BRCA1 functions as a differential modulator of chemotherapy-induced apoptosis

We have evaluated the role played by BRCA1 in mediating the phenotypic response to a range of chemotherapeutic agents commonly used in cancer treatment. Here we provide evidence that BRCA1 functions as a differential mediator of chemotherapy-induced apoptosis. Specifically, we demonstrate that BRCA1 mediates sensitivity to apoptosis induced by antimicrotubule agents but conversely induces resistance to DNA-damaging agents. These data are supported by a variety of experimental models including cells with inducible expression of BRCA1, siRNA-mediated inactivation of endogenous BRCA1, and reconstitution of BRCA1-deficient cells with wild-type BRCA1. Most notably we demonstrate that BRCA1 induces a 10-1000-fold increase in resistance to a range of DNA-damaging agents, in particular those that give rise to double-strand breaks such as etoposide or bleomycin. In contrast, BRCA1 induces a >1000-fold increase in sensitivity to the spindle poisons, paclitaxel and vinorelbine. Fluorescence-activated cell sorter analysis demonstrated that BRCA1 mediates G(2)/M arrest in response to both antimicrotubule and DNA-damaging agents. However, poly(ADP-ribose) polymerase and caspase-3 cleavage assays indicate that the differential effect mediated by BRCA1 in response to these agents occurs through the inhibition or induction of apoptosis. Therefore, our data suggest that BRCA1 acts as a differential modulator of apoptosis depending on the nature of the cellular insult.

Desferrioxamine treatment increases the genomic stability of Ataxia-telangiectasia cells

Ataxia-telangiectasia (AT) is an autosomal recessive disorder characterized by genomic instability, chronic oxidative damage, and increased cancer incidence. Compared to normal cells, AT cells exhibit unusual sensitivity to exogenous oxidants, including t-butyl hydroperoxide (t-BOOH). Since ferritin releases labile iron under oxidative stress (which is chronic in AT) and labile iron mediates the toxic effects of t-butyl hydroperoxide, we hypothesized that chelation of intracellular labile iron would increase the genomic stability of AT cells, with and without exogenous oxidative stress. Here we report that desferrioxamine treatment increases the plating efficiency of AT, but not normal cells, in the colony forming-efficiency assay (a method often used to measure genomic stability). Additionally, desferrioxamine increases AT, but not normal cell resistance, to t-butyl hydroperoxide in this assay. Last, AT cells exhibit increased sensitivity to the toxic effects of FeCl(2) in the colony forming-efficiency assay and fail to demonstrate a FeCl(2)-induced G(2) checkpoint response when compared to normal cells. Our data indicates that: (1) chelation of labile iron increases genomic stability in AT cells, but not normal cells; and (2) AT cells exhibit deficits in their responses to iron toxicity. While preliminary, our findings suggest that AT might be, in part, a disorder of iron metabolism and treatment of individuals with AT with desferrioxamine might have clinical efficacy.

Adenosine triphosphate binding cassette (ABC) transporters are expressed and regulated during terminal keratinocyte differentiation: a potential role for ABCA7 in epidermal lipid reorganization

Central aspects of the cellular lipid trafficking mechanisms that occur during keratinocyte differentiation are still not well understood. In the past years, evidence has accumulated to suggest that members of the superfamily of adenosine triphosphate binding cassette (ABC) transporters are critically involved in the transmembrane transport of cellular lipids. To test the hypothesis that ABC molecules are potentially involved in the epidermal transport of sphingolipids, glycerophospholipids, cholesterol, and fatty acids, we performed mRNA expression profiling of all currently known ABC molecules during in vitro differentiation of human keratinocytes and HaCaT cells. We identified six ABC molecules that displayed significant regulation during differentiation of these cells. The recently cloned transporter ABCA7 was highly expressed in keratinocytes and HaCaT cells and upregulated during differentiation. Overexpression of ABCA7 in HeLa cells resulted in increased expression of intracellular and cell surface ceramide and elevated intracellular phosphatidylserine levels. Given the observation that during terminal keratinocyte differentiation intracellular and surface ceramide levels are increased, our results render ABCA7 a candidate regulator of ceramide transport in this process. In addition to ABCA7, the cholesterol transporters ABCB1 and ABCG1 and the glutathione/glucuronide sulfate transporters ABCC1, ABCC3, and ABCC4, were strongly upregulated during keratinocyte and HaCaT cell differentiation. These findings support the notion that ABCB1 and ABCG1 are potentially implicated in cholesterol transport, whereas ABCC1, ABCC3, and ABCC4 are candidate regulators of the translocation of sulfated lipids during stratum corneum keratinization. Our results suggest specific biologic functions for members of the ABC transporter family in epidermal lipid reorganization during terminal keratinocyte differentiation.

