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.     

The cyclin-dependent kinase Cdc28p regulates distinct modes of Cdc6p proteolysis during the budding yeast cell cycle

BACKGROUND: Cdc28p, the major cyclin-dependent kinase in budding yeast, prevents re-replication within each cell cycle by preventing the reassembly of Cdc6p-dependent pre-replicative complexes (pre-RCs) once origins have fired. Cdc6p is a rapidly degraded protein that must be synthesised in each cell cycle and is present only during the G1 phase. RESULTS: We found that, at different times in the cell cycle, there are distinct modes of Cdc6p proteolysis. Before Start, Cdc6p proteolysis did not require either the anaphase-promoting complex (APC/C) or the SCF complex, which mediate the major cell cycle regulated ubiquitination pathways, nor did it require Cdc28p activity or any of the potential Cdc28p phosphorylation sites in Cdc6p. In fact, the activation of B cyclin (Clb)-Cdc28p kinase inactivated this pathway of Cdc6p degradation later in the cell cycle. Activation of the G1 cyclins (Clns) caused Cdc6p degradation to become extremely rapid. This degradation required the SCF(CDC4) and Cdc28p consensus sites in Cdc6p, but did not require Clb5 and Clb6. Later in the cell cycle, SCF(CDC4)-dependent Cdc6p proteolysis remained active but became less rapid. CONCLUSIONS: Levels of Cdc6p are regulated in several ways by the Cdc28p cyclin-dependent kinase. The Cln-dependent elimination of Cdc6p, which does not require the S-phase-promoting cyclins Clb5 and Clb6, suggests that the ability to assemble pre-RCs is lost before, not concomitant with, origin firing.     

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.     

Cdc6 stability is regulated by the Huwe1 ubiquitin ligase after DNA damage

The Cdc6 protein is an essential component of pre-replication complexes (preRCs), which assemble at origins of DNA replication during the G1 phase of the cell cycle. Previous studies have demonstrated that, in response to ionizing radiation, Cdc6 is ubiquitinated by the anaphase promoting complex (APC(Cdh1)) in a p53-dependent manner. We find, however, that DNA damage caused by UV irradiation or DNA alkylation by methyl methane sulfonate (MMS) induces Cdc6 degradation independently of p53. We further demonstrate that Cdc6 degradation after these forms of DNA damage is also independent of cell cycle phase, Cdc6 phosphorylation of the known Cdk target residues, or the Cul4/DDB1 and APC(Cdh1) ubiquitin E3 ligases. Instead Cdc6 directly binds a HECT-family ubiquitin E3 ligase, Huwe1 (also known as Mule, UreB1, ARF-BP1, Lasu1, and HectH9), and Huwe1 polyubiquitinates Cdc6 in vitro. Degradation of Cdc6 in UV-irradiated cells or in cells treated with MMS requires Huwe1 and is associated with release of Cdc6 from chromatin. Furthermore, yeast cells lacking the Huwe1 ortholog, Tom1, have a similar defect in Cdc6 degradation. Together, these findings demonstrate an important and conserved role for Huwe1 in regulating Cdc6 abundance after DNA damage.     

Dbf4p, an essential S phase-promoting factor, is targeted for degradation by the anaphase-promoting complex

The Dbf4p/Cdc7p protein kinase is essential for the activation of replication origins during S phase. The catalytic subunit, Cdc7p, is present at constant levels throughout the cell cycle. In contrast, we show here that the levels of the regulatory subunit, Dbf4p, oscillate during the cell cycle. Dbf4p is absent from cells during G(1) and accumulates during the S and G(2) phases. Dbf4p is rapidly degraded at the time of chromosome segregation and remains highly unstable during pre-Start G(1) phase. The rapid degradation of Dbf4p during G(1) requires a functional anaphase-promoting complex (APC). Mutation of a sequence in the N terminus of Dbf4p which resembles the cyclin destruction box eliminates this APC-dependent degradation of Dbf4p. We suggest that the coupling of Dbf4p degradation to chromosome separation may play a redundant role in ensuring that prereplicative complexes, which assemble after chromosome segregation, do not immediately refire.     

