Identification of the sequence responsible for the nuclear localization of human Cdc6

The Cdc6 is the essential protein for the initiation of DNA replication. Cdc6 is localized in the G1 nucleus, and abnormal nuclear localization of this protein induces irregular initiation of DNA replication. We identified here that amino acids K57 and R58 in the human Cdc6 protein play an important role in the nuclear localization of the protein. The fundamental features of the mechanism regulating the localization of Cdc6 seem to be maintained in yeast, Xenopus, and human, since the amino acid sequence surrounding K57 and R58, (S/T)PXKR(L/I), is conserved in these species. Substitution of amino acid residue S54 with E and not Q blocked partially the nuclear localization of the protein, implying that the phosphorylation at S54 is involved in the regulating mechanism of the cell cycle-dependent localization of Cdc6.     

The Cdc6 Nucleotide–Binding Site Regulates Its Activity in DNA Replication in Human Cells

The Cdc6 protein of budding yeast and its homologues in other species play an essential role in the initiation of DNA replication. A cDNA encoding a human homologue of Cdc6 (HsCdc6) has been cloned and expressed as a fusion protein in a soluble and functionally active form. The purified protein bound specifically to ATP and slowly hydrolyzed it, whereas HsCdc6 mutants containing amino acid substitutions in the Walker A or B motifs were defective. The mutant proteins retained the ability to bind HsOrc1 and HsCdc6 but displayed aberrant conformations in the presence of nucleotides. Microinjection of either mutant protein into human cells in G1 inhibited DNA replication, suggesting that ATP binding and hydrolysis by HsCdc6 are essential for DNA replication.     

Interactions between the archaeal Cdc6 and MCM proteins modulate their biochemical properties

The origin recognition complex, Cdc6 and the minichromosome maintenance (MCM) complex play essential roles in the initiation of eukaryotic DNA replication. Homologs of these proteins may play similar roles in archaeal replication initiation. While the interactions among the eukaryotic initiation proteins are well documented, the protein–protein interactions between the archaeal proteins have not yet been determined. Here, an extensive structural and functional analysis of the interactions between the Methanothermobacter thermautotrophicus MCM and the two Cdc6 proteins (Cdc6-1 and -2) identified in the organism is described. The main contact between Cdc6 and MCM occurs via the N-terminal portion of the MCM protein. It was found that Cdc6–MCM interaction, but not Cdc6–DNA binding, plays the predominant role in regulating MCM helicase activity. In addition, the data showed that the interactions with MCM modulate the autophosphorylation of Cdc6-1 and -2. The results also suggest that MCM and DNA may compete for Cdc6-1 protein binding. The implications of these observations for the initiation of archaeal DNA replication are discussed.     

Expression of Cdc18/Cdc6 and Cdt1 during G2 phase induces initiation of DNA replication

Cdc18/Cdc6 and Cdt1 are essential initiation factors for DNA replication. In this paper we show that expression of Cdc18 in fission yeast G2 cells is sufficient to override the controls that ensure one S phase per cell cycle. Cdc18 expression in G2 induces DNA synthesis by re-firing replication origins and recruiting the MCM Cdc21 to chromatin in the presence of low levels of Cdt1. However, when Cdt1 is expressed together with Cdc18 in G2, cells undergo very rapid, uncontrolled DNA synthesis, accumulating DNA contents of 64C or more. Our data suggest that Cdt1 may potentiate re-replication by inducing origins to fire more persistently, possibly by stabilizing Cdc18 on chromatin. In addition, low level expression of a mutant form of Cdc18 that cannot be phosphorylated by cyclin-dependent kinases is not sufficient to induce replication in G2, but does so only when co-expressed with Cdt1. Thus, regulation of both Cdc18 and Cdt1 in G2 plays a crucial role in preventing the re-initiation of DNA synthesis until the next cell cycle.     

Cdc6 and DNA replication: Limited to humble origins

The budding yeast Cdc6 protein is important for regulating DNA replication intiation. Cdc6p acts at replication origins, and cdc6-1 mutants arrest with unreplicated DNA and show elevated minichromosome loss rates. Overexpression of the related Cdc 18 protein in fission yeast results in DNA rereplication; however, Cdc6p overexpression does not cause this result. A recent paper⁽¹⁾ further defines the role of Cdc6p in DNA replication. Cdc6p only promotes DNA replication between the end of mitosis and late G₁, and although the Cdc6 protein is highly unstable, neither degradation nor nuclear localization is critical for limiting DNA replication to this interval.     

