Cyclin B1-Cdk1 is the key initiator of mitosis, but when and where activation occurs has not been precisely determined in mammalian cells. Activation may occur in the nucleus or cytoplasm, as just before nuclear envelope breakdown, Polo-like kinase1 (Plk1) is proposed to phosphorylate cyclin B1 in its nuclear export sequence (NES), to trigger rapid nuclear import. We raised phospho-specific antibodies against cyclin B1 that primarily recognise the active form of the complex. We show that cyclin B1 is initially phosphorylated on centrosomes in prophase and that Plk1 phosphorylates cyclin B1, but not in the NES. Furthermore, phosphorylation by Plk1 does not cause cyclin B1 to move into the nucleus. We conclude that cyclin B1-Cdk1 is first activated in the cytoplasm and that centrosomes may function as sites of integration for the proteins that trigger mitosis.
We describe a cell-free system from HeLa cells that initiates DNA replication under cell cycle control. G1 but not G2 phase nuclei initiate replication when coincubated with S phase nuclei in cytosolic extracts from S phase but not from G1 or G2 phase HeLa cells. S phase nuclei or an S phase nuclear extract are required for the initiation of semiconservative DNA replication in G1 nuclei but not for elongation in S phase nuclei. S phase nuclear extract could be replaced by recombinant human cyclins A and E complexed to Cdk2 but not by Cdk2 alone or by human cyclin B1 complexed to Cdc2. In S phase cytosol, cyclins A/Cdk2 and E/Cdk2 triggered initiation synergistically.
In eukaryotes, mitosis is initiated by M phase promoting factor (MPF), composed of B-type cyclins and their partner protein kinase, CDK1. In animal cells, MPF is cytoplasmic in interphase and is translocated into the nucleus after mitosis has begun, after which it associates with the mitotic apparatus until the cyclins are degraded in anaphase. We have used a fusion protein between human cyclin B1 and green fluorescent protein (GFP) to study this dynamic behaviour in real time, in living cells. We found that when we injected cyclin B1-GFP, or cyclin B1-GFP bound to CDK1 (i.e. MPF), into interphase nuclei it is rapidly exported into the cytoplasm. Cyclin B1 nuclear export is blocked by leptomycin B, an inhibitor of the recently identified export factor, exportin 1 (CRM1). The nuclear export of MPF is mediated by a nuclear export sequence in cyclin B1, and an export-defective cyclin B1 accumulates in interphase nuclei. Therefore, during interphase MPF constantly shuttles between the nucleus and the cytoplasm, but the bulk of MPF is retained in the cytoplasm by rapid nuclear export. We found that a cyclin mutant with a defective nuclear export signal does not enhance the premature mitosis caused by interfering with the regulatory phosphorylation of CDK1, but is more sensitive to inhibition by the Wee1 kinase.
Mitotic fragmentation of the Golgi apparatus can be largely explained by disruption of the interaction between GM130 and the vesicle-docking protein p115. Here we identify a single serine (Ser-25) in GM130 as the key phosphorylated target and Cdc2 as the responsible kinase. MEK1, a component of the MAP kinase signaling pathway recently implicated in mitotic Golgi fragmentation, was not required for GM130 phosphorylation or mitotic fragmentation either in vitro or in vivo. We propose that Cdc2 is directly involved in mitotic Golgi fragmentation and that signaling via MEK1 is not required for this process.
We show that phosphorylation of human cyclin B1 is required for its rapid translocation to the nucleus towards the end of prophase. Phosphorylation enhances cyclin B1 nuclear import by creating a nuclear import signal. The phosphorylation of the CRS is therefore a critical step in the control of mitosis.
We have raised and characterized antibodies specific for human cyclin B2 and have compared the properties of cyclins B1 and B2 in human tissue culture cells. Cyclin B1 and B2 levels are very low in G1 phase, increase in S and G2 phases and peak at mitosis. Both B‐type cyclins associate with p34cdc2; their associated kinase activities appear when cells enter mitosis and disappear as the cyclins are destroyed in anaphase. However, human cyclins B1 and B2 differ dramatically in their subcellular localization. Cyclin B1 co‐localizes with microtubules, whereas cyclin B2 is primarily associated with the Golgi region. In contrast to cyclin B1, cyclin B2 does not relocate to the nucleus at prophase, but becomes uniformly distributed throughout the cell. The different subcellular locations of human cyclins B1 and B2 implicate them in the reorganization of different aspects of the cellular architecture at mitosis and indicate that different mitotic cyclin‐cyclin‐dependent kinase complexes may have distinct roles in the cell cycle.