CDK inhibitor p21 is degraded by a proliferating cell nuclear antigen-coupled Cul4-DDB1Cdt2 pathway during S phase and after UV irradiation

Previous reports showed that chromatin-associated PCNA couples DNA replication with Cul4-DDB1(Cdt2)-dependent proteolysis of the licensing factor Cdt1. The CDK inhibitor p21, another PCNA-binding protein, is also degraded both in S phase and after UV irradiation. Here we show that p21 is degraded by the same ubiquitin-proteasome pathway as Cdt1 in HeLa cells. When PCNA or components of Cul4-DDB1(Cdt2) were silenced or when the PCNA binding site on p21 was mutated, degradation of p21 was prevented both in S phase and after UV irradiation. p21 was co-immunoprecipitated with Cul4A and DDB1 proteins when expressed in cells. The purified Cul4A-DDB1(Cdt2) complex ubiquitinated p21 in vitro. Consistently, p21 protein levels are low during S phase and increase around G(2) phase. Mutational analysis suggested that in addition to the PCNA binding domain, its flanking regions are also important for recognition by Cul4-DDB1(Cdt2). Our findings provide a new aspect of proteolytic control of p21 during the cell cycle.     

Separate SCF(CDC4) recognition elements target Cdc6 for proteolysis in S phase and mitosis

The Cdc6 DNA replication initiation factor is targeted for ubiquitin-mediated proteolysis by the E3 ubiquitin ligase SCF(CDC4) from the end of G1phase until mitosis in the budding yeast Saccharomyces cerevisiae. Here we describe a dominant-negative CDC6 mutant that, when overexpressed, arrests the cell cycle by inhibiting cyclin-dependent kinases (CDKs) and, thus, prevents passage through mitosis. This mutant protein inhibits CDKs more efficiently than wild-type Cdc6, in part because it is completely refractory to SCF(CDC4)-mediated proteolysis late in the cell cycle and consequently accumulates to high levels. The mutation responsible for this phenotype destroys a putative CDK phosphorylation site near the middle of the Cdc6 primary amino acid sequence. We show that this site lies within a novel Cdc4-interacting domain distinct from a Cdc4-interacting site identified previously near the N-terminus of the protein. We show that both sites can target Cdc6 for proteolysis in late G1/early S phase whilst only the newly identified site can target Cdc6 for proteolysis during mitosis.     

Cell Cycle Control of Cdc7p Kinase Activity through Regulation of Dbf4p Stability

In Saccharomyces cerevisiae, the heteromeric kinase complex Cdc7p-Dbf4p plays a pivotal role at replication origins in triggering the initiation of DNA replication during the S phase. We have assayed the kinase activity of endogenous levels of Cdc7p kinase by using a likely physiological target, Mcm2p, as a substrate. Using this assay, we have confirmed that Cdc7p kinase activity fluctuates during the cell cycle; it is low in the G1 phase, rises as cells enter the S phase, and remains high until cells complete mitosis. These changes in kinase activity cannot be accounted for by changes in the levels of the catalytic subunit Cdc7p, as these levels are constant during the cell cycle. However, the fluctuations in kinase activity do correlate with levels of the regulatory subunit Dbf4p. The regulation of Dbf4p levels can be attributed in part to increased degradation of the protein in G1 cells. This G1-phase instability is cdc16 dependent, suggesting a role of the anaphase-promoting complex in the turnover of Dbf4p. Overexpression of Dbf4p in the G1 phase can partially overcome this elevated turnover and lead to an increase in Cdc7p kinase activity. Thus, the regulation of Dbf4p levels through the control of Dbf4p degradation has an important role in the regulation of Cdc7p kinase activity during the cell cycle.     

Control of Swe1p degradation by the morphogenesis checkpoint.

In the budding yeast Saccharomyces cerevisiae, a cell cycle checkpoint coordinates mitosis with bud formation. Perturbations that transiently depolarize the actin cytoskeleton cause delays in bud formation, and a 'morphogenesis checkpoint' detects the actin perturbation and imposes a G2 delay through inhibition of the cyclin-dependent kinase, Cdc28p. The tyrosine kinase Swe1p, homologous to wee1 in fission yeast, is required for the checkpoint-mediated G2 delay. In this report, we show that Swe1p stability is regulated both during the normal cell cycle and in response to the checkpoint. Swe1p is stable during G1 and accumulates to a peak at the end of S phase or in early G2, when it becomes unstable and is degraded rapidly. Destabilization of Swe1p in G2 and M phase depends on the activity of Cdc28p in complexes with B-type cyclins. Several different perturbations of actin organization all prevent Swe1p degradation, leading to the persistence or further accumulation of Swe1p, and cell cycle delay in G2.     

Cell cycle regulation of the yeast Cdc7 protein kinase by association with the Dbf4 protein.