Schizosaccharomyces pombe Noc3 is essential for ribosome biogenesis and cell division but not DNA replication

The initiation of eukaryotic DNA replication is preceded by the assembly of prereplication complexes (pre-RCs) at chromosomal origins of DNA replication. Pre-RC assembly requires the essential DNA replication proteins ORC, Cdc6, and Cdt1 to load the MCM DNA helicase onto chromatin. Saccharomyces cerevisiae Noc3 (ScNoc3), an evolutionarily conserved protein originally implicated in 60S ribosomal subunit trafficking, has been proposed to be an essential regulator of DNA replication that plays a direct role during pre-RC formation in budding yeast. We have cloned Schizosaccharomyces pombe noc3(+) (Spnoc3(+)), the S. pombe homolog of the budding yeast ScNOC3 gene, and functionally characterized the requirement for the SpNoc3 protein during ribosome biogenesis, cell cycle progression, and DNA replication in fission yeast. We showed that fission yeast SpNoc3 is a functional homolog of budding yeast ScNoc3 that is essential for cell viability and ribosome biogenesis. We also showed that SpNoc3 is required for the normal completion of cell division in fission yeast. However, in contrast to the proposal that ScNoc3 plays an essential role during DNA replication in budding yeast, we demonstrated that fission yeast cells do enter and complete S phase in the absence of SpNoc3, suggesting that SpNoc3 is not essential for DNA replication in fission yeast.     

A Yeast GSK-3 Kinase Mck1 Promotes Cdc6 Degradation to Inhibit DNA Re-Replication

Cdc6p is an essential component of the pre-replicative complex (pre-RC), which binds to DNA replication origins to promote initiation of DNA replication. Only once per cell cycle does DNA replication take place. After initiation, the pre-RC components are disassembled in order to prevent re-replication. It has been shown that the N-terminal region of Cdc6p is targeted for degradation after phosphorylation by Cyclin Dependent Kinase (CDK). Here we show that Mck1p, a yeast homologue of GSK-3 kinase, is also required for Cdc6 degradation through a distinct mechanism. Cdc6 is an unstable protein and is accumulated in the nucleus only during G1 and early S-phase in wild-type cells. In mck1 deletion cells, CDC6p is stabilized and accumulates in the nucleus even in late S phase and mitosis. Overexpression of Mck1p induces rapid Cdc6p degradation in a manner dependent on Threonine-368, a GSK-3 phosphorylation consensus site, and SCF^CDC4. We show evidence that Mck1p-dependent degradation of Cdc6 is required for prevention of DNA re-replication. Loss of Mck1 activity results in synthetic lethality with other pre-RC mutants previously implicated in re-replication control, and these double mutant strains over-replicate DNA within a single cell cycle. These results suggest that a GSK3 family protein plays an unexpected role in preventing DNA over-replication through Cdc6 degradation in Saccharomyces cerevisiae. We propose that both CDK and Mck1 kinases are required for Cdc6 degradation to ensure a tight control of DNA replication.     

The functional role of Cdc6 in S-G2/M in mammalian cells

The Cdc6 protein is required for licensing of replication origins before the onset of DNA replication in eukaryotic cells. Here, we examined whether Cdc6 has other roles in mammalian cell-cycle progression from S to G2/M phase. Using RNA interference, we showed that depletion of Cdc6 in synchronous G1 cells blocks G1 to S transition, confirming the essential role of Cdc6 in the initiation of DNA replication. In contrast, depletion of Cdc6 in synchronous S-phase cells slowed DNA replication and led to mitotic lethality. The Cdc6-depleted S-phase cells showed fewer newly fired origins; however, established replication forks remained active, even during chromatin condensation. Despite such DNA replication abnormalities, loss of Cdc6 failed to activate Chk1 kinase. These results show that Cdc6 is not only required for G1 origin licensing, but is also crucial for proper S-phase DNA replication that is essential for DNA segregation during mitosis.     

