation sites (Cdc18(CDK)) is not sufficient to induce rereplication. Similar to Cdc18, Cdt1 is expressed periodically in the cell cycle, accumulating in the nucleus in G(1) and declining in G(2). When Cdt1 is expressed constitutively from an ectopic promoter, it accumulates in the nucleus throughout the cell cycle but does not promote reinitiation. However, constitutive expression of Cdt1, together with Cdc18(CDK), is sufficient to induce extra rounds of DNA replication in the absence of mitosis. Significantly greater levels of rereplication can be induced by coexpression of Cdc18(CDK) and a Cdt1 mutant lacking a conserved C-terminal motif. In contrast, uncontrolled DNA replication does not occur when either mutant protein is expressed in the absence of the other. Constitutive expression of wild-type or mutant Cdt1 also leads to an increase in the levels of Cdc18(CDK), possibly as a result of increased protein stability. Our data are consistent with the hypothesis that control of rereplication depends on a redundant mechanism in which negative regulation of Cdt1 functions in parallel with the negative regulation of Cdc18.

Interactions between two catalytically distinct MCM subgroups are essential for coordinated ATP hydrolysis and DNA replication

The six MCM (minichromosome maintenance) proteins are essential DNA replication factors that each contain a putative ATP binding motif and together form a heterohexameric complex. We show that these motifs are required for viability in vivo and coordinated ATP hydrolysis in vitro. Mutational analysis discriminates between two functionally distinct MCM protein subgroups: Mcm4p, 6p, and 7p contribute canonical ATP binding motifs essential for catalysis, whereas the related motifs in Mcm2p, 3p, and 5p serve a regulatory function. Reconstitution experiments indicate that specific functional interactions between these two subgroups are required for robust ATP hydrolysis. Our observations show parallels between the MCM complex and the F1-ATPase, and we discuss how ATP hydrolysis by the MCM complex might be coupled to DNA strand separation.

Multiple phosphorylation sites of DNA polymerase alpha-primase cooperate to regulate the initiation of DNA replication in vitro

DNA polymerase alpha-primase (pol-prim) is the only enzyme that can start DNA replication de novo. The 180-kDa (p180) and 68-kDa (p68) subunits of the human four-subunit enzyme are phosphorylated by Cyclin-dependent kinases (Cdks) in a cell cycle-dependent manner. Cyclin A-Cdk2 physically interacts with pol-prim and phosphorylates N-terminal amino acids of the p180 and the p68 subunits, leading to an inhibition of pol-prim in initiating cell-free SV40 DNA replication. Mutation of conserved putative Cdk phosphorylation sites in the N terminus of human p180 and p68 reduced their phosphorylation by Cyclin A-Cdk2 in vitro. In contrast to wild-type pol-prim these mutants were no longer inhibited by Cyclin A-Cdk2 in the initiation of viral DNA replication. Importantly, rather than inhibiting it, Cyclin A-Cdk2 stimulated the initiation activity of pol-prim containing a triple N-terminal alanine mutant of the p180 subunit. Together these results suggest that Cyclin A-Cdk2 executes both stimulatory and inhibitory effects on the activity of pol-prim in initiating DNA replication.

Functional analysis of mutant and wild-type Drosophila origin recognition complex

The origin recognition complex (ORC) is the DNA replication initiator protein in eukaryotes. We have reconstituted a functional recombinant Drosophila ORC and compared activities of the wild-type and several mutant ORC variants. Drosophila ORC is an ATPase, and our studies show that the ORC1 subunit is essential for ATP hydrolysis and for ATP-dependent DNA binding. Moreover, DNA binding by ORC reduces its ATP hydrolysis activity. In vitro, ORC binds to chromatin in an ATP-dependent manner, and this process depends on the functional AAA(+) nucleotide-binding domain of ORC1. Mutations in the ATP-binding domain of ORC1 are unable to support cell-free DNA replication. However, mutations in the putative ATP-binding domain of either the ORC4 or ORC5 subunits do not affect either of these functions. We also provide evidence that the Drosophila ORC6 subunit is directly required for all of these activities and that a large pool of ORC6 is present in the cytoplasm, cytologically proximal to the cell membrane. Studies reported here provide the first functional dissection of a metazoan initiator and highlight the basic conserved and divergent features among Drosophila and budding yeast ORC complexes.

