Oncogenic c-H-ras deregulates survivin expression: an improvement for survival

Survivin protein accomplishes two basic functions: cell cycle regulation and control of apoptosis. It is only expressed in G2/M phase and it influences rescue pathways in apoptosis-induced cells. Overexpression of constitutive active c-H-ras in HeLa, or induction of c-H-ras in a stable HeLaDiR cell line, led to sustained survivin expression in all cell cycle phases and even protected cells from drug induced apoptosis. siRNA-mediated silencing of survivin reversed this protection. Here we link the anti-apoptotic property of survivin to its cell cycle (in)dependent regulation via the activity of oncogenic c-H-ras.     

Integrative genomics based identification of potential human hepatocarcinogenesis-associated cell cycle regulators: RHAMM as an example

DNA microarray has been widely used to examine gene expression profile of different human tumors. The information generated from microarray analysis usually represents the overall range of cancer-associated abnormality associated with gene regulation. In order to identify key regulatory genes involved in carcinogenesis of human cancer, hypothesis driven data mining of the microarray data plus experimental validation becomes a critical approach in the post-genome era. Here, we present an integrative genomic analysis of published microarray data and homolog gene database. Over 20,000 genes were examined to reveal 16 genes specific to vertebrates, cell cycle G2/M regulated, and overexpressed in human HCC. Using Affymetrix microarray analysis, we found that all 16 genes were up-regulated in human HCC. Among these 16 genes, we experimentally validated the up-regulation of receptor for hyaluronan-mediated motility (RHAMM) in different cell model systems. We first confirmed elevation of RHAMM in the G2/M phase of synchronized HeLa cells. We also found that RHAMM had an elevated level of expression in all the HCC samples we examined and it was induced during the G2/M phase of regenerating mouse hepatocytes after partial hepatectomy. Thus, the expression of RHAMM appears to be tightly regulated during mammalian cell cycle G2/M progression. The ectopic overexpression of RHAMM in 293T cells resulted in the accumulation of cells at G2/M phase. RHAMM-induced mitotic arrest of cells was predominantly in the prophase. Taken together, using an integrated functional genomic approach, we have uncovered a set of genes that may play specific roles in cell cycle progression and in HCC development. To elucidate the function of these genes in cell cycle regulation may shed light on the control mechanism of human HCC in the future.     

Hemopoietic cell transformation is associated with failure to downregulate glucose uptake during the G2/M phase of the cell cycle

Growth factors and cytokines initiate multiple signal transduction pathways that lead to cell survival, cell cycle progression or differentiation. A common feature of these pathways is increased cellular metabolism and glucose uptake. Furthermore, the energy requirements of many cancers and transformed cell lines are met by constitutive upregulation of glucose uptake. Relationships among transforming events, glucose uptake and cell cycle progression are not well understood. Here we investigated the regulation of glucose transport during the cell cycle of growth factor-dependent 32D cells, primary T-cells, src-transformed 32D cells and Jurkat cells. Cells were enriched in the G1, S and G2/M phases of the cell cycle, and glucose transporter expression and 2-deoxyglucose uptake were measured. Glucose transporter expression increased with cell volume as cells progressed through the cell cycle. Growth factor-dependent 32D cells and T-lymphocytes were characterised by increased 2-deoxyglucose uptake from G1 to S and reduced uptake at G2/M, with the highest specific activity of transporters in the S phase. In contrast, src-transformed 32D cells and Jurkat cells showed increased 2-deoxyglucose uptake from S to G2/M, with the highest glucose transporter specific activity in G2/M. Our results show that glucose transport is regulated in a cell cycle-dependent manner and suggest that this regulation may be altered in transformed cells.     

Antizyme1基因转染对K562细胞增殖与凋亡的影响

研究鸟氨酸脱羧酶抗酶蛋白对人红白血病K562细胞增殖、三氧化二砷（ As2O3）诱导凋亡时的影响。方法: 定点突变技术构建缺失frameshift位点的pEGFP-N1-AZ1-mutation重组表达载体。脂质体法转染K562细胞,通过G418筛选获得稳定表达antizyme1的K562pAZ1m细胞系。采用不同浓度的As2O3处理细胞,通过MTT法检测细胞增殖,流式细胞术分析细胞周期及凋亡变化。并通过RT-PCR方法检测antiyme1转染对cyclin D1和survivin基因表达的影响。结果：获得稳定表达antizyme1的K562-AZ1m细胞株后,其增殖能力明显减慢。CyclinD1基因表达降低,细胞主要停滞于G0/G1期。在 As2O3的诱导作用下,细胞凋亡增多,survivin基因表达降低。结论：AZ1基因能够抑制K562细胞增殖,通过对cyclinD1的负调控使细胞周期停滞于G0/G1期。并可能通过下调survivin表达来加强 As2O3对其的诱导凋亡作用     