A mathematical model for analysis of the cell cycle in cell lines derived from human tumors

The growth of human cancers is characterised by long and variable cell cycle times that are controlled by stochastic events prior to DNA replication and cell division. Treatment with radiotherapy or chemotherapy induces a complex chain of events involving reversible cell cycle arrest and cell death. In this paper we have developed a mathematical model that has the potential to describe the growth of human tumour cells and their responses to therapy. We have used the model to predict the response of cells to mitotic arrest, and have compared the results to experimental data using a human melanoma cell line exposed to the anticancer drug paclitaxel. Cells were analysed for DNA content at multiple time points by flow cytometry. An excellent correspondence was obtained between predicted and experimental data. We discuss possible extensions to the model to describe the behaviour of cell populations in vivo.

Dynamic recruitment of NF-Y and histone acetyltransferases on cell-cycle promoters

Regulation of transcription during the cell-cycle is under the control of E2 factors (E2Fs), often in cooperation with nuclear factor Y (NF-Y), a histone-like CCAAT-binding trimer. NF-Y is paradigmatic of a constitutive, ubiquitous factor that pre-sets the promoter architecture for other regulatory proteins to access it. We analyzed the recruitment of NF-Y, E2F1/4/6, histone acetyltransferases, and histone deacetylase (HDAC) 1/3/4 to several cell-cycle promoters by chromatin immunoprecipitation assays in serum-starved and restimulated NIH3T3 cells. NF-Y binding is not constitutive but timely regulated in all promoters tested, being displaced when promoters are repressed. p300 association correlates with activation, and it is never found in the absence of NF-Y, whereas PCAF/hGCN5 is often found before NF-Y association. E2F4 and E2F6, together with HDACs, are bound to repressed promoters, including the G2/M Cyclin B2. As expected, an inverse relationship between HDACs association and histones H3/H4 acetylation is observed. Blocking cells in G1 with the cyclin-dependent kinase 2 inhibitor R-roscovitine confirms that NF-Y is bound to G1/S but not to G2/M promoters in G1. These data indicate that following the release of E2Fs/HDACs, a hierarchy of PCAF-NF-Y-p300 interactions and H3-H4 acetylations are required for activation of cell-cycle promoters.

Diverse but overlapping functions of the two forkhead-associated (FHA) domains in Rad53 checkpoint kinase activation

Forkhead-associated (FHA) domains are phosphothreonine-binding modules prevalent in proteins with important cell cycle and DNA damage response functions. The yeast checkpoint kinase Rad53 is unique in containing two FHA domains. We have generated novel recessive rad53 alleles with abolished FHA domain functions resulting from Ala substitution of the critical phosphothreonine-binding residues Arg70 and Arg605. In asynchronous cells, inactivation of the N-terminal FHA1 domain did not impair Rad53 activation and downstream functions, whereas inactivation of the C-terminal FHA2 domain led to reduced Rad53 activation and significantly increased DNA damage sensitivity. Simultaneous inactivation of both FHA domains abolished Rad53 activation and all downstream functions and dramatically increased the sensitivity to DNA damage and replication blocks similar to kinase-defective and rad53 null alleles, but did not compromise the essential viability function of Rad53. Interestingly, in G2/M synchronized cells, mutation of either FHA domain prevented Rad53 activation and impaired the cell cycle arrest checkpoint. Our data demonstrate that both FHA domains are required for normal Rad53 functions and indicate that the two FHA domains have differential but partially overlapping roles in Rad53 activation and downstream signaling.

