NGX6基因对人结肠癌细胞HT-29细胞周期的影响

NGX6基因是新克隆的候选抑瘤基因,研究表明NGX6重表达可抑制结肠癌细胞的增殖.为进一步研究NGX6对细胞周期的影响,采用流式细胞仪检测NGX6重表达对结肠癌细胞HT-29细胞周期的影响,发现NGX6重表达可增加HT-29细胞在G0/G1期的分布比例,减少了S,G2,M期细胞数.利用蛋白质印迹和流式细胞术分析NGX6转染前后HT-29细胞周期素(cyclins)和细胞周期素依赖性蛋白激酶抑制物(cyclin-dependentkinaseinhibitor,CKI)的表达变化,发现NGX6可下调HT-29细胞中cyclinE、cyclinD1的表达及上调p27的表达,对cyclinA和cyclinB的表达无明显影响,p16在三组结肠癌细胞中均无表达.研究结果表明,NGX6在HT-29细胞中通过下调cyclinE、cyclinD1和上调p27的表达,阻滞细胞周期于G0/G1期,从而发挥其在结肠癌中的抑瘤作用.     

塞来昔布诱导HCT-116结肠癌细胞G2/M阻滞

目的:研究选择性COX-2抑制剂塞来昔布诱导结肠癌细胞株HCT-116细胞周期阻滞的作用及其可能的机制。方法:应用流式细胞仪检测塞来昔布对HCT-116细胞周期的影响,定量PCR检测细胞周期素cyclinB1及COX-2 mRNA表达水平,Western-Blot检测细胞周期素cyclinB1的蛋白水平。结果:塞来昔布诱导HCT-116细胞G2/M阻滞的作用呈剂量依赖性,塞来昔布在mRNA及蛋白水平下调HCT-116细胞的cyclinB1。结论:塞来昔布能在体外抑制HCT-116细胞的增殖,诱导G2/M的阻滞,其作用与下调细胞周期素cyclinB1有关。     

CDK1 siRNA干扰在Taxol诱导细胞凋亡中的作用

目的研究转染细胞周期依赖性蛋白激酶1（cyclin．dependent kinase1,CDK1）siRNA、以及转染后进行凋亡刺激对细胞周期和凋亡的影响,探讨CDK1在细胞凋亡中的确切作用,揭示细胞周期与细胞凋亡协调的分子机制。方法以人宫颈癌细胞株HeLa细胞为研究对象,脂质体转染CDK1siRNA,转染后48h加紫杉醇（Tax01）（20μg／m1）刺激凋亡,Western印迹检测CDK1和抗凋亡蛋白BCL2表达,AnnexinV／PI法检测细胞的凋亡,流式细胞仪分析DNA含量检测细胞周期。结果转染CDK1 siRNA后,CDK1蛋白的表达下降,细胞周期G2／M期比例增加,细胞凋亡率与对照相比没有明显升高。只加Taxol刺激12h后细胞凋亡率增加并伴有S期和G2／M期比例增加。转染CDKlsiRNA后再用Taxol刺激,其细胞凋亡率没有明显改变,G2／M期阻滞效应也没有叠加。BCL2蛋白只在加Taxol刺激组表达下降,与CDK1表达减少没有相关性。结论siRNA沉默导致的CDK1表达降低只导致细胞周期G2／M期阻滞,没有引起细胞凋亡;CDK1的表达降低对紫杉醇所诱导的细胞周期阻滞和细胞凋亡效应没有明显影响。     