Purification and characterization of the Schizosaccharomyces pombe origin recognition complex: interaction with origin DNA and Cdc18 protein

The origin recognition complex (ORC) plays a central role in the initiation of DNA replication in eukaryotic cells. It interacts with origins of DNA replication in chromosomal DNA and recruits additional replication proteins to form functional initiation complexes. These processes have not been well characterized at the biochemical level except in the case of Saccharomyces cerevisiae ORC. We report here the expression, purification, and initial characterization of Schizosaccharomyces pombe ORC (SpORC) containing six recombinant subunits. Purified SpORC binds efficiently to the ars1 origin of DNA replication via the essential Nterminal domain of the SpOrc4 subunit which contains nine AT-hook motifs. Competition binding experiments demonstrated that SpORC binds preferentially to DNA molecules rich in AT-tracts, but does not otherwise exhibit a high degree of sequence specificity. The complex is capable of binding to multiple sites within the ars1 origin of DNA replication with similar affinities, indicating that the sequence requirements for origin recognition in S. pombe are significantly less stringent than in S. cerevisiae. We have also demonstrated that SpORC interacts directly with Cdc18p, an essential fission yeast initiation protein, and recruits it to the ars1 origin in vitro. Recruitment of Cdc18p to chromosomal origins is a likely early step in the initiation of DNA replication in vivo. These data indicate that the purified recombinant SpORC retains at least two of its primary biological functions and that it will be useful for the eventual reconstitution of the initiation reaction with purified proteins.     

The Cdc4/34/53 pathway targets Cdc6p for proteolysis in budding yeast.

The budding yeast Cdc6 protein (Cdc6p) is essential for formation of pre-replicative complexes (pre-RCs) at origins of DNA replication. Regulation of pre-RC assembly plays a key role in making initiation of DNA synthesis dependent upon passage through mitosis and in limiting DNA replication to once per cell cycle. Cdc6p is normally only present at high levels during the G1 phase of the cell cycle. This is partly because the CDC6 gene is only transcribed during G1. In this article we show that rapid degradation of Cdc6p also contributes to this periodicity. Cdc6p degradation rates are regulated during the cell cycle, reaching a peak during late G1/early S phase. Removal of a 47-amino-acid domain near the N-terminus of Cdc6p prevents degradation of Cdc6p. Likewise, mutations in the Cdc4/34/53 pathway involved in ubiquitin-mediated degradation block proteolysis and genetic evidence is presented indicating that the N-terminus of Cdc6p interacts with the Cdc4/34/53 pathway, probably through Cdc4p. A stable Cdc6p mutant which is no longer degraded by the Cdc4/34/53 pathway is, none the less, fully functional. Constitutive overexpression of either wild-type or stable Cdc6p does not induce re-replication and does not induce assembly of pre-replicative complexes after DNA replication is complete.     

Mcm10 plays a role in functioning of the eukaryotic replicative DNA helicase, Cdc45-Mcm-GINS

Eukaryotic DNA replication is initiated at multiple origins of replication, where many replication proteins assemble under the control of the cell cycle [1]. A key process of replication initiation is to convert inactive Mcm2-7 to active Cdc45-Mcm-GINS (CMG) replicative helicase [2]. However, it is not known whether the CMG assembly would automatically activate its helicase activity and thus assemble the replisome. Mcm10 is an evolutionally conserved essential protein required for the initiation of replication [3, 4]. Although the roles of many proteins involved in the initiation are understood, the role of Mcm10 remains controversial [5-9]. To characterize Mcm10 in more detail, we constructed budding yeast cells bearing a degron-fused Mcm10 protein that can be efficiently degraded in response to auxin. In the absence of Mcm10, a stable CMG complex was assembled at origins. However, subsequent translocation of CMG, replication protein A loading to origins, and the intra-S checkpoint activation were severely diminished, suggesting that origin unwinding is defective. We also found that Mcm10 associates with origins during initiation in an S-cyclin-dependent kinase- and Cdc45-dependent manner. Thus, Mcm10 plays an essential role in functioning of the CMG replicative helicase independent of assembly of a stable CMG complex at origins.     

Distinct roles for Sld3 and GINS during establishment and progression of eukaryotic DNA replication forks

The Cdc45 protein is crucial for the initiation of chromosome replication in eukaryotic cells, as it allows the activation of prereplication complexes (pre-RCs) that contain the MCM helicase. This causes the unwinding of origins and the establishment of DNA replication forks. The incorporation of Cdc45 at nascent forks is a highly regulated and poorly understood process that requires, in budding yeast, the Sld3 protein and the GINS complex. Previous studies suggested that Sld3 is also important for the progression of DNA replication forks after the initiation step, as are Cdc45 and GINS. In contrast, we show here that Sld3 does not move with DNA replication forks and only associates with MCM in an unstable manner before initiation. After the establishment of DNA replication forks from early origins, Sld3 is no longer essential for the completion of chromosome replication. Unlike Sld3, GINS is not required for the initial recruitment of Cdc45 to origins and instead is necessary for stable engagement of Cdc45 with the nascent replisome. Like Cdc45, GINS then associates stably with MCM during S-phase.     