Regulation of the G2/M transition in oocytes of xenopus tropicalis

The molecular events regulating hormone-induced oocyte activation and meiotic maturation are probably best understood in Xenopus laevis. In X. laevis, progesterone activates the G2-arrested oocyte, induces entry into M phase of meiosis I (MI) and resumption of the meiotic cell cycles, and leads to the formation of a mature, fertilizable egg. Oocytes of Xenopus tropicalis offer several practical advantages over those of X. laevis, including faster and more synchronous meiotic cell cycle progression, less seasonal variability, and the availability of transgenic approaches. Previous work found several similarities in the pathways regulating oocyte maturation in the two species. Here, we report several additional ones that are conserved in X. tropicalis. (1). Injection of Mos mRNA into G2-arrested oocytes activates the MAP kinase cascade and induces the G2/MI transition. (2). Injection of the beta subunit of the kinase CK2 (a negative regulator of Mos and oocyte activation) delays the G2/MI transition. (3). Elevating PKA activity blocks progesterone-induced maturation; repressing PKA activity induces entry into MI in the absence of progesterone. (4). LF (anthrax lethal factor), which cleaves certain MAP kinase kinases, strongly reduces both the rate and extent of entry into MI. In contrast to the one previously reported major difference between oocytes of the two species, we find that injection of egg cytoplasm ("MPF activity") into G2-arrested X. tropicalis oocytes induces entry into meiosis I even when protein synthesis is blocked, just as it does in oocytes of X. laevis. These results indicate that much of what we have learned from studies of X. laevis oocytes holds for those of X. tropicalis, and suggest that X. tropicalis oocytes offer a good experimental system for investigating certain questions that require a rapid, synchronous progression through the G2/meiosis I transition.

RLIP, an effector of the Ral GTPases, is a platform for Cdk1 to phosphorylate epsin during the switch off of endocytosis in mitosis

The Ral signaling pathway is critically involved in Ras-dependent oncogenesis. One of its key actors, RLIP/RalBP1, which participates in receptor endocytosis during interphase, is also involved in mitotic processes when endocytosis is switched off. During mitosis, RLIP76 is located on the duplicated centrosomes and is required for their proper separation and movement to the poles. We have looked for actors that associate with RLIP during mitosis. We show here that RLIP/RalBP1 interacts with an active p34cdc2.cyclinB1 (cdk1) enzyme and that this interaction is crucial for the mitotic phosphorylation of Epsin that, once phosphorylated, is no longer competent for endocytosis. We show also that this latter phosphorylation is dependent on Ral signaling. We propose that RLIP/RalBP1 is used as a platform by the mitotic cdk1 to facilitate the phosphorylation of Epsin, which makes Epsin incompetent for endocytosis during mitosis, when endocytosis is switched off.

An overactivated ATR/CHK1 pathway is responsible for the prolonged G2 accumulation in irradiated AT cells

Induction of checkpoint responses in G1, S, and G2 phases of the cell cycle after exposure of cells to ionizing radiation (IR) is essential for maintaining genomic integrity. Ataxia telangiectasia mutated (ATM) plays a key role in initiating this response in all three phases of the cell cycle. However, cells lacking functional ATM exhibit a prolonged G2 arrest after IR, suggesting regulation by an ATM-independent checkpoint response. The mechanism for this ataxia telangiectasia (AT)-independent G2-checkpoint response remains unknown. We report here that the G2 checkpoint in irradiated human AT cells derives from an overactivation of the ATR/CHK1 pathway. Chk1 small interfering RNA abolishes the IR-induced prolonged G2 checkpoint and radiosensitizes AT cells to killing. These results link the activation of ATR/CHK1 with the prolonged G2 arrest in AT cells and show that activation of this G2 checkpoint contributes to the survival of AT cells.

