Changes in association of the Xenopus origin recognition complex with chromatin on licensing of replication origins

Identification of a binding region for human origin recognition complex proteins 1 and 2 that coincides with an origin of DNA replication

We investigated the binding regions of components of the origin recognition complex (ORC) in the human genome. For this purpose, we performed chromatin immunoprecipitation assays with antibodies against human Orc1 and Orc2 proteins. We identified a binding region for human Orc proteins 1 and 2 in a <1-kbp segment between two divergently transcribed human genes. The region is characterized by CpG tracts and a central sequence rich in AT base pairs. Both, Orc1 and Orc2 proteins are found at the intergenic region in the G(1) phase, but S-phase chromatin contains only Orc2 protein, supporting the notion that Orc1p dissociates from its binding site in the S phase. Sequences corresponding to the intergenic region are highly abundant in a fraction of nascent DNA strands, strongly suggesting that this region not only harbors the binding sites for Orc1 protein and Orc2 protein but also serves as an origin of bidirectional DNA replication.

Replication licensing--defining the proliferative state?

The proliferation of eukaryotic cells is a highly regulated process that depends on the precise duplication of chromosomal DNA in each cell cycle. Regulation of the replication licensing system, which promotes the assembly of complexes of proteins termed Mcm2-7 onto replication origins, is responsible for preventing re-replication of DNA in a single cell cycle. Recent work has shown how the licensing system is directly controlled by cyclin-dependent kinases (CDKs). Repression of origin licensing is emerging as a ubiquitous route by which the proliferative capacity of cells is lowered, and Mcm2-Mcm7 proteins show promise as diagnostic markers of early cancer stages. These results have prompted us to propose a functional distinction between the proliferative state and the non-proliferative state (including G0) depending on whether origins are licensed.

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.

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.

Cell cycle-dependent proteolysis and phosphorylation of human Mcm10

Mcm10 (Dna43) is an essential protein for chromosomal DNA replication in Saccharomyces cerevisiae. Recently, we identified a human Mcm10 homolog that interacts with the mammalian Orc2 and Mcm2-7 complex. We additionally demonstrated that human Mcm10 binds nuclease-resistant nuclear structures during S phase and dissociates from them in G(2) phase. In this study, we have further characterized the subcellular localization, modification, and expression levels of human Mcm10 protein throughout the cell cycle. Human Mcm10 protein decreased in late M phase, remained low during G(1) phase, started to accumulate, and bound chromatin at the onset of S phase. Proteasome inhibitors stabilized Mcm10 levels, suggesting that proteolysis is involved in the down-regulation of the protein in late M/G(1) phase. Dissociation of Mcm10 from chromatin in G(2)/M phase was concomitant with alterations in the electrophoretic mobility of the protein. Treatment with lambda phosphatase revealed that mobility shifts were due to hyperphosphorylation. These results indicate that human Mcm10 is regulated by proteolysis and phosphorylation in a cell cycle-dependent manner. It is further suggested that mammalian Mcm10 is involved in S phase progression, and not the formation of a prereplicative complex, as previously proposed from data on the S. cerevisiae protein.

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.

Mutational analysis of conserved sequence motifs in the budding yeast cdc6 protein 1 1Edited by M. Yaniv

The Cdc6 protein is required to load a complex of Mcm2-7 family members (the MCM complex) into prereplicative complexes at budding yeast origins of DNA replication. Cdc6p is a member of the AAA(+) superfamily of proteins, which includes the prokaryotic and eukaryotic clamp loading proteins. These proteins share a number of conserved regions of homology and a common three-dimensional architecture. Two of the conserved sequence motifs are the Walker A and B motifs that are involved in nucleotide metabolism and are essential for Cdc6p function in vivo. Here, we analyse mutants in the other conserved sequence motifs. Several of these mutants are temperature-sensitive for growth and are unable to recruit the MCM complex to chromatin at the restrictive temperature. In one such temperature-sensitive mutant, a highly conserved asparagine residue in the sensor I motif was changed to alanine. Overexpression of this mutant protein is lethal. This phenotype is very similar to the phenotype previously described for a mutation in the Walker B motif, suggesting a common role for sensor I and the Walker B motif in Cdc6 function.