Expression of the Argonaute protein PiwiL2 and piRNAs in adult mouse mesenchymal stem cells

Piwi (P-element-induced wimpy testis) first discovered in Drosophila is a member of the Argonaute family of micro-RNA binding proteins with essential roles in germ-cell development. The murine homologue of PiwiL2, also known as Mili is selectively expressed in the testes, and mice bearing targeted mutations of the PiwiL2 gene are male-sterile. PiwiL2 proteins are thought to protect the germ line genome by suppressing retrotransposons, stabilizing heterochromatin structure, and regulating target genes during meiosis and mitosis. Here, we report that PiwiL2 and associated piRNAs (piRs) may play similar roles in adult mouse mesenchymal stem cells. We found that PiwiL2 is expressed in the cytoplasm of metaphase mesenchymal stem cells from the bone marrow of adult and aged mice. Knockdown of PiwiL2 with a specific siRNA enhanced cell proliferation, significantly increased the number of cells in G1/S and G2/M cell cycle phases and was associated with increased expression of cell cycle genes CCND1, CDK8, microtubule regulation genes, and decreased expression of tumor suppressors Cables 1, LATS, and Cxxc4. The results suggest broader roles for Piwi in genome surveillance beyond the germ line and a possible role in regulating the cell cycle of mesenchymal stem cells.     

Effects of p21 Gene Down-Regulation through RNAi on Antler Stem Cells In Vitro

Cell cycle is an integral part of cell proliferation, and consists mainly of four phases, G1, S, G2 and M. The p21 protein, a cyclin dependent kinase inhibitor, plays a key role in regulating cell cyclevia G1 phase control. Cells capable of epimorphic regeneration have G2/M accumulation as their distinctive feature, whilst the majority of somatic cells rest at G1 phase. To investigate the role played byp21 in antler regeneration, we studied the cell cycle distribution of antler stem cells (ASCs), via down-regulation of p21 in vitro using RNAi. The results showed that ASCs had high levels of p21 mRNA expression and rested at G1 phase, which was comparable to the control somatic cells. Down-regulation of p21 did not result in ASC cell cycle re-distribution toward G2/M accumulation, but DNA damage and apoptosis of the ASCs significantly increased and the process of cell aging was slowed. These findings suggest that the ASCs may have evolved to use an alternative, p21-independent cell cycle regulation mechanism. Also a unique p21-dependent inhibitory effect may control DNA damage as a protective mechanism to ensure the fast proliferating ASCs do not become dysplastic/cancerous. Understanding of the mechanism underlying the role played by p21 in the ASCs could give insight into a mammalian system where epimorphic regeneration is initiated whilst the genome stability is effectively maintained.     

Survivin reduces activation-induced T cell death in G1 phase

A process termed activation-induced cell death (AICD) is responsible for peripheral T cell tolerance after negative selection of self-reactive T cells, and deletion of hyperactivated T cells following the immune response. Cells in G1 phase of the cell cycle are most susceptible to AICD. We have investigated the relationship between the induction of AICD by phorbol 12-myristate 13-acetate plus ionomycin during the cell cycle and the expression of survivin, an inhibitor of the apoptosis protein (LAP) family. AICD was highly induced in cells of the human T cell line Jurkat E6.1 arrested in G1 phase, whereas survivin was hardly expressed in G1 and instead it was highly expressed in G2/M. Moreover, transient over-expression of survivin in G1 partially blocked the induction of AICD. These results suggest that survivin inhibits the induction of AICD, especially in G1 phase.     

Effects of the dilution rate on cell cycle distribution and PEI-mediated transient gene expression by CHO cells in continuous culture

In this study, a continuous culture system was applied to mammalian cells on large scale, and polyethyleneimine (PEI) mediated transient gene expression (TGE). PEI MAX 40,000 was chosen as a superior reagent from three types of PEI. The cell cycle distribution of cells in batch and continuous cultures was determined, in which the effects of cell cycle distribution on transfection efficiency, post-transfection proliferation and recombinant prothrombin expression were evaluated. Compared with cells from end-log and plateau phase in batch culture, cells from mid-log phase possessed a larger fraction of S and G2/M phase cells and a smaller fraction of G1 phase cells. In the continuous culture, the fraction of cells in the S and G2/M phases increased and the fraction of cells in the G1/G0 phase decreased with increasing dilution rates. Cells from the continuous culture run at highest dilution rate had excellent proliferation, transfection efficiency and protein expression. These results were confirmed by transfecting cells synchronized to different phases. The G2/M arrested cells exhibited a nearly 10-fold increase in recombinant human prothrombin production relative to that of non-dividing cells. The use of continuous culture for large scale transfection demonstrated a better cell physiological state for TGE process.     

