Fission yeast Fizzy-related protein srw1p is a G(1)-specific promoter of mitotic cyclin B degradation

Downregulation of cyclin-dependent kinase (Cdk)-mitotic cyclin complexes is important during cell cycle progression and in G(1) arrested cells undergoing differentiation. srw1p, a member of the Fizzy-related protein family in fission yeast, is required for the degradation of cdc13p mitotic cyclin B during G(1) arrest. Here we show that srw1p is not required for the degradation of cdc13p during mitotic exit demonstrating that there are two systems operative at different stages of the cell cycle for cdc13p degradation, and that srw1p is phosphorylated by Cdk-cdc13p only becoming dephosphorylated during G(1) arrest. We propose that this phosphorylation targets srw1p for proteolysis and inhibits its activity to promote cdc13p turnover.     

Inactivation of a Cdk2 inhibitor during interleukin 2-induced proliferation of human T lymphocytes.

Peripheral blood T lymphocytes require two sequential mitogenic signals to reenter the cell cycle from their natural, quiescent state. One signal is provided by stimulation of the T-cell antigen receptor, and this induces the synthesis of both cyclins and cyclin-dependent kinases (CDKs) that are necessary for progression through G1. Antigen receptor stimulation alone, however, is insufficient to promote activation of G1 cyclin-Cdk2 complexes. This is because quiescent lymphocytes contain an inhibitor of Cdk2 that binds directly to this kinase and prevents its activation by cyclins. The second mitogenic signal, which can be provided by the cytokine interleukin 2, leads to inactivation of this inhibitor, thereby allowing Cdk2 activation and progression into S phase. Enrichment of the Cdk2 inhibitor from G1 lymphocytes by cyclin-CDK affinity chromatography indicates that it may be p27Kip1. These observations show how sequentially acting mitogenic signals can combine to promote activation of cell cycle proteins and thereby cause cell proliferation to start. CDK inhibitors have been shown previously to be induced by signals that negatively regulate cell proliferation. Our new observations show that similar proteins are down-regulated by positively acting signals, such as interleukin 2. This finding suggests that both positive and negative growth signals converge on common targets which are regulators of G1 cyclin-CDK complexes. Inactivation of G1 cyclin-CDK inhibitors by mitogenic growth factors may be one biochemical pathway underlying cell cycle commitment at the restriction point in G1.     

Activation of the Cdc42p GTPase by cyclin-dependent protein kinases in budding yeast

Cyclin-dependent kinases (CDKs) trigger essential cell cycle processes including critical events in G1 phase that culminate in bud emergence, spindle pole body duplication, and DNA replication. Localized activation of the Rho-type GTPase Cdc42p is crucial for establishment of cell polarity during G1, but CDK targets that link the Cdc42p module with cell growth and cell cycle commitment have remained largely elusive. Here, we identify the GTPase-activating protein (GAP) Rga2p as an important substrate related to the cell polarity function of G1 CDKs. Overexpression of RGA2 in the absence of functional Pho85p or Cdc28p CDK complexes is toxic, due to an inability to polarize growth. Mutation of CDK consensus sites in Rga2p that are phosphorylated both in vivo and in vitro by Pho85p and Cdc28p CDKs results in a loss of G1 phase-specific phosphorylation. A failure to phosphorylate Rga2p leads to defects in localization and impaired polarized growth, in a manner dependent on Rga2p GAP function. Taken together, our data suggest that CDK-dependent phosphorylation restrains Rga2p activity to ensure appropriate activation of Cdc42p during cell polarity establishment. Inhibition of GAPs by CDK phosphorylation may be a general mechanism to promote proper G1-phase progression.     

Coordinated effects of microRNA-494 induce G₂/M arrest in human cholangiocarcinoma

MicroRNA (miRs) have emerged as salient regulators in cancer homeostasis and, recently, as putative therapeutics. Cholangiocarcinomas (CCA) are aggressive cancers with survival usually measured in months. mRNA arrays followed by pathway analysis revealed that miR-494 is a major modulator of the cell cycle progression from gap 2 (G?) to mitosis (M). We performed fluorescence activated cell sorting (FACS) as well as differential interference contrast (DIC) microscopy, and confirmed that miR-494 induces a significant arrest in G?/M in CCA cells. Furthermore, we verified that miR-494 modulates the protein level of six genes involved in the G?/M transition: Polo-like Kinase 1 (PLK1), pituitary tumor-transforming gene 1 (PTTG1), Cyclin B1 (CCNB1), cell-division cycle 2 (CDC2), cell-division cycle 20 (CDC20) and topoisomerase II α (TOP2A). Next, we identified direct binding of miR-494 to the open reading frame (ORF) and downregulation of PTTG1 and TOP2A. In summary, our findings suggest that miR-494 has a global regulatory role in cell cycle progression, exerted by concerted effects on multiple proteins involved in gap 1 (G?) to synthesis (S), as described previously, as well as G? to M progression. Therefore, it appears that the simultaneous effects of a single miR species on multiple targets along the same canonical pathway is advantageous for the usage of miRs as therapeutics. In addition, our data suggest that miRs act within a narrow range. miR expression above the upper threshold does not appear to induce further effects, which is reassuring in terms of off-target effects of miR surrounding noncancerous tissue.     