Initiating DNA synthesis: from recruiting to activating the MCM complex

The exact duplication of a genome once per cell division is required of every proliferating cell. To achieve this goal, eukaryotes adopt a strategy that limits every replication origin to a single initiation event within a narrow window of the cell cycle by temporally separating the assembly of the pre-replication complex (pre-RC) from the initiation of DNA synthesis. A key component of the pre-RC is the hexameric MCM complex, which is also the presumed helicase of the growing forks. An elaborate mechanism recruits the MCM complex to replication origins, and a regulatory chain reaction converts the poised, but inactive, MCM complex into an enzymatically active helicase. A growing list of proteins, including Mcm10 and Cdt1, are involved in the recruitment process. Two protein kinases, the Cdc7-Dbf4 kinase (DDK) and the cyclin-dependent kinase (CDK), trigger a chain reaction that results in the phosphorylation of the MCM complex and finally in the initiation of DNA synthesis. A composite picture from recent studies suggests that DDK is recruited to the pre-RC during G(1) phase but must wait until S phase to phosphorylate the MCM complex. CDK is required for the recruitment of Cdc45 and other downstream components of the elongation machinery.

The human origin recognition complex protein 1 dissociates from chromatin during S phase in HeLa cells

We investigated the association of human origin recognition complex (ORC) proteins hOrc1p and hOrc2p with chromatin in HeLa cells. Independent procedures including limited nuclease digestion and differential salt extraction of isolated nuclei showed that a complex containing hOrc1p and hOrc2p occurs in a nuclease-resistant compartment of chromatin and can be eluted with moderate high salt concentrations. A second fraction of hOrc2p that dissociates in vitro at low salt conditions was found to occur in a chromatin compartment characterized by its high accessibility to micrococcal nuclease. Functional differences between these two sites become apparent in HeLa cells that synchronously enter the S phase after a release from a double-thymidine block. The hOrc1p/hOrc2p-containing complexes dissociate from their chromatin sites during S phase and reassociate at the end of mitosis. In contrast, the fraction of hOrc2p in nuclease-accessible, more open chromatin remains bound during all phases of the cell cycle. We propose that the hOrc1p/hOrc2p-containing complexes are components of the human origin recognition complex. Thus, the observed cell cycle-dependent release of the hOrc1p/hOrc2p-containing complexes is in line with previous studies with Xenopus and Drosophila systems, which indicated that a change in ORC stability occurs after prereplication complex formation. This could be a powerful mechanism that prevents the rereplication of already replicated chromatin in the metazoan cell cycle.

Regulation of chromosome replication

The initiation of DNA replication in eukaryotic cells is tightly controlled to ensure that the genome is faithfully duplicated once each cell cycle. Genetic and biochemical studies in several model systems indicate that initiation is mediated by a common set of proteins, present in all eukaryotic species, and that the activities of these proteins are regulated during the cell cycle by specific protein kinases. Here we review the properties of the initiation proteins, their interactions with each other, and with origins of DNA replication. We also describe recent advances in understanding how the regulatory protein kinases control the progress of the initiation reaction. Finally, we describe the checkpoint mechanisms that function to preserve the integrity of the genome when the normal course of genome duplication is perturbed by factors that damage the DNA or inhibit DNA synthesis.

Where it all starts: eukaryotic origins of DNA replication

Chromosomal origins of DNA replication in eukaryotic cells not only are crucial for understanding the basic process of DNA duplication but also provide a tool to analyze how cell cycle regulators are linked to the replication machinery. During the past decade much progress has been made in identifying replication origins in eukaryotic genomes. More recently, replication initiation point (RIP) mapping has allowed us to detect start sites for DNA synthesis at the nucleotide level and thus to monitor replication initiation events at the origin very precisely. Beyond giving us the precise positions of start sites, the application of RIP mapping in yeast and human cells has revealed a single, defined start point at which replication initiates, a scenario very reminiscent of transcription initiation. More importantly, studies in yeast have shown that the binding site for the initiator, the origin recognition complex (ORC), lies immediately adjacent to the replication start point, which suggests that ORC directs the initiation machinery to a distinct site. Therefore, in our pursuit of identifying ORC-binding sites in higher eukaryotes, RIP mapping may lead the way.