Dynamic behavior of Nuf2-Hec1 complex that localizes to the centrosome and centromere and is essential for mitotic progression in vertebrate cells

Nuf2 and Hec1 are evolutionarily conserved centromere proteins. To clarify the functions of these proteins in vertebrate cells, we characterized them in chicken DT40 cells. We generated GFP fusion constructs of Nuf2 and Hec1 to examine in detail the localization of these proteins during the cell cycle. We found that Nuf2 is associated with Hec1 throughout the cell cycle and that this complex is localized to the centrosomes during G1 and S phases and then moves through the nuclear membrane to the centromere in G2 phase. During mitosis, this complex is localized to the centromere. We also created conditional loss-of-function mutants of Nuf2 and Hec1. In both mutants, the cell cycle arrested at prometaphase, suggesting that the Nuf2-Hec1 complex is essential for mitotic progression. The inner centromere proteins CENP-A, -C, and -H and checkpoint protein BubR1 were localized to chromosomes in the mutant cells arrested at prometaphase, but Mad2 localization was abolished. Furthermore, photobleaching experiments revealed that the Nuf2-Hec1 complex is stably associated with the centromere and that interaction of this complex with the centrosome is dynamic.

Inhibition of topoisomerase II overrides the G2/M check points of the cell cycle in EBV-lymphocytes

Epstein-Barr virus (EBV) is associated with a number of human malignancies. In vitro EBV infection transforms human lymphocytes into proliferating cell lines (EBV-lymphocytes). Etoposide, topoisomerase II inhibitor, induced apoptosis in EBV-lymphocytes as shown by expression of phosphatidylserine, loss of DNA and mitochondrial membrane potential, and cell shrinkage. In contrast, those cells, which had yet to display signs of apoptosis, grew to exceed their normal size. These EBV-lymphocytes had unusual cellular and nuclear morphology, higher mitochondrial membrane potential, increased expression of proteins and an amount of DNA that exceeded the maximum DNA content in normal EBV-lymphocytes by more than two-fold. Application of the caspase inhibitor Z-VAD-FMK in the presence of etoposide increased the numbers of such large cells. This data suggests that inhibition of topoisomerase II by etoposide does not inhibit DNA synthesis but rather overrides the G(2)/M check points of the cell cycle, resulting in cells growth over their genetically determined size. This may trigger apoptosis to eliminate cells, which failed to complete mitosis.

DNA damage during the spindle-assembly checkpoint degrades CDC25A, inhibits cyclin-CDC2 complexes, and reverses cells to interphase

Cell cycle checkpoints that monitor DNA damage and spindle assembly are essential for the maintenance of genetic integrity, and drugs that target these checkpoints are important chemotherapeutic agents. We have examined how cells respond to DNA damage while the spindle-assembly checkpoint is activated. Single cell electrophoresis and phosphorylation of histone H2AX indicated that several chemotherapeutic agents could induce DNA damage during mitotic block. DNA damage during mitotic block triggered CDC2 inactivation, histone H3 dephosphorylation, and chromosome decondensation. Cells did not progress into G1 but seemed to retract to a G2-like state containing 4N DNA content, with stabilized cyclin A and cyclin B1 binding to Thr14/Tyr15-phosphorylated CDC2. The loss of mitotic cells was not due to cell death because there was no discernible effect on caspase-3 activation, DNA fragmentation, or viability. Extensive DNA damage during mitotic block inactivated cyclin B1-CDC2 and prevented G1 entry when the block was removed. The mitotic DNA damage responses were independent of p53 and pRb, but they were dependent on ATM. CDC25A that accumulated during mitosis was rapidly destroyed after DNA damage in an ATM-dependent manner. Ectopic expression of CDC25A or nonphosphorylatable CDC2 effectively inhibited the dephosphorylation of histone H3 after DNA damage. Hence, although spindle disruption and DNA damage provide conflicting signals to regulate CDC2, the negative regulation by the DNA damage checkpoint could overcome the positive regulation by the spindle-assembly checkpoint.