胃癌、癌旁和正常组织中存活蛋白的表达与细胞周期变化的相关性研究

目的:探讨胃癌、癌旁和正常组织中存活蛋白的表达情况及其与细胞周期变化的相关性。方法:采用免疫组化SP法检测胃癌、癌旁和正常组织中存活蛋白的表达,同时用流式细胞仪检测3种组织中细胞周期的变化,分析存活蛋白的表达与细胞周期变化的相关性。结果:存活蛋白在正常胃黏膜组织中无表达,胃癌癌旁组织中阳性表达率为16.67%,胃癌组织中阳性表达率为46.67%;与正常胃组织比较,胃癌癌旁组织和胃癌组织G0/G1期细胞均有明显下降,S期细胞均有明显升高,胃癌组织G2/M期细胞明显高于正常组织;存活蛋白的表达与G2/M期细胞数相关(rs=0.627)。结论:存活蛋白在胃癌组织中表达明显增加,并且与胃癌组织细胞周期变化相关,可通过调节细胞周期促进细胞增殖。     

芹菜素对MDA-MB-231细胞增殖及侵袭转移的影响

目的:研究芹菜素对乳腺癌MDA-MB-231细胞增殖及侵袭转移能力的影响,探讨其作用 机制.方法:芹菜素处理MDA-MB-231细胞,MTT法及流式法检测细胞增殖、粘附和周期变化 ;Millicell小室检测新生血管形成、侵袭转移能力的改变;免疫细胞化学检测Bcl-2、Bax 、cyclinB1、VEGF、MMP-9、E-cd蛋白的表达差异.结果:芹菜素明显抑 制MDA-MB-231细胞增殖,诱导细胞凋,G2/M期细胞比例由4.79%增至36.12%(P＜0.05 );细胞的黏附、新生血管形成 能力均显著降低;侵袭转移穿膜细胞数明显低于对照组,分别由88.67、106.33降至45.67、 68(P＜0.05);Bcl-2、cyclinB1、VEGF、MMP-9蛋白表达明显降低;Bax,E-cd的表达则增 加.结论:芹菜素有效抑制MDA-MB-231细胞增殖,阻滞细胞于G2/M期, 诱导细胞凋亡;抑制 细胞粘附、新生血管形成、侵袭与转移的能力,其机制与抑制Bcl-2、cyclinB1、VEGF、MMP 9表达,促进Bax、E-cd表达有关.     

丙戊酸钠抑制A549细胞生长

目的研究丙戊酸钠对肺癌A549细胞增殖和细胞周期的影响。方法MTT检测生长抑制,流式细胞仪检测细胞周期和凋亡,Western blot检测p21WAF1/CIP1蛋白表达。结果丙戊酸钠以剂量依赖性方式抑制A549细胞生长;丙戊酸钠上调G0/G1期比例,下调S期和G2/M期,不影响细胞凋亡;丙戊酸钠上调p21WAF1/CIP1蛋白表达。结论丙戊酸钠上调p21WAF1/CIP1表达,使细胞阻滞于G0/G1期,抑制A549细胞生长。     

苜蓿银纹夜蛾核型多角体病毒的感染对Sf9细胞周期的影响

病毒的感染导致细胞内部发生一系列变化。应用流式细胞仪FACS的荧光检测 ,测出Sf9细胞完成整个周期循环大约需要 18h ,G1、S、G2 /M各时相的时间间隔约为 6h ;AcNPV感染Sf9细胞 12 18h ,细胞被抑制于G2 /M期 ;Sf9细胞同步于G1/S期后释放细胞并用AcNPV感染 ,12h后 ,2 / 3的细胞处于G2 /M期 ,1/ 3的细胞处于S期     

利用405nm激光激发Hoechst33342染色细胞DNA的流式细胞技术

目的:探讨流式细胞仪上405 nm激光激发Hoechst33342染色细胞DNA的效果及影响检测结果的因素。方法:SW480和A549两种细胞经Hoechst33342染色后,流式细胞仪405 nm激光激发检测DNA含量,利用软件计算出处于G0/G1期、S期和G2/M期细胞的百分比,以PI染色法结果作为对照。结果:SW480和A549细胞经Hoechst33342染色后各期的细胞百分比与PI染色法基本一致,无明显差异(P0.05)。结论:405 nm激光激发Hoechst33342染色细胞DNA结果可靠,可作为紫外检测的替代方法。     

