Regulation of the mitotic exit protein kinases Cdc15 and Dbf2

In budding yeast, the release of the protein phosphatase Cdc14 from its inhibitor Cfi1/Net1 in the nucleolus during anaphase triggers the inactivation of Clb CDKs that leads to exit from mitosis. The mitotic exit pathway controls the association between Cdc14 and Cfi1/Net1. It is comprised of the RAS-like GTP binding protein Tem1, the exchange factor Lte1, the GTPase activating protein complex Bub2-Bfa1/Byr4, and several protein kinases including Cdc15 and Dbf2. Here we investigate the regulation of the protein kinases Dbf2 and Cdc15. We find that Cdc15 is recruited to both spindle pole bodies (SPBs) during anaphase. This recruitment depends on TEM1 but not DBF2 or CDC14 and is inhibited by BUB2. Dbf2 also localizes to SPBs during anaphase, which coincides with activation of Dbf2 kinase activity. Both events depend on the mitotic exit pathway components TEM1 and CDC15. In cells lacking BUB2, Dbf2 localized to SPBs in cell cycle stages other than anaphase and telophase and Dbf2 kinase was prematurely active during metaphase. Our results suggest an order of function of mitotic exit pathway components with respect to SPB localization of Cdc15 and Dbf2 and activation of Dbf2 kinase. BUB2 negatively regulates all 3 events. Loading of Cdc15 on SPBs depends on TEM1, whereas loading of Dbf2 on SPBs and activation of Dbf2 kinase depend on TEM1 and CDC15.     

Dbf2 is essential for cytokinesis and correct mitotic spindle formation in Candida albicans

We have characterized the DBF2 gene, encoding a protein kinase of the NDR family in Candida albicans, and demonstrate that this gene is essential for cell viability. Conditional mutants were constructed by using the MET3 promoter to analyse the phenotype of cells lacking this kinase. The absence of Dbf2 resulted in cells arrested as large-budded pairs that failed to contract the actomyosin ring, a function similar to that described for its Saccharomyces cerevisiae orthologue. In addition to its role in cytokinesis, Dbf2 regulates mitotic spindle organization and nuclear segregation as Dbf2-depleted cells have abnormal microtubules and severe defects in nuclear migration to the daughter cell, which results in a cell cycle block during mitosis. Taken together, these results imply that Dbf2 performs several functions during exit from mitosis and cytokinesis. Consistent with a role in spindle organization, the protein localizes to the mitotic spindle during anaphase, and it interacts physically with tubulin, as indicated by immunoprecipitation experiments. Finally, DBF2 depletion also resulted in impaired true hyphal growth.     

A Bub2p-dependent spindle checkpoint pathway regulates the Dbf2p kinase in budding yeast

Exit from mitosis in all eukaroytes requires inactivation of the mitotic kinase. This occurs principally by ubiquitin-mediated proteolysis of the cyclin subunit controlled by the anaphase-promoting complex (APC). However, an abnormal spindle and/or unattached kinetochores activates a conserved spindle checkpoint that blocks APC function. This leads to high mitotic kinase activity and prevents mitotic exit. DBF2 belongs to a group of budding yeast cell cycle genes that when mutated prevent cyclin degradation and block exit from mitosis. DBF2 encodes a protein kinase which is cell cycle regulated, peaking in metaphase-anaphase B/telophase, but its function remains unknown. Here, we show the Dbf2p kinase activity to be a target of the spindle checkpoint. It is controlled specifically by Bub2p, one of the checkpoint components that is conserved in fission yeast and higher eukaroytic cells. Significantly, in budding yeast, Bub2p shows few genetic or biochemical interactions with other members of the spindle checkpoint. Our data now point to the protein kinase Mps1p triggering a new parallel branch of the spindle checkpoint in which Bub2p blocks Dbf2p function.     