G2 arrest in response to topoisomerase II inhibitors: the role of p53

We have previously found that the overexpression of p53 causes G(2) arrest and represses the synthesis of cyclin-dependent kinase 1 and cyclin B1, two proteins required for cells to traverse from G(2) into M. G(2) arrest occurs in response to DNA damage caused by a variety of agents and treatments. Here, we investigate the role of p53 in the G(2) arrest that occurs in response to the topoisomerase inhibitors etoposide and merbarone. In HT1080 cells expressing a dominant-negative form of p53, treatment with etoposide still caused G(2) arrest, but the arrest could be overcome by additional treatment with caffeine, which inhibits the damage-responsive kinases ataxia telangiectasia mutated (ATM) and atm and rad3-related (ATR). However, caffeine could not overcome etoposide-induced G(2) arrest in HT1080 cells with functional p53. We conclude that etoposide activates two pathways, one of which depends on p53 and the other of which is sensitive to caffeine, and that either pathway is sufficient to activate G(2) arrest. Etoposide inhibits topoisomerase II by trapping the enzyme in a complex with cleaved DNA. Inhibition of topoisomerase II with merbarone, which does not stabilize a cleavage complex, causes G(2) arrest by a checkpoint that monitors the decatenation of chromatin. We find that caffeine can abrogate merbarone-induced G(2) arrest even in cells with functional p53, indicating that p53 does not contribute to the decatenation-sensitive response. Thus, p53 has a differential role in effecting G(2) arrest in response to topoisomerase II inhibitors, depending upon the mechanisms of action of the inhibitors tested.

Regulation of Cdc2/cyclin B activation in Xenopus egg extracts via inhibitory phosphorylation of Cdc25C phosphatase by Ca(2+)/calmodulin-dependent protein [corrected] kinase II

Activation of Cdc2/cyclin B kinase and entry into mitosis requires dephosphorylation of inhibitory sites on Cdc2 by Cdc25 phosphatase. In vertebrates, Cdc25C is inhibited by phosphorylation at a single site targeted by the checkpoint kinases Chk1 and Cds1/Chk2 in response to DNA damage or replication arrest. In Xenopus early embryos, the inhibitory site on Cdc25C (S287) is also phosphorylated by a distinct protein kinase that may determine the intrinsic timing of the cell cycle. We show that S287-kinase activity is repressed in extracts of unfertilized Xenopus eggs arrested in M phase but is rapidly stimulated upon release into interphase by addition of Ca2+, which mimics fertilization. S287-kinase activity is not dependent on cyclin B degradation or inactivation of Cdc2/cyclin B kinase, indicating a direct mechanism of activation by Ca2+. Indeed, inhibitor studies identify the predominant S287-kinase as Ca2+/calmodulin-dependent protein kinase II (CaMKII). CaMKII phosphorylates Cdc25C efficiently on S287 in vitro and, like Chk1, is inhibited by 7-hydroxystaurosporine (UCN-01) and debromohymenialdisine, compounds that abrogate G2 arrest in somatic cells. CaMKII delays Cdc2/cyclin B activation via phosphorylation of Cdc25C at S287 in egg extracts, indicating that this pathway regulates the timing of mitosis during the early embryonic cell cycle.

Cyclin-dependent kinases and S phase control in mammalian cells

Mammalian DNA replication is an elegantly choreographed process in which multiple components are assembled at the origins to form the prereplication complex. Formation and activation of the prereplication complex requires coordinate actions of G1and S phase cyclin-dependent kinases. Cyclin E-CDK2 and cyclin A-CDK2, together with DBF4-CDC7, phosphorylate several components of the prereplication complex and replication machinery. In this review, we summarize the current understanding of the mechanism of initiation of DNA replication in mammalian cells. The roles of cyclin A/E-CDK2 complexes in driving replication, their relationship with other regulators of S phase, and their role in keeping replication to only once per cell cycle will be discussed. In addition, an important issue is the checks and balances that prevent inappropriate DNA replication, and how a breakdown in these checkpoints can lead to genomic instability and cancer. A critical mediator of these checkpoints, ATM, signals through a comprehensive network of proteins leading to CDK2 inhibition thus preventing DNA synthesis. This will be reviewed in addition to other mechanisms involved in the intra-S phase DNA damage checkpoint.