Making sense of eukaryotic DNA replication origins

DNA replication is the process by which cells make one complete copy of their genetic information before cell division. In bacteria, readily identifiable DNA sequences constitute the start sites or origins of DNA replication. In eukaryotes, replication origins have been difficult to identify. In some systems, any DNA sequence can promote replication, but other systems require specific DNA sequences. Despite these disparities, the proteins that regulate replication are highly conserved from yeast to humans. The resolution may lie in a current model for once-per-cell-cycle regulation of eukaryotic replication that does not require defined origin sequences. This model implies that the specification of precise origins is a response to selective pressures that transcend those of once-per-cell-cycle replication, such as the coordination of replication with other chromosomal functions. Viewed in this context, the locations of origins may be an integral part of the functional organization of eukaryotic chromosomes.

Characterization of Schizosaccharomyces pombe mcm7(+) and cdc23(+) (MCM10) and interactions with replication checkpoints

MCM proteins are required for the proper regulation of DNA replication. We cloned fission yeast mcm7(+) and showed it is essential for viability; spores lacking mcm7(+) begin S phase later than wild-type cells and arrest with an apparent 2C DNA content. We isolated a novel temperature-sensitive allele, mcm7-98, and also characterized two temperature-sensitive alleles of the fission yeast homolog of MCM10, cdc23(+). mcm7-98 and both cdc23ts alleles arrest with damaged chromosomes and an S phase delay. We find that mcm7-98 is synthetically lethal with the other mcmts mutants but does not interact genetically with either cdc23ts allele. However, cdc23-M36 interacts with mcm4ts. Unlike other mcm mutants or cdc23, mcm7-98 is synthetically lethal with checkpoint mutants Deltacds1, Deltachk1, or Deltarad3, suggesting chromosomal defects even at permissive temperature. Mcm7p is a nuclear protein throughout the cell cycle, and its localization is dependent on the other MCM proteins. Our data suggest that the Mcm3p-Mcm5p dimer interacts with the Mcm4p-Mcm6p-Mcm7p core complex through Mcm7p.

In vivo interactions of archaeal Cdc6/Orc1 and minichromosome maintenance proteins with the replication origin

Although genome analyses have suggested parallels between archaeal and eukaryotic replication systems, little is known about the DNA replication mechanism in Archaea. By two-dimensional gel electrophoreses we positioned a replication origin (oriC) within 1 kb in the chromosomal DNA of Pyrococcus abyssi, an anaerobic hyperthermophile, and demonstrated that the oriC is physically linked to the cdc6 gene. Our chromatin immunoprecipitation assays indicated that P. abyssi Cdc6 and minichromosome maintenance (MCM) proteins bind preferentially to the oriC region in the exponentially growing cells. Whereas the oriC association of MCM was specifically inhibited by stopping DNA replication with puromycin treatment, Cdc6 protein stayed bound to the replication origin after de novo protein synthesis was inhibited. Our data suggest that archaeal and eukaryotic Cdc6 and MCM proteins function similarly in replication initiation and imply that an oriC association of MCM could be regulated by an unknown mechanism in Archaea.

Phosphorylation of Mcm4 at specific sites by cyclin-dependent kinase leads to loss of Mcm4,6,7 helicase activity

Mcm proteins that play an essential role in eukaryotic DNA replication are phosphorylated in vivo, and cyclin-dependent protein kinase is at least in part responsible for the phosphorylation of Mcm4. Our group reported that the DNA helicase activity of Mcm4,6,7 complex, which may be involved in initiation of DNA replication, is inhibited following phosphorylation by Cdk2/cyclin A in vitro. Here, we further examined the interplay between mouse Mcm4,6,7 complex and cyclin-dependent kinases and determined the sites required for the phosphorylation of Mcm4. Six Ser and Thr residues, in all, were required for the phosphorylation. Inhibition of Mcm4,6,7 helicase activity by Cdk2/cyclin A was largely relieved by introducing mutations in these residues of Mcm4. Anti-phosphothreonine antibodies raised against one of these sites reacted with Mcm4 prepared from HeLa cells at mitotic phase but did not bind to those at G(1) and G(1)/S, suggesting that this site is mainly phosphorylated in the mitotic phase. Mcm4,6,7 complex purified from HeLa cells at the mitotic phase exhibited a low level of DNA helicase activity, compared with the complexes prepared from cells at other phases. These results suggest that phosphorylation of Mcm4 at specific sites leads to loss of Mcm4,6,7 DNA helicase activity.

Autophosphorylation of archaeal Cdc6 homologues is regulated by DNA

The initiator protein Cdc6 (Cdc18 in fission yeast) plays an essential role in the initiation of eukaryotic DNA replication. In yeast the protein is expressed before initiation of DNA replication and is thought to be essential for loading of the helicase onto origin DNA. The biochemical properties of the protein, however, are largely unknown. Using three archaeal homologues of Cdc6, it was found that the proteins are autophosphorylated on Ser residues. The winged-helix domain at the C terminus of Cdc6 interacts with DNA, which apparently regulates the autophosphorylation reaction. Yeast Cdc18 was also found to autophosphorylate, suggesting that this function of Cdc6 may play a widely conserved and essential role in replication initiation.