Cyclins A and E and their partner cyclin-dependent kinases (Cdks) are key regulators of DNA synthesis and of mitosis. Immunofluorescence studies have shown that both cyclins are nuclear and that a proportion of cyclin A is localized to sites of DNA replication. However, recently, both cyclin A and cyclin E have been implicated as regulators of centrosome replication, and it is unclear when and where these cyclin-Cdks can interact with cytoplasmic substrates. We have used live cell imaging to study the behavior of cyclin/Cdk complexes. We found that cyclin A and cyclin E are able to regulate both nuclear and cytoplasmic events because they both shuttle between the nucleus and the cytoplasm. However, we found that there are marked differences in their shuttling behavior, which raises the possibility that cyclin/Cdk function could be regulated at the level of nuclear import and export. In the course of these experiments, we have also found that, contrary to published results, mutations in the hydrophobic patch of cyclin A do affect Cdk binding and nuclear import. This has implications for the role of the hydrophobic patch as a substrate selection motif. INTRODUCTIONSuccessive waves of cyclin-dependent kinase (Cdk) activity control progress through the eukaryotic cell cycle. Cdks are activated by binding a member of the cyclin family and phosphorylation by Cdk-activating kinase. The cyclin-Cdks that have been most strongly implicated in controlling entry into, and progress through, DNA replication are cyclins A and E. Both cyclins bind to Cdk2 (Elledge and Spottswood, 1991;Tsai et al., 1991;Koff et al., 1992), and the levels of both cyclins are strictly regulated throughout the cell cycle, by transcriptional and proteolytic mechanisms. Cyclin E levels are primarily dictated by the rate of its transcription because it is an unstable protein that is rapidly degraded by two different pathways of ubiquitin-dependent proteolysis (Clurman et al., 1996;Won and Reed, 1996;Singer et al., 1999;Wang et al., 1999;Winston et al., 1999;Nakayama et al., 2000). In contrast, cyclin A is stable until cells enter mitosis. Cyclin A levels first start to increase at the beginning of S phase and continue to rise throughout S and G2 phases until prometaphase, when they are rapidly degraded by ubiquitin-dependent proteolysis (Pines and Hunter, 1990;Hunt et al., 1992).There is extensive evidence to indicate that the activation of cyclin E/Cdk2 leads to the initiation of DNA replication. Cyclin E/Cdk2 activity is maximal at G1/S (Koff et al., 1992), replication of DNA in vitro is dependent on cyclin E/Cdk2 activity (Jackson et al., 1995;Strausfeld et al., 1996;Krude et al., 1997) and, in vivo, cyclin E is essential for DNA replication in Drosophila (Sauer et al., 1995). Cyclin A/Cdk2 has also been demonstrated to promote DNA replication (Girard et al., 1991;Pagano et al., 1992;Zindy et al., 1992;Strausfeld et al., 1996). However, cyclin A may be more significant in regulating progression through S phase (Connell-Crowley et al., 1998), perhap...
In mammalian cells, the Golgi apparatus is disassembled at the onset of mitosis and reassembled at the end of mitosis. This disassembly–reassembly is generally believed to be essential for the equal partitioning of Golgi into two daughter cells. For Golgi disassembly, membrane fusion, which is mediated by NSF and p97, needs to be blocked. For the NSF pathway, the tethering of p115-GM130 is disrupted by the mitotic phosphorylation of GM130, resulting in the inhibition of NSF-mediated fusion. In contrast, the p97/p47 pathway does not require p115-GM130 tethering, and its mitotic inhibitory mechanism has been unclear. Now, we have found that p47, which mainly localizes to the nucleus during interphase, is phosphorylated on Serine-140 by Cdc2 at mitosis. The phosphorylated p47 does not bind to Golgi membranes. An in vitro assay shows that this phosphorylation is required for Golgi disassembly. Microinjection of p47(S140A), which is unable to be phosphorylated, allows the cell to keep Golgi stacks during mitosis and has no effect on the equal partitioning of Golgi into two daughter cells, suggesting that Golgi fragmentation-dispersion may not be obligatory for equal partitioning even in mammalian cells.
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