Yeast Cdc7 protein kinase and Dbf4 protein are both required for the initiation of DNA replication at the G1/S phase boundary of the mitotic cell cycle. Cdc7 kinase function is stage-specific in the cell cycle, but total Cdc7 protein levels remained unchanged. Therefore, regulation of Cdc7 function appears to be the result of posttranslational modification. In this study, we have attempted to elucidate the mechanism responsible for achieving this specific execution point of Cdc7. Cdc7 kinase activity was shown to be maximal at the G1/S boundary by using either cultures synchronized with alpha factor or Cdc- mutants or with inhibitors of DNA synthesis or mitosis. Therefore, Cdc7 kinase is regulated by a posttranslational mechanism that ensures maximal Cdc7 activity at the G1/S boundary, which is consistent with Cdc7 function in the cell cycle. This cell cycle-dependent regulation could be the result of association with the Dbf4 protein. In this study, the Dbf4 protein was shown to be required for Cdc7 kinase activity in that Cdc7 kinase activity is thermolabile in vitro when extracts prepared from a temperature-sensitive dbf4 mutant grown under permissive conditions are used. In vitro reconstitution assays, in addition to employment of the two-hybrid system for protein-protein interactions, have demonstrated that the Cdc7 and Dbf4 proteins interact both in vitro and in vivo. A suppressor mutation, bob1-1, which can bypass deletion mutations in both cdc7 and dbf4 was isolated. However, the bob1-1 mutation cannot bypass all events in G1 phase because it fails to suppress temperature-sensitive cdc4 or cdc28 mutations. This indicates that the Cdc7 and Dbf4 proteins act at a common point in the cell cycle. Therefore, because of the common point of function for the two proteins and the fact that the Dbf4 protein is essential for Cdc7 function, we propose that Dbf4 may represent a cyclin-like molecule specific for the activation of Cdc7 kinase.     

Phosphorylation Controls Timing of Cdc6p Destruction: A Biochemical Analysis

The replication initiation protein Cdc6p forms a tight complex with Cdc28p, specifically with forms of the kinase that are competent to promote replication initiation. We now show that potential sites of Cdc28 phosphorylation in Cdc6p are required for the regulated destruction of Cdc6p that has been shown to occur during the Saccharomyces cerevisiae cell cycle. Analysis of Cdc6p phosphorylation site mutants and of the requirement for Cdc28p in an in vitro ubiquitination system suggests that targeting of Cdc6p for degradation is more complex than previously proposed. First, phosphorylation of N-terminal sites targets Cdc6p for polyubiquitination probably, as expected, through promoting interaction with Cdc4p, an F box protein involved in substrate recognition by the Skp1-Cdc53-F-box protein (SCF) ubiquitin ligase. However, in addition, mutation of a single, C-terminal site stabilizes Cdc6p in G2 phase cells without affecting substrate recognition by SCF in vitro, demonstrating a second and novel requirement for specific phosphorylation in degradation of Cdc6p. SCF-Cdc4p- and N-terminal phosphorylation site-dependent ubiquitination appears to be mediated preferentially by Clbp/Cdc28p complexes rather than by Clnp/Cdc28ps, suggesting a way in which phosphorylation of Cdc6p might control the timing of its degradation at then end of G1 phase of the cell cycle. The stable cdc6 mutants show no apparent replication defects in wild-type strains. However, stabilization through mutation of three N-terminal phosphorylation sites or of the single C-terminal phosphorylation site leads to dominant lethality when combined with certain mutations in the anaphase-promoting complex.     

Binding to the yeast SwI4,6-dependent cell cycle box, CACGAAA, is cell cycle regulated in vivo.

In Saccharomyces cerevisiae commitment to cell division occurs late in the G1 phase of the cell cycle at a point called Start and requires the activity of the Cdc28 protein kinase and its associated G1 cyclins. The Swi4,6-dependent cell cycle box binding factor, SBF, is important for maximal expression of the G1 cyclin and HO endonuclease genes at Start. The cell cycle regulation of these genes is modulated through an upstream regulatory element termed the SCB (SwI4,6-dependent cell cycle box, CACGAAA), which is dependent on both SWI4 and SWI6. Although binding of SWI4 and SWI6 to SCB sequences has been well characterized in vitro, the binding of SBF in vivo has not been examined. We used in vivo dimethyl sulfate footprinting to examine the occupancy of SCB sequences throughout the cell cycle. We found that binding to SCB sequences occurred in the G1 phase of the cell cycle and was greatly reduced in G2. In the absence of either SWI4 or SWI6, SCB sequences were not occupied at any cell cycle stage. These results suggest that the G1-specific expression of SCB-dependent genes is regulated at the level of DNA binding in vivo.     