Human origin recognition complex binds to the region of the latent origin of DNA replication of Epstein-Barr virus

Epstein-Barr virus (EBV) replicates in its latent phase once per cell cycle in proliferating B cells. The latent origin of DNA replication, oriP, supports replication and stable maintenance of the EBV genome. OriP comprises two essential elements: the dyad symmetry (DS) and the family of repeats (FR), both containing clusters of binding sites for the transactivator EBNA1. The DS element appears to be the functional replicator. It is not yet understood how oriP-dependent replication is integrated into the cell cycle and how EBNA1 acts at the molecular level. Using chromatin immunoprecipitation experiments, we show that the human origin recognition complex (hsORC) binds at or near the DS element. The association of hsORC with oriP depends on the DS element. Deletion of this element not only abolishes hsORC binding but also reduces replication initiation at oriP to background level. Co-immunoprecipitation experiments indicate that EBNA1 is associated with hsORC in vivo. These results indicate that oriP might use the same cellular initiation factors that regulate chromosomal replication, and that EBNA1 may be involved in recruiting hsORC to oriP.

Architecture of the human origin recognition complex

All the human homologs of the six subunits of Saccharomyces cerevisiae origin recognition complex have been reported so far. However, not much has been reported on the nature and the characteristics of the human origin recognition complex. In an attempt to purify recombinant human ORC from insect cells infected with baculoviruses expressing HsORC subunits, we found that human ORC2, -3, -4, and -5 form a core complex. HsORC1 and HsORC6 subunits did not enter into this core complex, suggesting that the interaction of these two subunits with the core ORC2-5 complex is extremely labile. We found that the C-terminal region of ORC2 interacts directly with the N-terminal region of ORC3. The C-terminal region of ORC3 was, however, necessary to bring ORC4 and ORC5 into the core complex. A fragment containing the N-terminal 200 residues of ORC3 (ORC3N) competitively inhibited the ORC2-ORC3 interaction. Overexpression of this fragment in U2OS cells blocked the cells in G(1), providing the first evidence that a mammalian ORC subunit is important for the G(1)-S transition in mammalian cells.

DNA replication origins: from sequence specificity to epigenetics

Site-specific initiation of DNA replication is a conserved function in all organisms. In Escherichia coli and Saccharomyces cerevisiae, DNA replication origins are sequence specific, but in multicellular organisms, origins are not so clearly defined. In this article, I present a model of origin specification by epigenetic mechanisms that allows the establishment of stable chromatin domains, which are characterized by autonomous replication. According to this model, origins of DNA replication help to establish domains of gene expression for the generation of cell diversity.

DNA replication forks pause at silent origins near the HML locus in budding yeast

Chromosomal replicators in budding yeast contain an autonomously replicating sequence (ARS) that functions in a plasmid, but certain ARSs are silent as replication origins in their natural chromosomal context. In chromosome III, the HML ARS cluster (ARS302-ARS303-ARS320) and ARS301 flank the transcriptionally silent mating-type locus HML, and all of these ARSs are silent as replication origins. ARS301 and ARS302 function in transcriptional silencing mediated by the origin recognition complex (ORC) and a heterochromatin structure, while the functions of ARS303 and ARS320 are not known. In this work, we discovered replication fork pause sites at the HML ARS cluster and ARS301 by analyzing DNA replication intermediates from the chromosome via two-dimensional gel electrophoresis. The replication fork pause at the HML ARS cluster was independent of cis- and trans-acting mutations that abrogate transcriptional silencing at HML. Deletion of the HML ARS cluster led to loss of the pause site. Insertion of a single, heterologous ARS (ARS305) in place of the HML ARS cluster reconstituted the pause site, as did multiple copies of DNA elements (A and B1) that bind ORC. The orc2-1 mutation, known to alter replication timing at origins, did not detectably affect the pause but activated the silent origin at the HML ARS cluster in a minority of cells. Delaying the time of fork arrival at HML led to the elimination of the pause sites at the HML ARS cluster and at the copy of ARS305 inserted in place of the cluster. Loss of the pause sites was accompanied by activation of the silent origins in the majority of cells. Thus, replication fork movement near HML pauses at a silent origin which is competent for replication initiation but kept silent through Orc2p, a component of the replication initiator. Possible functions for replication fork pause sites in checkpoints, S-phase regulation, mating-type switching, and transcriptionally silent heterochromatin are discussed.