Budding yeast Cdc6p induces re-replication in fission yeast by inhibition of SCFPop-mediated proteolysis

In fission yeast, overexpression of the replication initiator protein Cdc18p induces re-replication, a phenotype characterized by continuous DNA synthesis in the absence of cell division. In contrast, overexpression of Cdc6p, the budding yeast homolog of Cdc18p, does not cause re-replication in S. cerevisiae. However, we have found that Cdc6p has the ability to induce re-replication in fission yeast. Cdc6p cannot functionally replace Cdc18p, but instead interferes with the proteolysis of both Cdc18p and Rum1p, the inhibitor of the protein kinase Cdc2p. This activity of Cdc6p is entirely contained within a short N-terminal peptide, which forms a tight complex with Cdc2p and the F-box/WD-repeat protein Sud1p/Pop2p, a component of the SCF^Pop ubiquitin ligase in fission yeast. These interactions are mediated by two distinct regions within the N-terminal region of Cdc6p and depend on the integrity of its Cdc2p phosphorylation sites. The data suggest that disruption of re-replication control by overexpression of Cdc6p in fission yeast is a consequence of sequestration of Cdc2p and Pop2p, two factors involved in the negative regulation of Rum1p, Cdc18p and potentially other replication proteins.     

Xenopus Cdc6 performs separate functions in initiating DNA replication

Cdc6 performs an essential role in the initiation of eukaryotic DNA replication by recruiting the minichromosome maintenance (MCM) complex onto DNA. Using immunodepletion/add-back experiments in Xenopus egg extracts, we have determined that both Walker A (ATP binding) and Walker B (ATP hydrolysis) motifs of Xenopus Cdc6 (Xcdc6) are essential, but have distinct functional roles. Although Walker B mutant protein binds chromatin well, Walker A mutant protein binds chromatin poorly. Neither Walker A nor Walker B mutant protein, however, load appreciable MCM onto DNA. Herein, we provide evidence that Cdc6 functions as a multimer: 1) mutant and wild-type Xcdc6 form multimers; 2) either mutant protein is dominant negative when added before wild-type Xcdc6, but stimulates DNA replication when added simultaneously with wild-type Xcdc6; and 3) the two mutants restore DNA replication when added together, in the absence of wild-type Xcdc6. Our findings suggest that ATP may play a key regulatory role within this multimer: its binding to Cdc6 promotes chromatin association and its hydrolysis facilitates MCM loading. Moreover, ATP binding and hydrolysis may occur in trans between Cdc6 subunits within the complex.     

Linking mitosis with S-phase: Cdc6 at play

In order to maintain genomic stability, cells must coordinate DNA replication such that every origin of replication fires once and only once per cell cycle. In addition, the order of replication and mitosis must be strictly controlled. To accomplish regulated origin firing, multicomponent pre-replicative complexes (pre-RCs) are assembled at origins of replication during G1. The Cdc6 protein (Cdc6p) is one of the essential and highly regulated components of the pre-RC. In addition, Cdc6 appears to be important after DNA replication, specifically during mitosis. In this review, we discuss the role of Cdc6 in regulating cell cycle specific phosphorylation and a newly recognized role in dephosphorylation of substrates important for progression of mitosis. We present a model in which Cdc6 would couple the shift between the two mitotic oscillators contributing to the coordination of the order of mitosis with the initiation of DNA replication.     