A Dbf4p BRCA1 C-terminal-like domain required for the response to replication fork arrest in budding yeast

Dbf4p is an essential regulatory subunit of the Cdc7p kinase required for the initiation of DNA replication. Cdc7p and Dbf4p orthologs have also been shown to function in the response to DNA damage. A previous Dbf4p multiple sequence alignment identified a conserved approximately 40-residue N-terminal region with similarity to the BRCA1 C-terminal (BRCT) motif called "motif N." BRCT motifs encode approximately 100-amino-acid domains involved in the DNA damage response. We have identified an expanded and conserved approximately 100-residue N-terminal region of Dbf4p that includes motif N but is capable of encoding a single BRCT-like domain. Dbf4p orthologs diverge from the BRCT motif at the C terminus but may encode a similar secondary structure in this region. We have therefore called this the BRCT and DBF4 similarity (BRDF) motif. The principal role of this Dbf4p motif was in the response to replication fork (RF) arrest; however, it was not required for cell cycle progression, activation of Cdc7p kinase activity, or interaction with the origin recognition complex (ORC) postulated to recruit Cdc7p-Dbf4p to origins. Rad53p likely directly phosphorylated Dbf4p in response to RF arrest and Dbf4p was required for Rad53p abundance. Rad53p and Dbf4p therefore cooperated to coordinate a robust cellular response to RF arrest.     

Asymmetric spindle pole localization of yeast Cdc15 kinase links mitotic exit and cytokinesis

The inactivation of mitotic cyclin-dependent kinases (CDKs) during anaphase is a prerequisite for the completion of nuclear division and the onset of cytokinesis [1, 2]. In the budding yeast Saccharomyces cerevisiae, the essential protein kinase Cdc15 [3] together with other proteins of the mitotic exit network (Tem1, Lte1, Cdc5, and Dbf2/Dbf20 [4-7]) activates Cdc14 phosphatase, which triggers cyclin degradation and the accumulation of the CDK inhibitor Sic1 [8]. However, it is still unclear how CDK inactivation promotes cytokinesis. Here, we analyze the properties of Cdc15 kinase during mitotic exit. We found that Cdc15 localized to the spindle pole body (SPB) in a unique pattern. Cdc15 was present at the SPB of the mother cell until late mitosis, when it also associated with the daughter pole. High CDK activity inhibited this association, while dephosphorylation of Cdc15 by Cdc14 phosphatase enabled it. The analysis of Cdc15 derivatives indicated that SPB localization was specifically required for cytokinesis but not for mitotic exit. These results show that Cdc15 has two separate functions during the cell cycle. First, it is required for the activation of Cdc14. CD14, in turn, promotes CDK inactivation and also dephosphorylates of Cdc15. As a consequence, Cdc15 binds to the daughter pole and triggers cytokinesis. Thus, Cdc15 helps to coordinate mitotic exit and cytokinesis.     

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.     

A MAP kinase is activated late in plant mitosis and becomes localized to the plane of cell division.

In eukaryotes, mitogen-activated protein kinases (MAPKs) are part of signaling modules that transmit diverse stimuli, such as mitogens, developmental cues, or various stresses. Here, we report a novel alfalfa MAPK, Medicago MAP kinase 3 (MMK3). Using an MMK3-specific antibody, we detected the MMK3 protein and its associated activity only in dividing cells. The MMK3 protein could be found during all stages of the cell cycle, but its protein kinase activity was transient in mitosis and correlated with the timing of phragmoplast formation. Depolymerization of microtubules by short treatments with the drug amiprophosmethyl during anaphase and telophase abolished MMK3 activity, indicating that intact microtubules are required for MMK3 activation. During anaphase, MMK3 was found to be concentrated in between the segregating chromosomes; later, it localized at the midplane of cell division in the phragmoplast. As the phragmoplast microtubules were redistributed from the center to the periphery during telophase, MMK3 still localized to the whole plane of division; thus, phragmoplast microtubules are not required to keep MMK3 at this location. Together, these data strongly support a role for MMK3 in the regulation of plant cytokinesis.     

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.     