苜蓿银纹夜蛾核型多角体病毒的感染对Sf9细胞周期的影响

病毒的感染导致细胞内部发生一系列变化.应用流式细胞仪FACS的荧光检测,测出Sf9细胞完成整个周期循环大约需要18h,G\-1、S、G\-2/M各时相的时间间隔约为6h;AcNPV感染Sf9细胞12-18h,细胞被抑制于G\-2/M期;Sf9细胞同步于G\-1/S期后释放细胞并用AcNPV感染,12h后,2/3的细胞处于G\-2/M期,1/3的细胞处于S期.     

瘦素对血管平滑肌细胞周期蛋白D1、CDK2表达的影响

目的观察瘦素对人平滑肌细胞周期时相及cyclin D1、CDK2表达的影响,探讨瘦素促进平滑肌细胞增殖的作用机制。方法取对数生长期的平滑肌细胞同步于G0期,分为加入浓度为0、20、40、80、100、200ng/ml瘦素的各组。作用24h后分别用MTT法检测细胞活性,用流式仪进行细胞周期时相的检测,Western blot法测定Cyclin D1、CDK2的表达。结果随着瘦素浓度的增加G0/G1期的平滑肌细胞逐渐减少,S期和G2/M期细胞逐渐增加,PI增殖指数逐渐增加。cyclin D1、CDK2蛋白的表达呈剂量依赖性的上升趋势。以上两项检测均在100ng/ml处达最高。结论瘦素上调cyclinD1、CDK2蛋白的表达,可能是促进平滑肌细胞增殖的机制之一。     

Flow cytometry study of human cyclin B1 and cyclin E expression in leukemic cell lines: cell cycle kinetics and cell localization

Experiments by flow cytometry (FCM) after nuclei isolation have never been done to investigate cyclins. We have conducted different experiments by FCM using whole cells and isolated nuclei to study the immunolocalization and kinetic patterns of cyclin B1 and cyclin E in various leukemic cell lines. During asynchronous growth, all whole cells had a scheduled, cell cycle phase-restricted expression of cyclin B1. By using a washless immunostaining of unfixed nuclei, cyclin B1 was detected in all cell cycle phases, including G1, although to a lesser extent than in G2/M, suggesting that in whole cells the cyclin B1 epitope is masked and accessible only in isolated nuclei. When the cells were synchronized at the G1/S boundary by thymidine or in the G1 phase by sodium n-butyrate, an identical accumulation of cyclin B1 was observed. As for cyclin E, its expression was higher with thymidine treatment than with sodium n-butyrate, particularly in nuclei. The elevated cyclin B1 level in the cells arrested at the G1/S boundary may reflect the increased half-life of this protein stabilized as the result of cyclin E overexpression. However, our FCM data also support the notion that accumulation of human cyclin B1 in leukemic cell lines begins during the G1 phase of the cell cycle, probably in the nucleus. The detection of cyclin B1 by Western blot in cells sorted in the G1 phase of the cell cycle confirms this finding. It is possible, therefore, that tumor transformation or leukemic phenotype may invariably be associated with altered cyclin B1 expression.     

Different expression profiles of human cyclin B1 in normal PHA-stimulated T lymphocytes and leukemic T cells