Parathyroid hormone and the regulation of cell cycle in colon adenocarcinoma cells

Parathyroid hormone (PTH) functions as a major mediator of bone remodeling and as an essential regulator of calcium homeostasis. In this study, we investigated the role of PTH in the regulation of the cell cycle in human colon adenocarcinoma Caco-2 cells. Flow cytometry analysis revealed that PTH (10^− 8 M, 12-24 h) treatment increases the number of cells in the G0/G1 phase and diminishes the number in both phases S and G2/M. In addition, analysis by Western blot showed that the hormone increases the expression of the inhibitory protein p27Kip1 and diminishes the expression of cyclin D1, cyclin D3 and CDK6. However, the amounts of CDK4, p21Cip1, p15INK4B and p16INK4A were not different in the absence or presence of PTH. Inhibitors of PKC (Ro-318220, bisindolylmaleimide and chelerythine), but not JNK (SP600125) and PP2A (okadaic acid and calyculin A), reversed PTH response in Caco-2 cells. Taken together, our results suggest that PTH induces G0/G1 phase arrest of Caco-2 intestinal cells and changes the expression of proteins involved in cell cycle regulation via the PKC signaling pathway.     

Differential effect of heme oxygenase-1 in endothelial and smooth muscle cell cycle progression

Arterial remodeling in response to pathological insult is a complex process that depends in part on the balance between vascular cell apoptosis and proliferation. Studies in experimental models suggest that HO-1 mediates neointimal formation while limiting lumen stenosing, indicating a differential effect on vascular endothelial (EC) and smooth muscle cells (SMC). We investigated the effect of HO-1 expression on cell cycle progression in EC and SMC. The addition of SnMP (10 microM), an inhibitor of HO activity, to EC or SMC for 24h, resulted in significant abnormalities in DNA distribution and cell cycle progression compared to cells treated with the HO-1 inducers, heme (10 microM) or SnCl(2) (10 microM). SnMP increased G(1) phase and decreased S and G(2)/M phases in EC while heme or SnCl(2) decreased G(1) phase, but increased S and G(2)/M phases (p<0.05). Opposite effects were obtained in SMC. SnMP decreased G(1) phase and increased S and G(2)/M phases while heme or SnCl(2) increased G(1) phase but decreased S and G(2)/M phases (p<0.05). Our data demonstrate that HO-1 regulates the cell cycle in a cell-specific manner; it increases EC but decreases SMC cycle progression. The mechanisms underlying the HO-1 cell-specific effect on cell cycle progression within the vascular wall are yet to be explored. Nevertheless, these findings suggest that cell-specific targeting of HO-1 expression may provide a novel therapeutic strategy for the treatment of cardiovascular diseases.     

Induction of survivin expression by taxol (paclitaxel) is an early event, which is independent of taxol-mediated G2/M arrest

Survivin is a novel anti-apoptotic protein that is highly expressed in cancer but is undetectable in most normal adult tissues. It was reported that taxol-mediated mitotic arrest of cancer cells is associated with survivin induction, which preserves a survival pathway and results in resistance to taxol. In this study, we provide new evidence that induction of survivin by taxol is an early event and is independent of taxol-mediated G(2)/M arrest. Taxol treatment of MCF-7 cells rapidly up-regulated survivin expression (3.5-15-fold) within 4 h without G(2)/M arrest. Lengthening the treatment of cells (48 h) with taxol resulted in decreased survivin expression in comparison with early times following taxol treatment, although G(2)/M cells were significantly increased at later times. Interestingly, 3 nm taxol induces survivin as effectively as 300 nm and more effectively than 3000 nm. As a result, 3 nm taxol is ineffective at inducing cell death. However, inhibition of taxol-mediated survivin induction by small interfering RNA significantly increased taxol-mediated cell death. Taxol rapidly activated the phosphatidylinositol 3-kinase/Akt and MAPK pathways. Inhibition of these pathways diminished survivin induction and sensitized cells to taxol-mediated cell death. A cis-acting DNA element upstream of -1430 in the survivin pLuc-2840 construct is at least partially responsible for taxol-mediated survivin induction. Together, these data show, for the first time, that taxol-mediated induction of survivin is an early event and independent of taxol-mediated G(2)/M arrest. This appears to be a new mechanism for cancer cells to evade taxol-induced apoptosis. Targeting this survival pathway may result in novel approaches for cancer therapeutics.     