ATP bound to the origin recognition complex is important for preRC formation

The origin recognition complex (ORC) binds origins of replication and directs the assembly of a higher order protein complex at these sites. ORC binds and hydrolyzes ATP in vitro. ATP binding to the largest subunit of ORC, Orc1p, stimulates specific binding to origin DNA; however, the function of ATP hydrolysis by ORC is unknown. To address the role of ATP hydrolysis, we have generated mutants within Orc1p that are dominant lethal. At physiological ATP concentrations, these mutants are defective for ATP hydrolysis but not ATP binding in the absence of DNA. These mutants inhibit formation of the prereplicative complex when overexpressed. The dominant lethal phenotype of these mutant ORC complexes is suppressed by simultaneous overexpression of wild-type, but not mutant, Cdc6p. Our findings suggest that these hydrolysis-defective mutants inhibit growth by titrating Cdc6p away from the origin. Based on these observations, we propose that Cdc6p specifically recognizes the ATP-bound state of Orc1p and that ATP hydrolysis is coupled to preRC disassembly.

Assembly of the human origin recognition complex

The six-subunit origin recognition complex (ORC) was originally identified in the yeast Saccharomyces cerevisiae. Yeast ORC binds specifically to origins of replication and serves as a platform for the assembly of additional initiation factors, such as Cdc6 and the Mcm proteins. Human homologues of all six ORC subunits have been identified by sequence similarity to their yeast counterparts, but little is known about the biochemical characteristics of human ORC (HsORC). We have extracted HsORC from HeLa cell chromatin and probed its subunit composition using specific antibodies. The endogenous HsORC, identified in these experiments, contained homologues of Orc1-Orc5 but lacked a putative homologue of Orc6. By expressing HsORC subunits in insect cells using the baculovirus system, we were able to identify a complex containing all six subunits. To explore the subunit-subunit interactions that are required for the assembly of HsORC, we carried out extensive co-immunoprecipitation experiments with recombinant ORC subunits expressed in different combinations. These studies revealed the following binary interactions: HsOrc2-HsOrc3, HsOrc2-HsOrc4, HsOrc3-HsOrc4, HsOrc2-HsOrc6, and HsOrc3-HsOrc6. HsOrc5 did not form stable binary complexes with any other HsORC subunit but interacted with sub-complexes containing any two of subunits HsOrc2, HsOrc3, or HsOrc4. Complex formation by HsOrc1 required the presence of HsOrc2, HsOrc3, HsOrc4, and HsOrc5 subunits. These results suggest that the subunits HsOrc2, HsOrc3, and HsOrc4 form a core upon which the ordered assembly of HsOrc5 and HsOrc1 takes place. The characterization of HsORC should facilitate the identification of human origins of DNA replication.

AAA+ superfamily ATPases: common structure--diverse function

The AAA+ superfamily of ATPases, which contain a homologous ATPase module, are found in all kingdoms of living organisms where they participate in diverse cellular processes including membrane fusion, proteolysis and DNA replication. Recent structural studies have revealed that they usually form ring-shaped oligomers, which are crucial for their ATPase activities and mechanisms of action. These ring-shaped oligomeric complexes are versatile in their mode of action, which collectively seem to involve some form of disruption of molecular or macromolecular structure; unfolding of proteins, disassembly of protein complexes, unwinding of DNA, or alteration of the state of DNA-protein complexes. Thus, the AAA+ proteins represent a novel type of molecular chaperone. Comparative analyses have also revealed significant similarities and differences in structure and molecular mechanism between AAA+ ATPases and other ring-shaped ATPases.

Cyclin-dependent kinases prevent DNA re-replication through multiple mechanisms

The stable propagation of genetic information requires that the entire genome of an organism be faithfully replicated once and only once each cell cycle. In eukaryotes, this replication is initiated at hundreds to thousands of replication origins distributed over the genome, each of which must be prohibited from re-initiating DNA replication within every cell cycle. How cells prevent re-initiation has been a long-standing question in cell biology. In several eukaryotes, cyclin-dependent kinases (CDKs) have been implicated in promoting the block to re-initiation, but exactly how they perform this function is unclear. Here we show that B-type CDKs in Saccharomyces cerevisiae prevent re-initiation through multiple overlapping mechanisms, including phosphorylation of the origin recognition complex (ORC), downregulation of Cdc6 activity, and nuclear exclusion of the Mcm2-7 complex. Only when all three inhibitory pathways are disrupted do origins re-initiate DNA replication in G2/M cells. These studies show that each of these three independent mechanisms of regulation is functionally important.