Requirement for phosphatidylinositol-3 kinase activity during progression through S-phase and entry into mitosis

Phosphatidylinositol-3 kinase (PI3K) proteins are important regulators of cell survival and proliferation. PI3K-dependent signalling regulates cell proliferation by promoting G1- to S-phase progression during the cell cycle. However, a definitive role for PI3K at other times during the cell cycle is less clear. In these studies, we provide evidence that PI3K activity is required during DNA synthesis (S-phase) and G2-phase of the cell cycle. Inhibition of PI3K with LY294002 at the onset of S-phase caused a 4- to 5-h delay in progression through G2/M. LY294002 treatment at the end of S-phase caused an approximate 2-h delay in progression through G2/M, indicating that PI3K activity functions for both S- and G2-phase progression. The expression of constitutively activated Akt partially reversed the inhibitory effects of LY294002 on mitotic entry, which demonstrated that Akt was one PI3K target that was required during G2/M transitions. Inhibition of PI3K resulted in enhanced susceptibility of G2/M synchronized cells to undergo apoptosis in response to DNA damage as compared to asynchronous cells. Thus, similar to its role in promoting cell survival and cell cycle transitions from G1 to S phase, PI3K activity appears to promote entry into mitosis and protect against cell death during S- and G2-phase progression.

SAPK/JNK regulates cdc2/cyclin B kinase through phosphorylation and inhibition of cdc25c

Cells undergo M phase arrest in response to stresses like UV irradiation or DNA damage. Stress-activated protein kinase (SAPK, also known as c-Jun N-terminal kinase, JNK) is activated by such stress stimuli. We addressed the potential effects of SAPK activation on cell cycle regulatory proteins. Activation of SAPK strongly correlated with inhibition of cdc2/cyclin B kinase, an important regulator of G2/M phase. SAPK directly phosphorylated the cdc2 regulator, cdc25c, in vitro on serine 168 (S168). This residue was highly phosphorylated in vivo in response to stress stimuli. cdc25c phosphorylated on S168 in cells lacks phosphatase activity, and expression of a S168A mutant of cdc25c reversed the inhibition of cdc2/cyclin B kinase activity by cell stress. Antibodies directed against phosphorylated S168 detect increased phosphorylation of S168 after cell stress. We conclude that SAPK regulates cdc2/cyclin B kinase following stress events by a novel mechanism involving inhibitory phosphorylation of the cdc2-activating phosphatase cdc25c on S168.

PPARgamma ligands inhibit cholangiocarcinoma cell growth through p53-dependent GADD45 and p21 pathway

Ligands of peroxisome proliferator-activated receptor-gamma (PPARgamma) induce differentiation and growth inhibition in several human cancers. However, the role of PPARgamma ligands in the growth control of human cholangiocarcinoma cells remains unknown. This study was designed to investigate the biological functions and molecular mechanisms of PPARgamma ligands in the growth regulation of human cholangiocarcinoma cells. Western blot analysis showed that PPARgamma is expressed in all of the three human cholangiocarcinoma cell lines used in this study (SG231, CC-LP-1, and HuCCT1). Transient transfection assays using a peroxisome proliferator response element (PPRE) reporter construct showed that the PPARgamma expressed in human cholangiocarcinoma cells is functional as a transcription activator. Exposure of SG231, CC-LP-1, and HuCCT1 cells to PPARgamma ligands 15-deoxy-delta12, 14-prostaglandin J(2) (15d-PGJ(2)) and troglitazone for 24 to 96 hours resulted in a dose-dependent inhibition of cell growth. Flow cytometry analysis showed that 15d-PGJ(2) and troglitazone-induced cell cycle arrest at the G2/M checkpoint. Consistent with these findings, both 15d-PGJ(2) and troglitazone significantly inhibited the G2/M cyclin-dependent kinase (CDK) Cdc2 activity. Furthermore, cells treated with 15d-PGJ(2) and troglitazone showed elevated expression of p53 and two p53-controlled downstream genes, GADD45 and p21(WAF1/Cip1). Dominant negative inhibition of p53 in SG231 cells significantly blocked the 15d-PGJ(2) and troglitazone-induced growth inhibition, G2/M arrest, and GADD45/p21 induction. 15d-PGJ(2) and troglitazone failed to directly inhibit Cdc2 activity in a cell-free system in spite of direct association between GADD45 and PPARgamma proteins. In conclusion, these results show a novel p53-dependent mechanism in the PPARgamma ligand-mediated inhibition of cholangiocarcinoma growth and suggest a potential therapeutic role of PPARgamma ligands in the treatment of human cholangiocarcinoma.