Mitotic exit kinase Dbf2 directly phosphorylates chitin synthase Chs2 to regulate cytokinesis in budding yeast

How cell cycle machinery regulates extracellular matrix (ECM) remodeling during cytokinesis remains poorly understood. In the budding yeast Saccharomyces cerevisiae, the primary septum (PS), a functional equivalent of animal ECM, is synthesized during cytokinesis by the chitin synthase Chs2. Here, we report that Dbf2, a conserved mitotic exit kinase, localizes to the division site after Chs2 and directly phosphorylates Chs2 on several residues, including Ser-217. Both phosphodeficient (chs2-S217A) and phosphomimic (chs2-S217D) mutations cause defects in cytokinesis, suggesting that dynamic phosphorylation-dephosphorylation of Ser-217 is critical for Chs2 function. It is striking that Chs2-S217A constricts asymmetrically with the actomyosin ring (AMR), whereas Chs2-S217D displays little or no constriction and remains highly mobile at the division site. These data suggest that Chs2 phosphorylation by Dbf2 triggers its dissociation from the AMR during the late stage of cytokinesis. Of interest, both chs2-S217A and chs2-S217D mutants are robustly suppressed by increased dosage of Cyk3, a cytokinesis protein that displays Dbf2-dependent localization and also stimulates Chs2-mediated chitin synthesis. Thus Dbf2 regulates PS formation through at least two independent pathways: direct phosphorylation and Cyk3-mediated activation of Chs2. Our study establishes a mechanism for direct cell cycle control of ECM remodeling during cytokinesis.     

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.     

Maturation‐associated Dbf4 expression is essential for mouse zygotic DNA replication

Cdc7 is an S‐phase‐promoting kinase (SPK) that is required for the activation of replication initiation complex assembly because it phosphorylates the MCM protein complex serving as the replicative helicase in eukaryotic organisms. Cdc7 activity is undetectable in immature mouse GV oocytes, although Cdc7 protein is already expressed at the same level as in mature oocytes or early one‐cell embryos at zygotic S‐phase, in which Cdc7 kinase activity is clearly detectable. Dbf4 is a regulatory subunit of Cdc7 and is required for Cdc7 kinase activity. Dbf4 is not readily detectable in immature GV oocytes but accumulates to a level similar to that in one‐cell embryos during oocyte maturation, suggesting that Cdc7 is already activated in unfertilized eggs (metaphase II). RNAi‐mediated knockdown of maternal Dbf4 expression prevents the maturation‐associated increase in Dbf4 protein, abolishes the activation of Cdc7, and leads to the failure of DNA replication in one‐cell embryos, demonstrating that Dbf4 expression is the key regulator of Cdc7 activity in mouse oocytes. Dormant Dbf4 mRNA in immature GV oocytes is recruited by cytoplasmic polyadenylation during oocyte maturation and is dependent on MPF activity via its cytoplasmic polyadenylation element (CPE) upstream of the hexanucleotide (HEX) in the 3′ untranslated region (3′UTR). Our results suggest that Cdc7 is inactivated in immature oocytes, preventing it from the unwanted phosphorylation of MCM proteins, and the oocyte is qualified by proper maturation to proceed following embryogenesis after fertilization through zygotic DNA replication.     

Cell Cycle Regulation of DNA Replication Initiator Factor Dbf4p

The precise duplication of eukaryotic genetic material takes place once and only once per cell cycle and is dependent on the completion of the previous mitosis. Two evolutionarily conserved kinases, the cyclin B (Clb)/cyclin-dependent kinase (Cdk/Cdc28p) and Cdc7p along with its interacting factor Dbf4p, are required late in G1 to initiate DNA replication. We have determined that the levels of Dbf4p are cell cycle regulated. Dbf4p levels increase as cells begin S phase and remain high through late mitosis, after which they decline dramatically as cells begin the next cell cycle. We report that Dbf4p levels are sensitive to mutations in key components of the anaphase-promoting complex (APC). In addition, Dbf4p is modified in response to DNA damage, and this modification is dependent upon the DNA damage response pathway. We had previously shown that Dbf4p interacts with the M phase polo-like kinase Cdc5p, a key regulator of the APC late in mitosis. These results further link the actions of the initiator protein, Dbf4p, to the completion of mitosis and suggest possible roles for Dbf4p during progression through mitosis.     