Regulation of survivin by retinoic acid and its role in paclitaxel-mediated cytotoxicity in MCF-7 breast cancer cells

The chemotherapeutic drug paclitaxel induces microtubular stabilization and mitotic arrest associated with increased survivin expression. Survivin is a member of the inhibitor of apoptosis (iap) family which is highly expressed in during G2/M phase where it regulates spindle formation during mitosis. It is also constitutively overexpressed in most cancer cells where it may play a role in chemotherapeutic resistance. MCF-7 breast cancer cells stably overexpressing the sense strand of survivin (MCF-7(survivin-S) cells) were more resistant to paclitaxel than cells depleted of survivin (MCF-7(survivin-AS) despite G2/M arrest in both cell lines. However, survivin overexpression did not protect cells relative to control MCF-7(pcDNA3) cells. Paclitaxel-induced cytotoxicity can be enhanced by retinoic acid and here we show that RA strongly reduces survivin expression in MCF-7 cells and prevents paclitaxel-mediated induction of survivin expression. Mitochondrial release of cytochrome c after paclitaxel alone or in combination with RA was weak, however robust Smac release was observed. While RA/paclitaxel-treated MCF-7 (pcDNA3) cultures contained condensed apoptotic nuclei, MCF-7(survivin-S) nuclei were morphologically distinct with hypercondensed disorganized chromatin and released mitochondrial AIF-1. RA also reduced paclitaxel-associated levels of cyclin B1 expression consistent with mitotic exit. MCF-7(survivin-S) cells displayed a 30% increase in >2N/<4N ploidy while there was no change in this compartment in vector control cells following RA/paclitaxel. We propose that RA sensitizes MCF-7 cells to paclitaxel at least in part through survivin downregulation and the promotion of aberrant mitotic progression resulting in apoptosis. In addition we provide biochemical and morphological data which suggest that RA-treated MCF-7(survivin-S) cells can also undergo catastrophic mitosis when exposed to paclitaxel.     

CENP—B的基因表达与细胞周期关系的研究

本文以HeLa细胞为材料研究一种着丝粒蛋白CENP-B的基因表达与细胞周期及细胞核骨架的关系。将HeLa细胞同步在不同周期时相,以流式细胞光度术、同位素掺入和ACA着丝粒染色等方法检测细胞同步化效果。我们分别提取了各周期时相细胞的总RNA和Poly(A)~ RNA,用Dot blot和Northern blot杂交方法研究CENP-B在细胞周期中的表达。结果表明,CENP-B基因在细胞周期中的各个时相均有表达,但表达的强度差别很大:G2期表达最强,S期最弱,G1期中的表达介于二者之间;有意义的是CENP-B基因在M期仍然有较强的表达,表现出其在细胞周期中表达的持续性;这种表达的持续性反映了一种可能性:着丝粒、动粒蛋白不断合成,但直到S期后进入G2期时着丝粒、动粒蛋白到一定临界浓度时才开始组装新的动粒。另外,着丝粒、动粒蛋白的持续合成对着丝粒、动粒功能的发挥可能是必需的。用Bam H I限制性内切酶消化处于不同细胞周期时相的HeLa细胞核骨架,提取与核骨架紧密结合的DNA,用~(32)P标记的cDNA为探针研究CENP-B基因与细胞核骨架的结合与其表达的关系。结果证明,在G2期细胞中CENP-B基因表达最强,与细胞核骨架结合最为紧密,G1期细胞中次之,S期中CENP-B基因与核骨架结合最弱,说明CENP-B基因与细胞核骨架结合的紧密度影响其表达强度。     

PKB phosphorylation and survivin expression are cooperatively regulated by disruption of microfilament cytoskeleton

Changes in cell shape can lead to detachment and cell death, and the disruption in the actin cytoskeletal network, as one marker of cell shape changes, can itself induce apoptosis. In this study, the effects of cytochalasin B on the apoptosis-related proteins, protein kinase B and survivin were investigated. Apoptosis induced by disruption of microfilaments with cytochalasin B was found, although it happened at a low level, to simultaneously occur with G2/M arrest in 50% of the cytochalasin B-treated cells. During apoptosis, PKB phosphorylation and survivin expression was decreased by cytochalasin B, and the decline in survivin expression were preceded by PKB dephosphorylation, which implicated that survivin may be a target of PKB protein. The G2/M arrest of cytochalasin B-treated cells may be the direct function of cytochalasin B to microfilaments or the subsequent inhibition of survivin expression, or both. These results suggest that PKB/survivin signaling pathway may be responsible for the apoptosis induced by the disruption of actin cytoskeleton.