Histone deacetylases in Trypanosoma brucei: two are essential and another is required for normal cell cycle progression

Reversible protein acetylation is established as a modification of major regulatory significance. In particular, histone acetylation regulates access to genetic information in eukaryotes. For example, class I and class II histone deacetylases are regulatory components of corepressor complexes involved in cell cycle progression and differentiation. Here, we have investigated the function of such enzymes in Trypanosoma brucei, mono-flagellated parasitic protozoa that branched very early from the eukaryotic lineage. Four T. brucei genes encoding histone deacetylase orthologues have been identified, cloned and characterized. The predicted deacetylases, DAC1-4 are approximately 43, 61, 75 and 64 kDa respectively. They share significant similarity with mammalian and yeast class I (DAC1 and DAC2) and class II (DAC3 and DAC4) histone deacetylases, and all except DAC2 have the critical residues predicted to be required for deacetylase activity. In gene targeting experiments, DAC1 and DAC3 appear to be essential whereas DAC2 and DAC4 are not required for viability. Of the two mutant cell types, the dac4 mutant displays a delay in the G2/M phase of the cell cycle. Our results provide genetic validation of DAC1 and DAC3 as potential chemotherapy targets and demonstrate that T. brucei expresses at least three probable histone deacetylases with distinct function.     

Protein kinase C signaling mediates a program of cell cycle withdrawal in the intestinal epithelium

Members of the protein kinase C (PKC) family of signal transduction molecules have been widely implicated in regulation of cell growth and differentiation, although the underlying molecular mechanisms involved remain poorly defined. Using combined in vitro and in vivo intestinal epithelial model systems, we demonstrate that PKC signaling can trigger a coordinated program of molecular events leading to cell cycle withdrawal into G(0). PKC activation in the IEC-18 intestinal crypt cell line resulted in rapid downregulation of D-type cyclins and differential induction of p21(waf1/cip1) and p27(kip1), thus targeting all of the major G(1)/S cyclin-dependent kinase complexes. These events were associated with coordinated alterations in expression and phosphorylation of the pocket proteins p107, pRb, and p130 that drive cells to exit the cell cycle into G(0) as indicated by concomitant downregulation of the DNA licensing factor cdc6. Manipulation of PKC isozyme levels in IEC-18 cells demonstrated that PKCalpha alone can trigger hallmark events of cell cycle withdrawal in intestinal epithelial cells. Notably, analysis of the developmental control of cell cycle regulatory molecules along the crypt-villus axis revealed that PKCalpha activation is appropriately positioned within intestinal crypts to trigger this program of cell cycle exit-specific events in situ. Together, these data point to PKCalpha as a key regulator of cell cycle withdrawal in the intestinal epithelium.     

G1 block of the cell cycle during differentiation of F9 cells correlates with accumulation of inhibitors of the activity of cyclin-kinase complexes of proteins p21/Waf1 and p27/Kip

F9 teratocarcinoma cells have a very short duration of the cell cycle with a short G1-period typical for early embryonic cells. The cells are capable of differentiating towards parietal endoderm cells after the treatment with retinoic acid (RA) and dibutyryl-cAMP (db-cAMP). This leads to changes in the cell cycle; in particular, G1-period becomes longer, and then differentiated F9 cells leave the cycle to stay in G0-phase. It was previously reported that undifferentiated F9 cells undergo no G1 arrest of the cell cycle after DNA damage (Malashicheva et al., 2000). In the present work mechanisms of accumulation of G1-phase cells during differentiation induced by retinoic acid and db-cAMP were studied. Kinase activity of cyclin-Cdk complexes regulating the G1/S transition was analyzed. In differentiated F9 cells, the activity of cyclin-Cdk complexes, comprising Cdk4 and Cdk2 kinases and cyclins A and E, was significantly decreased. A decrease of Cdk4 kinase activity correlates with a drop of the cyclin D1 content. The amount of p21/Waf1 and p27/Kip inhibitors of the cyclin-kinase complexes increased in differentiated F9 cells. p21/Waf1 protein, which undergoes proteasomal degradation in undifferentiated F9 cells, was shown to be stable in their differentiated derivatives. Besides, in differentiated F9 cells p21/Waf1 and p27/Kip proteins can be detected with Cdk4/Cdk2-cyclin E complexes, in contrast to undifferentiated cells. Thus, we suggest that a G1/G0 block of the cell cycle taking place upon differentiation of F9 cells is likely to be caused by a decrease in cyclin-kinase activity due to stabilization and accumulation of p21/Waf1 and p27/Kip inhibitors and to their ability to associate with Cdk-cyclin complexes.     

Selective inhibition of proteins regulating CDK/cyclin complexes: strategy against cancer—a review

Cancer prevention is a global priority, but history indicates that the journey towards achieving the goal is difficult. Various cyclin dependent kinase complexes (CDKs/cyclins) operate as major cell signaling components in all stages of cell cycle. CDK/cyclin protein complexes, regulating the cell cycle, are conserved during evolution. In cancer cells, cell division is uncontrolled and CDKs/cyclins become ‘check-points’ or targets. Keeping this in view the proteins cyclin C, cyclin D2, CDKN1C, and Growth Arrest and DNA Damage (GADD45α) which play a major role in regulating CDK/cyclin complexes and operate in the initial stages of cell cycle (G₀ phase–S phase), have been identified as promising targets. Targeting critical regulators of cell-cycle signaling components by applying modern computational techniques is projected to be a potential tool for future cancer research.