Identification and characterization of Saccharomyces cerevisiae Cdc6 DNA-binding properties

Recent studies have shown that Cdc6 is an essential regulator in the formation of DNA replication complexes. However, the biochemical nature of the Cdc6 molecule is still largely unknown. In this report, we present evidence that the Saccharomyces cerevisiae Cdc6 protein is a double-stranded DNA-binding protein. First, we have demonstrated that the purified yeast Cdc6 can bind to double-stranded DNA (dissociation constant approximately 1 x 10(-7) M), not to single-stranded DNA, and that the Cdc6 molecule is a homodimer in its native form. Second, we show that GST-Cdc6 fusion proteins expressed in Escherichia coli bind DNA in an electrophoretic mobility shift assay. Cdc6 antibodies and GST antibodies, but not preimmune serum, induce supershifts of GST-Cdc6 and DNA complexes in these assays, which also showed that GST-Cdc6 binds to various DNA probes without apparent sequence specificity. Third, the minimal requirement for the binding of Cdc6 to DNA has been mapped within its N-terminal 47-amino acid sequence (the NP6 region). This minimal binding domain shows identical DNA-binding properties to those possessed by full-length Cdc6. Fourth, the GST-NP6 protein competes for DNA binding with distamycin A, an antibiotic that chelates DNA within the minor groove of the A+T-rich region. Finally, site-direct mutagenesis studies revealed that the (29)KRKK region of Cdc6 is essential for Cdc6 DNA-binding activity. To further elucidate the function of Cdc6 DNA binding in vivo, we demonstrated that a binding mutant of Cdc6 fails to complement either cdc6-1 temperature-sensitive mutant cells or Deltacdc6 null mutant cells at the nonpermissive temperature. The mutant gene also conferred growth impairments and increased the plasmid loss in its host, indicative of defects in DNA synthesis. Because the mutant defective in DNA binding also fails to stimulate Abf1 ARS1 DNA-binding activity, our results suggest that Cdc6 DNA-binding activity may play a pivotal role in the initiation of DNA replication.     

Regulation of the localization and stability of Cdc6 in living yeast cells

The Cdc6 protein is an essential regulator for initiation of DNA replication. Following the G1/S transition, Cdc6 is degraded through a ubiquitin-mediated proteolysis pathway. In this study, we tagged Cdc6 with green fluorescent protein (GFP) and used site-specific mutations to study the regulation of Cdc6 localization and degradation in living yeast cells. Our major findings are: (1). Cdc6-GFP distributes predominantly in the nucleus in all cell cycle stages, with a small increase in cytoplasmic localization in G2/M cells. (2). This nuclear localization is critical for Cdc6 degradation. When the N-terminal nuclear localization signal (NLS) was mutated, Cdc6-GFP no longer accumulated in the nucleus, and the mutant cdc6 was stabilized compared to wild type. (3). The putative CDK phosphorylation sites are not required for Cdc6 nuclear localization, but are important for protein stability. These observations suggest that the stability of Cdc6 protein is regulated by two factors: nuclear localization and phosphorylation by CDK1.     

S. pombe replication protein Cdc18 (Cdc6) interacts with Swi6 (HP1) heterochromatin protein: Region specific effects and replication timing in the centromere

Heterochromatin in S. pombe is associated with gene silencing at telomeres, the mating locus and centromeres. The compact heterochromatin structure raises the question how it unpacks and reforms during DNA replication. We show that the essential DNA replication factor Cdc18 (CDC6) associates with heterochromatin protein 1 (Swi6) in vivo and in vitro. Biochemical mapping and mutational analysis of the association domains show that the N-terminus of Cdc18 interacts with the chromoshadow domain of Swi6. Mutations in Swi6 that disrupt this interaction disrupt silencing and delay replication in the centromere. A mutation cdc18-I43A that reduces Cdc18 association with Swi6 has no silencing defect at the centromere, but changes Swi6 distribution and accelerates the timing of centromere replication. We suggest that fine tuning of Swi6 association at replication origins is important for negative as well as positive control of replication initiation.     

Cdc7 kinase complex: a key regulator in the initiation of DNA replication

DNA replication results from the action of a staged set of highly regulated processes. Among the stages of DNA replication, initiation is the key point at which all the G1 regulatory signals culminate. Cdc7 kinase is the critical regulator for the ultimate firing of the origins of initiation. Cdc7, originally identified in budding yeast and later in higher eukaryotes, forms a complex with a Dbf4-related regulatory subunit to generate an active kinase. Genetic evidence in mammals demonstrates essential roles for Cdc7 in mammalian DNA replication. Mini-chromosome maintenance protein (MCM) is the major physiological target of Cdc7. Genetic studies in yeasts indicate additional roles of Cdc7 in meiosis, checkpoint responses, maintenance of chromosome structures, and repair. The interplay between Cdc7 and Cdk, another kinase essential for the S phase, is also discussed.