BACKGROUND: In a previous work, we demonstrated with flow cytometry (FCM) methods that accumulation of human cyclin B1 in leukemic cell lines begins during the G(1) phase of the cell cycle (Viallard et al. , Exp Cell Res 247:208-219, 1999). In the present study, FCM was used to compare the localization and the kinetic patterns of cyclin B1 expression in Jurkat leukemia cell line and phytohemagglutinin (PHA)-stimulated normal T lymphocytes. METHODS: Cell synchronization was performed in G(1) with sodium n-butyrate, at the G(1)/S transition with thymidine and at mitosis with colchicine. Cells (leukemic cell line Jurkat or PHA-stimulated human T-lymphocytes) were stained for DNA and cyclin B1 and analyzed by FCM. Western blotting was used to confirm certain results. RESULTS: Under asynchronous growing conditions and for both cell populations, cyclin B1 expression was essentially restricted to the G(2)/M transition, reaching its maximal level at mitosis. When the cells were synchronized at the G(1)/S boundary by thymidine or inside the G(1) phase by sodium n-butyrate, Jurkat cells accumulated cyclin B1 in both situations, whereas T lymphocytes expressed cyclin B1 only during the thymidine block. The cyclin B1 fluorescence kinetics of PHA-stimulated T lymphocytes was strictly similar when considering T lymphocytes blocked at the G(1)/S phase transition by thymidine and in exponentially growing conditions. These FCM results were confirmed by Western blotting. The detection of cyclin B1 by Western blot in cells sorted in the G(1) phase of the cell cycle showed that cyclin B1 was present in the G(1) phase in leukemic T cells but not in normal T lymphocytes. Cyclin B1 degradation was effective at mitosis, thus ruling out a defective cyclin B1 proteolysis. CONCLUSIONS: We found that the leukemic T cells behaved quite differently from the untransformed T lymphocytes. Our data support the notion that human cyclin B1 is present in the G(1) phase of the cell cycle in leukemic T cells but not in normal T lymphocytes. Therefore, the restriction point from which cyclin B1 can be detected is different in the two models studied. We hypothesize that after passage through a restriction point differing in T lymphocytes and in leukemic cells, the rate of cyclin B1 synthesis becomes constant in the S and G(2)/M phases and independent from the DNA replication cycle.     

人类主要Cyclins在MOLT-4细胞阻断动力学下的表达规律

细胞周期素与相应的细胞周期素依赖性蛋白激酶相结合,驱动着细胞通过细胞周期各时相,而细胞周期素时相性规律大多来自酵母研究或同步化细胞的分析。本研究着重于人类非同步化细胞的细胞周期素时相性规律的揭示。采用人类白血病细胞株MOLT-4,使其处于对数生长期,加以有丝分裂中期阻滞法,应用多参数流式细胞术分析人类主要细胞周期素B1、A和E。分析发现,细胞周期素B1峰值在M期,降解于M期后,细胞周期素A峰值在G2期,降解于M期,细胞周期素E峰值在G1晚期,降解于S期。以上结果,使我们首次在人类非同步化培养细胞展现了主要细胞周期素的时相性表达规律。     

Cell Cycle-Related Cyclin B1 Quantification

Background

To obtain non-relative measures of cell proteins, purified preparations of the same proteins are used as standards in Western blots. We have previously quantified SV40 large T antigen expressed over a several fold range in different cell lines and correlated the average number of molecules to average fluorescence obtained by cytometry and determined cell cycle phase related expression by calculation from multi-parametric cytometry data. Using a modified approach, we report quantification of endogenous cyclin B1 and generation of the cell cycle time related expression profile.

Methodology

Recombinant cyclin B1 was purified from a baculovirus lysate using an antibody affinity column and concentrated. We created fixed cell preparations from nocodazole-treated (high cyclin B1) and serum starved (low cyclin B1) PC3 cells that were either lyophilized (for preservation) or solubilized. The lysates and purified cyclin B1 were subjected to Western blotting; the cell preparations were subjected to cytometry, and fluorescence was correlated to molecules. Three untreated cell lines (K562, HeLa, and RKO) were prepared for cytometry without lyophilization and also prepared for Western blotting. These were quantified by Western blotting and by cytometry using the standard cell preparations.