Aphidicolin triggers a block to replication origin firing in Xenopus egg extracts

DNA replication origins are located at random with respect to DNA sequence in Xenopus early embryos and on DNA replicated in Xenopus egg extracts. We have recently shown that origins fire throughout the S phase in Xenopus egg extracts. To study the temporal regulation of origin firing, we have analyzed origin activation in sperm nuclei treated with the DNA polymerase inhibitor aphidicolin. Sperm chromatin was incubated in Xenopus egg extracts in the presence of aphidicolin and transferred to a fresh extract, and digoxigenin-dUTP and biotin-dUTP were added at various times after aphidicolin release to selectively label early and late replicating DNA. Molecular combing analysis of single DNA fibers showed that only a fraction of potential origins were able to initiate in the presence of aphidicolin. After release from aphidicolin, the remaining origins fired asynchronously throughout the S phase. Therefore, initiation during the S phase depends on the normal progression of replication forks assembled at earlier activated origins. Caffeine, an inhibitor of the checkpoint kinases ATR and ATM, did not relieve the aphidicolin-induced block to origin firing. We conclude that a caffeine-insensitive intra-S phase checkpoint regulates origin activation when DNA synthesis is inhibited in Xenopus egg extracts.

Replication checkpoint: preventing mitotic catastrophe

A conserved network of signal transduction pathways prevents mitosis if DNA is damaged or its synthesis incomplete. Loss of this checkpoint control is detrimental to the developing embryo. Recent studies have shed new light on how the essential ATR and Chk1 protein kinases cooperate to prevent such a crisis.

Nucleosomes positioned by ORC facilitate the initiation of DNA replication

The packaging of eukaryotic DNA into nucleosomes is a critical regulator of nuclear events. To address the interplay between chromatin and replication initiation, we have assessed the determinants and function of the nucleosomal configuration of S. cerevisiae replication origins. Using in vitro and in vivo assays, we demonstrate that the yeast initiator, the origin recognition complex (ORC), is required to maintain the nucleosomal configuration adjacent to origins. Disruption of the ORC-directed nucleosomal arrangement at an origin interferes with initiation of replication, but does not alter the association of ORC with the origin. Instead, the nucleosomes positioned by ORC are important for prereplicative complex formation. These findings suggest that origin-proximal nucleosomes facilitate replication initiation, and that local chromatin structure affects origin function.

Genome-wide location and function of DNA binding proteins

Understanding how DNA binding proteins control global gene expression and chromosomal maintenance requires knowledge of the chromosomal locations at which these proteins function in vivo. We developed a microarray method that reveals the genome-wide location of DNA-bound proteins and used this method to monitor binding of gene-specific transcription activators in yeast. A combination of location and expression profiles was used to identify genes whose expression is directly controlled by Gal4 and Ste12 as cells respond to changes in carbon source and mating pheromone, respectively. The results identify pathways that are coordinately regulated by each of the two activators and reveal previously unknown functions for Gal4 and Ste12. Genome-wide location analysis will facilitate investigation of gene regulatory networks, gene function, and genome maintenance.

Xenopus ATR is a replication-dependent chromatin-binding protein required for the DNA replication checkpoint

BACKGROUND

The DNA replication checkpoint ensures that mitosis is not initiated before DNA synthesis is completed. Recent studies using Xenopus extracts have demonstrated that activation of the replication checkpoint and phosphorylation of the Chk1 kinase are dependent on RNA primer synthesis by DNA polymerase alpha, and it has been suggested that the ATR kinase-so-called because it is related to the product of the gene that is mutated in ataxia telangiectasia (ATM) and to Rad3 kinase-may be an upstream component of this response. It has been difficult to test this hypothesis as an ATR-deficient system suitable for biochemical studies has not been available.

RESULTS

We have cloned the Xenopus laevis homolog of ATR (XATR) and studied the function of the protein in Xenopus egg extracts. Using a chromatin-binding assay, we found that ATR associates with chromatin after initiation of replication, dissociates from chromatin upon completion of replication, and accumulates in the presence of aphidicolin, an inhibitor of DNA replication. Its association with chromatin was inhibited by treatment with actinomycin D, an inhibitor of RNA primase. There was an early rise in the activity of Cdc2-cyclin B in egg extracts depleted of ATR both in the presence or absence of aphidicolin. In addition, the premature mitosis observed upon depletion of ATR was accompanied by the loss of Chk1 phosphorylation.

CONCLUSIONS

ATR is a replication-dependent chromatin-binding protein, and its association with chromatin is dependent on RNA synthesis by DNA polymerase alpha. Depletion of ATR leads to premature mitosis in the presence and absence of aphidicolin, indicating that ATR is required for the DNA replication checkpoint.