Beta-catenin regulation during the cell cycle: implications in G2/M and apoptosis

Beta-catenin is a multifunctional protein involved in cell-cell adhesion and Wnt signal transduction. Beta-catenin signaling has been proposed to act as inducer of cell proliferation in different tumors. However, in some developmental contexts and cell systems beta-catenin also acts as a positive modulator of apoptosis. To get additional insights into the role of beta-catenin in the regulation of the cell cycle and apoptosis, we have analyzed the levels and subcellular localization of endogenous beta-catenin and its relation with adenomatous polyposis coli (APC) during the cell cycle in S-phase-synchronized epithelial cells. Beta-catenin levels increase in S phase, reaching maximum accumulation at late G2/M and then abruptly decreasing as the cells enter into a new G1 phase. In parallel, an increased cytoplasmic and nuclear localization of beta-catenin and APC is observed during S and G2 phases. In addition, strong colocalization of APC with centrosomes, but not beta-catenin, is detected in M phase. Interestingly, overexpression of a stable form of beta-catenin, or inhibition of endogenous beta-catenin degradation, in epidermal keratinocyte cells induces a G2 cell cycle arrest and leads to apoptosis. These results support a role for beta-catenin in the control of cell cycle and apoptosis at G2/M in normal and transformed epidermal keratinocytes.

Mitogen-activated protein kinase stimulation of Ca(2+) signaling is required for survival of endoplasmic reticulum stress in yeast

Endoplasmic reticulum (ER) stress in the budding yeast Saccharomyces cerevisiae triggers Ca2+ influx through a plasma membrane channel composed of Cch1 and Mid1. This response activates calcineurin, which helps to prevent cell death during multiple forms of ER stress, including the response to azole-class antifungal drugs. Herein, we show that ER stress activates the cell integrity mitogen-activate protein kinase cascade in yeast and that the activation of Pkc1 and Mpk1 is necessary for stimulation of the Cch1-Mid1 Ca2+ channel independent of many known targets of Mpk1 (Rlm1, Swi4, Swi6, Mih1, Hsl1, and Swe1). ER stress generated in response to miconazole, tunicamycin, or other inhibitors also triggered a transient G2/M arrest that depended upon the Swe1 protein kinase. Calcineurin played little role in the Swe1-dependent cell cycle arrest and Swe1 had little effect on calcineurin-dependent avoidance of cell death. These findings help to clarify the interactions between Mpk1, calcineurin, and Swe1 and suggest that the calcium cell survival pathway promotes drug resistance independent of both the unfolded protein response and the G2/M cell cycle checkpoint.

Both DNA topoisomerase II-binding protein 1 and BRCA1 regulate the G2-M cell cycle checkpoint

Cell cycle checkpoints play a central role in genomic stability. The human DNA topoisomerase II-binding protein 1 (TopBP1) protein contains eight BRCA1 COOH terminus motifs and shares similarities with Cut5, a yeast checkpoint Rad protein. TopBP1 also shares many features with BRCA1. We report that, when expression of TopBP1 protein is inhibited in BRCA1 mutant cells, mimicking a TopBP1, BRCA1 double-negative condition, the G(2)-M checkpoint is strongly abrogated and apoptosis is increased after ionizing radiation. However, a BRCA1-negative or a TopBP1-negative background resulted in only partial abrogation of the G(2)-M checkpoint. The BRCA1 mutant and TopBP1-reduced condition specifically destroys regulation of the Chk1 kinase but not the Chk2 kinase, suggesting involvement in the ataxia telangiectasia-related pathway. These results indicate that both TopBP1 and BRCA1 specifically regulate the G(2)-M checkpoint, partially compensating each function.