Results

The standard cell preparations had 1.5×10⁵ to 2.5×10⁶ molecules of cyclin B1 per cell on average (i.e., 16-fold range). The average coefficient of variation was 24%. Fluorescence varied 12-fold. The relationship between molecules/cell (Western blot) and immunofluorescence (cytometry) was linear (r² = 0.87). Average cyclin B1 levels for the three untreated cell lines determined by Western blotting and cytometry agreed within a factor of 2. The non-linear rise in cyclin B1 in S phase was quantified from correlated plots of cyclin B1 and DNA content. The peak levels achieved in G2 were similar despite differences in lineage, growth conditions, and rates of increase through the cell cycle (range: 1.6–2.2×10⁶ molecules per cell).

Conclusions

Net cyclin B1 expression begins in G1 in human somatic cells lines; increases non-linearly with variation in rates of accumulation, but peaks at similar peak values in different cell lines growing under different conditions. This suggests tight quantitative end point control.     

Human cyclin B3. mRNA expression during the cell cycle and identification of three novel nonclassical nuclear localization signals

Cyclins form complexes with cyclin-dependent kinases. By controlling activity of the enzymes, cyclins regulate progression through the cell cycle. A- and B-type cyclins were discovered due to their distinct appearance in S and G(2) phases and their rapid proteolytic destruction during mitosis. Transition from G(2) to mitosis is basically controlled by B-type cyclins. In mammals, two cyclin B proteins are well characterized, cyclin B1 and cyclin B2. Recently, a human cyclin B3 gene was described. In contrast to the expression pattern of other B-type cyclins, we find cyclin B3 mRNA expressed not only in S and G(2)/M cells but also in G(0) and G(1). Human cyclin B3 is expressed in different variants. We show that one isoform remains in the cytoplasm, whereas the other variant is translocated to the nucleus. Transport to the nucleus is dependent on three autonomous nonclassical nuclear localization signals that where previously not implicated in nuclear translocation. It had been shown that cyclin B3 coimmunoprecipitates with cdk2; but this complex does not exhibit any kinase activity. Furthermore, a degradation-resistant version of cyclin B3 can arrest cells in G(1) and G(2). Taken together with the finding that cyclin B3 mRNA is not only expressed in G(2)/M but is also detected in significant amounts in resting cells and in G(1) cells. This may suggest a dominant-negative function of human cyclin B3 in competition with activating cyclins in G(0) and the G(1) phase of the cell cycle.     

Expression of cyclin A,B1 and D1 after induction of cell cycle arrest in the Jurkat cell line exposed to doxorubicin

Jurkat human lymphoblastoid cells were incubated in increasing concentrations of doxorubicin (0.05, 0.1 and 0.15 μM) to induce cell death, and their expression of cyclin A, B1 and D1 was evaluated by flow cytometry (cell cycle progression, Annexin V assay, percentages and levels of each of the cyclins), transmission electron microscopy (ultrastructure) and confocal fluorescence microscopy (expression and intracellular localization of cyclins). After low‐dose doxorubicin treatment, Jurkat cells responded mainly by G2/M arrest, which was related to increased cyclin B1, A and D1 levels, a low level of apoptosis and/or mitotic catastrophe. The influence of doxorubicin on levels and/or localization of selected cyclins was confirmed, which may in turn contribute to the G2/M arrest induced by the drug.     

Expression of cyclins and cdks throughout murine carcinogenesis.