Repression of origin assembly in metaphase depends on inhibition of RLF-B/Cdt1 by geminin

Eukaryotic replication origins are 'licensed' for replication early in the cell cycle by loading Mcm(2-7) proteins. As chromatin replicates, Mcm(2-7) are removed, thus preventing the origin from firing again. Here we report the purification of the RLF-B component of the licensing system and show that it corresponds to Cdt1. RLF-B/Cdt1 was inhibited by geminin, a protein that is degraded during late mitosis. Immunodepletion of geminin from metaphase extracts allowed them to assemble licensed replication origins. Inhibition of CDKs in metaphase stimulated origin assembly only after the depletion of geminin. These experiments suggest that geminin-mediated inhibition of RLF-B/Cdt1 is essential for repressing origin assembly late in the cell cycle of higher eukaryotes.

Replication origins in Xenopus egg extract Are 5-15 kilobases apart and are activated in clusters that fire at different times

When Xenopus eggs and egg extracts replicate DNA, replication origins are positioned randomly with respect to DNA sequence. However, a completely random distribution of origins would generate some unacceptably large interorigin distances. We have investigated the distribution of replication origins in Xenopus sperm nuclei replicating in Xenopus egg extract. Replicating DNA was labeled with [(3)H]thymidine or bromodeoxyuridine and the geometry of labeled sites on spread DNA was examined. Most origins were spaced 5-15 kb apart. This regular distribution provides an explanation for how complete chromosome replication can be ensured although origins are positioned randomly with respect to DNA sequence. Origins were grouped into small clusters (typically containing 5-10 replicons) that fired at approximately the same time, with different clusters being activated at different times in S phase. This suggests that a temporal program of origin firing similar to that seen in somatic cells also exists in the Xenopus embryo. When the quantity of origin recognition complexes (ORCs) on the chromatin was restricted, the average interorigin distance increased, and the number of origins in each cluster decreased. This suggests that the binding of ORCs to chromatin determines the regular spacing of origins in this system.

Evidence for sequential action of cdc7 and cdk2 protein kinases during initiation of DNA replication in Xenopus egg extracts

To investigate how the protein kinase cdc7 stimulates DNA replication in metazoans, a soluble cell-free replication system derived from Xenopus eggs was used. DNA was incubated in egg cytosol to form prereplication complexes and then in nucleoplasmic extract to initiate DNA synthesis. We find that cdc7 is greatly enriched in nucleoplasmic extract and that this high concentration is essential for efficient DNA replication, supporting previous models that the nucleus activates replication indirectly by sequestering essential components. cdc7 binds to chromatin at the G(1)/S transition before initiation occurs, and it dissociates from chromatin as S phase progresses. The chromatin association of cdc7 requires chromatin-bound MCM. In turn, cdc7 is required to load the initiation factor cdc45 onto the DNA. Finally, efficient replication is observed when chromatin is exposed first to cdc7 and then to cdk2 but not when it is exposed to cdk2 before cdc7. Therefore, the cdc7- and cdk2-dependent initiation steps can be separated, indicating the existence of a novel, stable initiation intermediate. Moreover, the data suggest that cdk2 can only act after cdc7 has executed its function.

Aberrant replication timing induces defective chromosome condensation in Drosophila ORC2 mutants

BACKGROUND

The accurate duplication and packaging of the genome is an absolute prerequisite to the segregation of chromosomes in mitosis. To understand the process of cell-cycle chromosome dynamics further, we have performed the first detailed characterization of a mutation affecting mitotic chromosome condensation in a metazoan. Our combined genetic and cytological approaches in Drosophila complement and extend existing work employing yeast genetics and Xenopus in vitro extract systems to characterize higher-order chromosome structure and function.