Phosphorylation and spindle pole body localization of the Cdc15p mitotic regulatory protein kinase in budding yeast

Cdc15p is an essential protein kinase and functions with a group of late mitotic proteins that includes Lte1p, Tem1p, Cdc14p and Dbf2p/Dbf20p to inactivate Cdc28p-Clb2p at the end of mitosis in budding yeast [1] [2]. Cdc14p is activated and released from the nucleolus at late anaphase/telophase to dephosphorylate important regulators of Cdc28p-Clb2p such as Hct1p/Cdh1p, Sic1p and Swi5p in a CDC15-dependent manner [3] [4] [5] [6] [7]. How Cdc15p itself is regulated is not known. Here, we report that both the phosphorylation and localization of Cdc15p are cell cycle regulated. The extent of phosphorylation of Cdc15p gradually increases during cell-cycle progression until some point during late anaphase/telophase when it is rapidly dephosphorylated. We provide evidence suggesting that Cdc14p is the phosphatase responsible for the dephosphorylation of Cdc15p. Using a Cdc15p fusion protein coupled at its carboxyl terminus to green fluorescent protein (GFP), we found that Cdc15p, like its homologue Cdc7p [8] in fission yeast, localizes to the spindle pole bodies (SPBs) during mitosis. At the end of telophase, a portion of Cdc15p is located at the mother-bud neck, suggesting a possible role for Cdc15p in cytokinesis.     

Spo12 Is a Limiting Factor That Interacts with the Cell Cycle Protein Kinases Dbf2 and Dbf20, Which Are Involved in Mitotic Chromatid Disjunction

The DBF2 and DBF20 genes of the budding yeast Saccharomyces cerevisiae encode a pair of structurally similar protein kinases. Although yeast with either gene deleted is viable, deletion of both genes is lethal. Thus, the Dbf2 and Dbf20 proteins are functional alternatives for an essential activity. In contrast to deletions, four different mutant alleles of DBF2 are lethal. Thus, the presence of a nonfunctional Dbf2 protein, rather than the lack of function per se, is inhibitory. Here we present genetic evidence that nonfunctional mutant Dbf2 protein blocks the function of Dbf20 protein by sequestering a common interacting protein encoded by SPO12. Even a single extra copy of SPO12 is sufficient to suppress the dbf2 defect. Since SPO12 appears to encode a limiting factor, it may be a rate limiting cofactor that is involved in the regulation of the Dbf2 and Dbf20 protein kinases. A corollary to the finding that one extra copy of SPO12 can suppress dbf2, is that the acquisition of an extra chromosome VIII, which carries the SPO12 locus, will also suppress dbf2. Indeed, physical analysis of chromosome copy number in dbf2 revertants able to grow at 37° showed that the frequency of chromosome VIII acquisition increased when cells were incubated at the restrictive temperature, and reached a frequency of more than 100-fold the amount in wild-type yeast. This suggested that the dbf2 mutation was not only suppressed by an extra copy of chromosome VIII but also that the dbf2 mutation actually caused aberrant chromosomal segregation. Conventional assays for chromosome loss confirmed this proposal.     

Hierarchy of S-phase-promoting factors: yeast Dbf4-Cdc7 kinase requires prior S-phase cyclin-dependent kinase activation

In all eukaryotes, the initiation of DNA synthesis requires the formation of prereplicative complexes (pre-RCs) on replication origins, followed by their activation by two S-T protein kinases, an S-phase cyclin-dependent kinase (S-CDK) and a homologue of yeast Dbf4-Cdc7 kinase (Dbf4p-dependent kinase [DDK]). Here, we show that yeast DDK activity is cell cycle regulated, though less tightly than that of the S-CDK Clb5-Cdk1, and peaks during S phase in correlation with Dbf4p levels. Dbf4p is short-lived throughout the cell cycle, but its instability is accentuated during G(1) by the anaphase-promoting complex. Downregulating DDK activity is physiologically important, as joint Cdc7p and Dbf4p overexpression is lethal. Because pre-RC formation is a highly ordered process, we asked whether S-CDK and DDK need also to function in a specific order for the firing of origins. We found that both kinases are activated independently, but we show that DDK can perform its function for DNA replication only after S-CDKs have been activated. Cdc45p, a protein needed for initiation, binds tightly to chromatin only after S-CDK activation (L. Zou and B. Stillman, Science 280:593-596, 1998). We show that Cdc45p is phosphorylated by DDK in vitro, suggesting that it might be one of DDK's critical substrates after S-CDK activation. Linking the origin-bound DDK to the tightly regulated S-CDK in a dependent sequence of events may ensure that DNA replication initiates only at the right time and place.     