The overexpression and/or amplification of cell cycle regulating genes is an important factor in the progression of cancer. Recent attention has been focused on several cyclin and cdks genes whose expression were increased in many types of tumor. In this study, we investigated the expression kinetics of cyclins A, B, D1, E and cdks 1, 2, 4, 6 by RT-PCR coupled with densitometry and correlated to the growth fraction (percentage of S cells). This analysis was performed using an experimental murine leukemic model, generated by in vivo administration of murine clonogenic cells Wehi-3b injected into balb-c mice. Differential expression of cyclins and cdks was observed between normal and tumoral cells with different patterns of expression between G1 and G2M cyclins-cdks. G1 cyclins cdks expression was significantly increased in tumor cells when compared to normal cells. In the same manner, G2M cyclins cdks expression was only observed in tumor cells at a lower level than for G1 cyclins cdks, but not detected in normal cells. These differences correlated with the growth fraction for both the G1 cyclins cdks (r = 0.91, 0.94, 0.85, 0.90 and 0.96 for cyclin D1, cyclin E, cdk2, cdk4 and cdk6, respectively) and the G2M cyclins cdks (r = 0.96, 0.97 and 0.93 for cyclins A, B and cdkl respectively). Analysis of cyclins cdks expression kinetics during tumoral progression shows that cyclins A, B and cdkl were expressed from the 12th day on of disease, increased until the death of the animals and correlated with the growth fraction (r = 0.94, 0.95 and 0.97 for cyclins A, B and cdk1 respectively) (n = 20). Overexpression of other cyclins cdks were observed, from the 6th day on for cyclin D1, the 12th day for cdk2 and cdk4, the 15th day for cdk6 and the 20th day for cyclin E. These increases persisted during tumoral progression and correlated with the growth fraction (r = 0.85, 0.94, 0.93, 0.96, and 0.98 for cyclin D1, cyclin E, cdk2, cdk4 and cdk6, respectively) (n = 20). Our results demonstrated that G1 and G2-M cyclins cdks mRNA levels were increased at approximately the same time of maximal tumor growth. Only cyclin D1 overexpression occured at the initiation of tumoral development, and could therefore be considered as an early marker of cell proliferation.     

血小板生成素诱导胎肝CD34^＋造血干／祖细胞增殖分化与周期蛋白表达的关系

为了解胚胎时期巨核细胞增殖分化特有的内在机制,本研究观察了在体外培养体系中,胎肝源CD34+造血干/祖细胞在血小板生成素(thrombopoietin,TPO)作用下增殖分化特征与相关周期蛋白B1、D1和D3表达及细胞内水平变化的关系。结果发现(1)经12d培养后,TPO使胎肝源CD34     

Simultaneous detection of cyclin B1, p105, and DNA content provides complete cell cycle phase fraction analysis of cells that endoreduplicate

BACKGROUND: DNA analysis of endoreduplicating cells is difficult because of the overlap between stem-line G2 + M cells and 4C G1 cells. Simultaneous flow cytometry of DNA and cyclin B1 analytically separates these populations. The objective here was to develop simultaneous flow cytometry of DNA, cyclin B1, and p105 (highly expressed in mitosis) for improved, complete cell cycle phase fraction analysis of endoreduplicating cell populations. METHODS: Monoclonal antibody, GNS-1, reactive with human cyclin B1, was conjugated with fluorescein at three different fluorochrome-to-protein (F/P) ratios and tested for optimal sensitivity in a flow cytometric assay. A formaldehyde-methanol fixation procedure was optimized for retention of p105 within mitotic cells by analytic titration of formaldehyde. p105 was stained indirectly with Cy5-conjugated secondary antibody, followed by GNS-1, and DNA was stained with Hoechst 33342. The specificity of p105 in this assay was tested by comparison of manual and flow cytometric mitotic indices and by sorting and microscopic inspection. RESULTS: F/P 4.1 provided optimal fluorescein labeling of GNS-1. Formaldehyde (0.5%), followed by methanol permeabilization, fixed cells sufficiently to quantify stem-line and endoreduplicated G1, S, G2, and M phase fractions. Kinetic measurements of these fractions for both populations were demonstrated. CONCLUSIONS: The fluorochrome-to-protein ratio is important and can be optimized objectively for these assays. A permeabilization-sensitive antigen (p105), previously requiring formaldehyde/detergent-fixed cell preparations, was shown to work equally well with formaldehyde/ methanol fixation. Three-laser, two-parameter intracellular antigen analysis can be successfully coupled with DNA content analysis. Cell cycle kinetic analysis of endoreduplicating populations should be improved.