RESULTS

Two alleles of the ORC2 gene were found to cause death late in larval development, with defects in cell-cycle progression (delays in S-phase entry and metaphase exit) and chromosome condensation in mitosis. During S-phase progression in wild-type cells, euchromatin replicates early and heterochromatin replicates late. Both alleles disrupted the normal pattern of chromosomal replication, with some euchromatic regions replicating even later than heterochromatin. Mitotic chromosomes were irregularly condensed, with the abnormally late replicating regions of euchromatin exhibiting the greatest problems in mitotic condensation.

CONCLUSIONS

The results not only reveal novel functions for ORC2 in chromosome architecture in metazoans, they also suggest that the correct timing of DNA replication may be essential for the assembly of chromatin that is fully competent to undergo mitotic condensation.

Eukaryotic DNA replication: from pre-replication complex to initiation complex

A common mechanism has emerged for the control of the initiation of eukaryotic DNA replication. The minichromosome maintenance protein complex (MCM) and Cdc45 have now been recognized as central components of the initiation machinery. In addition, two types of S phase promoting kinases conserved between yeast and humans play critical roles in the initiation reaction. At the onset of S phase, S phase kinases promote the association of Cdc45 with MCM at origins. Upon the formation of the MCM-Cdc45 complex at origins, the duplex DNA is unwound and various replication proteins, including DNA polymerases, are recruited onto unwound DNA. The increasing number of newly identified factors involved in the initiation reaction indicates that the control of initiation requires highly evolved machinery in eukaryotic cells.

Induction of DNA replication in the germinal vesicle of the growing mouse oocyte

Growing mouse oocytes are physiologically arrested in the G2 phase of prophase of the first meiotic division. Growing oocytes were isolated from ovaries of 9- to 12-day-old mice and fused with parthenogenetic one-cell eggs or two-cell embryos derived from fertilized eggs. Resulting hybrids were injected with Dig-11-dUTP and examined for DNA replication using immunofluorescence. Parthenogenetic one-cell eggs fused at telophase II, G1, and middle-to-late S phase, and also S-phase two-cell blastomeres, were able to trigger DNA synthesis in oocyte germinal vesicle (GV) in the majority of hybrids cultured to the end of the first cell cycle. Activation of replication in the GV occurred within 2-3 h after fusion of growing oocytes with S-phase eggs. We show indirectly that the reactivation of replication in GVs was not dependent on the breakdown of the GV envelope. Although GVs had the ability to renew DNA replication after fusion, the G2 blastomere nuclei were incapable of reinitiating DNA replication under the influence of S-phase one-cell eggs. We hypothesize that the nuclei of growing oocytes arrested in meiotic prophase are in a physiological state that is equivalent to replication-competent G1, and not G2, nuclei.

Xenopus Cdc7 function is dependent on licensing but not on XORC, XCdc6, or CDK activity and is required for XCdc45 loading

The assembly and disassembly of protein complexes at replication origins play a crucial role in the regulation of chromosomal DNA replication. The sequential binding of the origin recognition complex (ORC), Cdc6, and the minichromosome maintenance (MCM/P1) proteins produces a licensed replication origin. Before the initiation of replication can occur, each licensed origin must be acted upon by S phase-inducing CDKs and the Cdc7 protein kinase. In the present report we describe the role of Xenopus Cdc7 (XCdc7) in DNA replication using cell-free extracts of Xenopus eggs. We show that XCdc7 binds to chromatin during G1 and S phase. XCdc7 associates with chromatin only once origins have been licensed, but this association does not require the continued presence of XORC or XCdc6 once they have fulfilled their essential role in licensing. Moreover, XCdc7 is required for the subsequent CDK-dependent loading of XCdc45 but is not required for the destabilization of origins that occurs once licensing is complete. Finally, we show that CDK activity is not necessary for XCdc7 to associate with chromatin, induce MCM/P1 phosphorylation, or perform its essential replicative function. From these results we suggest a simple model for the assembly of functional initiation complexes in the Xenopus system.