The G2-phase decatenation checkpoint is defective in Werner syndrome cells

It has been proposed that cells monitor chromatid catenation status after DNA replication and inhibit progression into mitosis until chromatids are correctly decatenated by topoisomerase II (TopoII). Studies in yeast have suggested that TopoII may interact with RecQ helicases during this process. Using ICRF187, a TopoII catalytic inhibitor that prevents chromatid decatenation without producing DNA strand breaks, we demonstrated that cells deficient of WRN, a human RecQ helicase, displayed a defect in decatenation checkpoint activation, which was corrected by ectopic expression of wild-type WRN. We also provide evidence that BRCA1 is phosphorylated in an ATR-dependent manner in response to decatenation checkpoint activation and that this phosphorylation is not detectable in Werner syndrome cells. Furthermore, ICRF187 treatment resulted in coimmunoprecipitation of WRN and TopoII. Finally, we demonstrated that override of the decatenation checkpoint resulted in enhanced chromosomal damage and apoptosis only in the absence of WRN, but not in normal cells. Our findings suggest that WRN plays a role in the activation of G(2) decatenation checkpoint and that the abortive function of this pathway itself does not appear to be sufficient to cause genomic instability but rather predisposes to genomic instability and apoptotic cell death in the absence of other "caretaker" genes, such as WRN.

A PHO80-like cyclin and a B-type cyclin control the cell cycle of the procyclic form of Trypanosoma brucei

Cyclins bind and activate cyclin-dependent kinases that regulate cell cycle progression in eukaryotes. Cell cycle control in Trypanosoma brucei was analyzed in the present study. Genes encoding four PHO80 cyclin homologues and three B-type cyclin homologues but no G1 cyclin homologues were identified in this organism. Through knocking down expression of the seven cyclin genes with the RNA interference technique in the procyclic form of T. brucei, we demonstrated that one PHO80 homologue (CycE1/CYC2) and a B-type cyclin homologue (CycB2) are the essential cyclins regulating G1/S and G2/M transitions, respectively. This lack of overlapping cyclin function differs significantly from that observed in the other eukaryotes. Also, PHO80 cyclin is known for its involvement only in phosphate signaling in yeast with no known function in cell cycle control. Both observations thus suggest the presence of simple and novel cell cycle regulators in trypanosomes. T. brucei cells deficient in CycE1/CYC2 displayed a long slender morphology, whereas those lacking CycB2 assumed a fat stumpy form. These cells apparently still can undergo cytokinesis generating small numbers of anucleated daughter cells, each containing a single kinetoplast known as a zoid. Two different types of zoids were identified, the slender zoid derived from reduced CycE1/CYC2 expression and the stumpy zoid from CycB2 deficiency. This observation indicates an uncoupling between the kinetoplast and the nuclear cycle, resulting in cell division driven by kinetoplast segregation with neither a priori S phase nor mitosis in the trypanosome.

The Chk2 tumor suppressor is not required for p53 responses in human cancer cells

Ionizing radiation damages chromosomal DNA and activates p53-dependent transcription in mammalian cells. The Chk2 protein kinase has been hypothesized to be the primary mediator of this response. We have rigorously tested this hypothesis in human cells by disrupting the CHK2 gene through homologous recombination. We found that the p53 response was unexpectedly robust in such cells. Phosphorylation of p53 at serine 20, accumulation of p53 protein, transcriptional activation of p53 target genes, and cell cycle arrest and apoptotic death phenotypes were completely intact regardless of CHK2 status. Our results indicate that Chk2 kinase is not required for p53 activation in human cells and explain why CHK2 and TP53 mutations can jointly occur in human tumors.

Cell-cycle responses to DNA damage in G2

Cellular reproduction, at its basic level, is simply the passing of genetic information from a single parent cell into two daughter cells. As the cellular genome encodes all the information that defines a cell, it is crucial that the genome be accurately replicated. Furthermore, the duplicated genome must be properly segregated so that each daughter cell contains the exact same information as the parent cell. The processes by which this occurs is known as the cell cycle. The failure of either duplication or segregation of the genome can have disastrous consequences for an organism, including cancer and death. This article discusses what is known about checkpoints, the surveillance mechanisms that monitor both the fidelity and accuracy of DNA replication and segregation. Specifically, we will focus on the G2 checkpoint that is responsible for ensuring proper segregation of the duplicated genome into the daughter cells and how this checkpoint functions to arrest entry into mitosis in response to DNA damage.