Regulation of the localization of Dbf2 and mob1 during cell division of saccharomyces cerevisiae.

The mitotic exit network (MEN) governs Cdk inactivation. In budding yeast, MEN consists of the protein phosphatase Cdc14, the ras-like GTPase Tem1, protein kinases Cdc15, Cdc5, Dbf2 and Dbf2-binding protein Mob1. Tem1, Dbf2, Cdc5 and Cdc15 have been reported to be localized at the spindle pole body (SPB). Here we report changes of the localization of Dbf2 and Mob1 during cell division. Dbf2 and Mob1 localize to the SPBs in anaphase and then moves to the bud neck, just prior to actin ring assembly, consistent with their role in cytokinesis. The neck localization, but not SPB localization, of Dbf2 was inhibited by the Bub2 spindle checkpoint. Cdc14 is the downstream target of Dbf2 in Cdk inactivation, but we found that the neck localization of DbP2 and Mob1 was dependent on the Cdc14 activity, suggesting that Dbf2 and Mob1 function in cytokinesis at the end of the mitotic signaling cascade.     

Identification and characterization of a Xenopus homolog of Dbf4, a regulatory subunit of the Cdc7 protein kinase required for the initiation of DNA replication

Dbf4 is a regulatory subunit for the Cdc7 protein kinase that is required for the initiation of eukaryotic DNA replication, but the precise roles of Dbf4-Cdc7 remain to be determined. Here we identified a Xenopus homolog of Dbf4 (XDbf4) and characterized XDbf4 and Xenopus Cdc7 (XCdc7) in Xenopus egg extracts. XDbf4 formed a complex with XCdc7 in egg extracts and activated XCdc7 kinase activity in vitro. In contrast with Dbf4 in yeast and mammalian cultured cells, the XDbf4 levels in egg extracts did not change during the cell cycle progression. XDbf4 was a phosphoprotein in interphase extracts, and was apparently hyperphosphorylated in cytostatic factor (CSF)-mediated, metaphase-arrested extracts and in mitotic extracts. However, the hyperphosphorylation of XDbf4 did not seem to affect the level of kinase activation, or chromatin binding of the XDbf4-XCdc7 complex. Upon release from CSF-arrest, XDbf4 was partially dephosphorylated and bound to chromatin. Interestingly, XDbf4 was loaded onto chromatin before XCdc7 during DNA replication in egg extracts. These results suggest that the function of XDbf4-XCdc7 during the early embryonic cell cycle is regulated in a manner distinct from that during the somatic cell cycle.     

Dual role of the Cdc7-regulatory protein Dbf4 during yeast meiosis

The Dbf4-dependent Cdc7 kinase (DDK) is essential for chromosome duplication in all eukaryotes, but was proposed to be dispensable for yeast pre-meiotic DNA replication. This discrepancy led us to investigate the role of the unstable Cdc7-regulatory protein Dbf4 in meiosis. We show that, when Dbf4 is depleted at the time of meiotic induction, cells enter the meiotic program but do not replicate their chromosomes. Surprisingly when Dbf4 is depleted after the initiation of DNA synthesis, S phase goes to completion, but most cells arrest before anaphase I. Deletion of the cohesin Rec8 suppresses this phenotype, suggesting a distinct role of DDK for meiotic chromosome segregation. As after Cdc5 depletion, a fraction of cells undergo a single equational division suggesting a failure to mono-orient sister kinetochores. Our results demonstrate that Dbf4 is essential for DNA replication during meiosis like in vegetative cells and provide evidence for an additional role in setting up the reductional division of meiosis I.