Xenopus cdc7 function is dependent on licensing but not on XORC, XCdc6, or CDK activity and is required for XCdc45 loading

The assembly and disassembly of protein complexes at replication origins play a crucial role in the regulation of chromosomal DNA replication. The sequential binding of the origin recognition complex (ORC), Cdc6, and the minichromosome maintenance (MCM/P1) proteins produces a licensed replication origin. Before the initiation of replication can occur, each licensed origin must be acted upon by S phase-inducing CDKs and the Cdc7 protein kinase. In the present report we describe the role of Xenopus Cdc7 (XCdc7) in DNA replication using cell-free extracts of Xenopus eggs. We show that XCdc7 binds to chromatin during G(1) and S phase. XCdc7 associates with chromatin only once origins have been licensed, but this association does not require the continued presence of XORC or XCdc6 once they have fulfilled their essential role in licensing. Moreover, XCdc7 is required for the subsequent CDK-dependent loading of XCdc45 but is not required for the destabilization of origins that occurs once licensing is complete. Finally, we show that CDK activity is not necessary for XCdc7 to associate with chromatin, induce MCM/P1 phosphorylation, or perform its essential replicative function. From these results we suggest a simple model for the assembly of functional initiation complexes in the Xenopus system.

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.

Review: nuclear structure and DNA replication

DNA replication is a highly conserved process among eukaryotes where it occurs within a unique organelle-the nucleus. The importance of this structure is indicated by the fact that assembly of prereplication complexes on cellular chromatin is delayed until mitosis is completed and a nuclear structure has formed. Although nuclear structure is dispensable for DNA replication in vitro, it does appear to play a role in vivo by regulating the concentration of proteins required to initiate DNA replication, by facilitating the assembly or activity of DNA replication forks, and by determining where in the genome initiation of DNA replication occurs.

Initiation of eukaryotic DNA replication: origin unwinding and sequential chromatin association of Cdc45, RPA, and DNA polymerase alpha

We report that a plasmid replicating in Xenopus egg extracts becomes negatively supercoiled during replication initiation. Supercoiling requires the initiation factor Cdc45, as well as the single-stranded DNA-binding protein RPA, and therefore likely represents origin unwinding. When unwinding is prevented, Cdc45 binds to chromatin whereas DNA polymerase alpha does not, indicating that Cdc45, RPA, and DNA polymerase alpha bind chromatin sequentially at the G1/S transition. Whereas the extent of origin unwinding is normally limited, it increases dramatically when DNA polymerase alpha is inhibited, indicating that the helicase that unwinds DNA during initiation can become uncoupled from the replication fork. We discuss the implications of these results for the location of replication start sites relative to the prereplication complex.

Think global, act local--how to regulate S phase from individual replication origins

All eukaryotes use similar proteins to licence replication origins but, paradoxically, origin DNA is much less conserved. Specific binding sites for these proteins have now been identified on fission yeast and Drosophila chromosomes, suggesting that the DNA-binding activity of the origin recognition complex has diverged to recruit conserved initiation factors on polymorphic replication origins. Once formed, competent origins are activated by cyclin- and Dbf4-dependent kinases. The latter have been shown to control S phase in several organisms but, in contrast to cyclin-dependent kinases, seem regulated at the level of individual origins. Global and local regulations generate specific patterns of DNA replication that help establish epigenetic chromosome states.

Sequential MCM/P1 subcomplex assembly is required to form a heterohexamer with replication licensing activity

Replication licensing factor (RLF) is a multiprotein complex involved in ensuring that chromosomal DNA replicates only once in a single cell cycle. It comprises two components, termed RLF-M and RLF-B. Purified RLF-M consists of a mixture of complexes containing all six members of the MCM/P1 family of minichromosome maintenance proteins. The precise composition of these different complexes and their contribution to RLF-M activity has been unclear. Here we show that in Xenopus extracts, MCM/P1 proteins mainly form heterohexamers containing each of the six proteins. This heterohexamer is readily split into subcomplexes, whose interactions and subunit composition we characterize in detail. We show for the first time an ordered multistep assembly pathway by which the heterohexamer can be reformed from the subcomplexes. Importantly, this novel pathway is essential for DNA replication, since only the full heterohexamer can bind productively to chromatin and provide RLF-M activity.