Down-regulation of p27(Kip1) by two mechanisms, ubiquitin-mediated degradation and proteolytic processing.

The intracellular level of p27(Kip1), a cyclin-dependent kinase (CDK) inhibitory protein, is rapidly reduced at the G1/S transition phase when the cell cycle pause ceases. In this study, we demonstrated that two posttranslational mechanisms were involved in p27(Kip1) breakdown: degradation via the ubiquitin (Ub)-proteasome pathway and proteolytic processing that rapidly eliminates the cyclin-binding domain. We confirmed that p27(Kip1) was ubiquitinated in vitro as well as in vivo. The p27(Kip1) -ubiquitination activity was higher at the G1/S boundary than during the G0/G1 phase, and p27(Kip1) ubiquitination was reduced significantly when the lysine residues at positions 134, 153, and 165 were replaced by arginine, suggesting that these lysine residues are the targets for Ub conjugation. In parallel with its Ub-dependent degradation, p27(Kip1) was processed rapidly at its N terminus, reducing its molecular mass from 27 to 22 kDa, by a ubiquitination-independent but adenosine triphosphate (ATP)-dependent mechanism with higher activity during the S than the G0/G1 phase. This 22-kDa intermediate had no cyclin-binding domain at its N terminus and virtually no CDK2 kinase inhibitory activity. These results suggest that p27(Kip1) is eliminated by two independent mechanisms, ubiquitin-mediated degradation and ubiquitin-independent processing, during progression from the G1 to S phase.     

The role and regulation of the preRC component Cdc6 in the initiation of premeiotic DNA replication

In all eukaryotes, the initiation of DNA replication is regulated by the ordered assembly of DNA/protein complexes on origins of DNA replication. In this report, we examine the role of Cdc6, a component of the prereplication complex, in the initiation of premeiotic DNA replication in budding yeast. We show that in the meiotic cycle, Cdc6 is required for DNA synthesis and sporulation. Moreover, similarly to the regulation in the mitotic cell cycle, Cdc6 is specifically degraded upon entry into the meiotic S phase. By contrast, chromatin-immunoprecipitation analysis reveals that the origin-bound Cdc6 is stable throughout the meiotic cycle. Preliminary evidence suggests that this protection reflects a change in chromatin structure that occurs in meiosis. Using the cdc28-degron allele, we show that depletion of Cdc28 leads to stabilization of Cdc6 in the mitotic cycle, but not in the meiotic cycle. We show physical association between Cdc6 and the meiosis-specific hCDK2 homolog Ime2. These results suggest that under meiotic conditions, Ime2, rather than Cdc28, regulates the stability of Cdc6. Chromatin-immunoprecipitation analysis reveals that similarly to the mitotic cell cycle, Mcm2 binds origins in G1 and meiotic S phases, and at the end of the second meiotic division, it is gradually removed from chromatin.     

Ubiquitination of free cyclin D1 is independent of phosphorylation on threonine 286

Cyclin D1 binds and regulates the activity of cyclin-dependent kinases (CDKs) 4 and 6. Phosphorylation of the retinoblastoma protein by cyclin D1.CDK4/6 complexes during the G(1) phase of the cell cycle promotes entry into S phase. Cyclin D1 protein is ubiquitinated and degraded by the 26 S proteasome. Previous studies have demonstrated that cyclin D1 ubiquitination is dependent on its phosphorylation by glycogen synthase kinase 3beta (GSK-3beta) on threonine 286 and that this phosphorylation event is greatly enhanced by binding to CDK4 (Diehl, J. A., Cheng, M. G., Roussel, M. F., and Sherr, C. J. (1998) Genes Dev. 12, 3499-3511). We now report an additional pathway for the ubiquitination of free cyclin D1 (unbound to CDKs). We show that, when unbound to CDK4, a cyclin D1-T286A mutant is ubiquitinated. Further, we show that a mutant of cyclin D1 that cannot bind to CDK4 (cyclin D1-KE) is also ubiquitinated in vivo. Our results demonstrate that free cyclin D1 is ubiquitinated independently of its phosphorylation on threonine 286 by GSK-3beta, suggesting that, as has been shown for cyclin E, distinct pathways of ubiquitination lead to the degradation of free and CDK-bound cyclin D1. The pathway responsible for ubiquitination of free cyclin D1 may be important in limiting the effects of cyclin D1 overexpression in a variety of cancers.     

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.