Rho小G蛋白介导的细胞周期调控

Rho小G蛋白作为一个信号分子家族具有多样化的功能, 可以调节细胞骨架重排 、细胞迁移、细胞极性、基因表达、细胞周期调控等. Rho小G蛋白家族对细胞周期 调控的研究主要集中在其对于有丝分裂期细胞的调节作用,包括调节有丝分裂期前 期细胞趋圆化、后期染色体排列及收缩环的收缩作用.近期的研究显示,Rho小G蛋白及其效应分子对于细胞周期G1、S、G2期的调控主要是通过影响细胞周期的正调控因子细胞周期蛋白D1 (cyclin D1) 和负调控因子细胞周期蛋白依赖型激酶相互作用蛋白1及细胞周期蛋白依赖型激酶抑制蛋白27 (p21cip1/p27kip1) 进行的.本文总结了Rho小G蛋白及其效应分子在细胞周期调控,尤其是对G1/S期调控的研究进展,并简要阐述了Rho小G蛋白介导的细胞周期调控异常与癌症发生的关系.     

细胞周期依赖性激酶4(Cdk4)在肿瘤发生发展中的作用

细胞周期依赖性激酶4(cdk4)是丝氨酸/苏氨酸激酶家族的成员,调控细胞周期G1期的进程.Cdk4与周期蛋白D(cyclin D)结合形成复合物,在G1期的演进中起重要作用,一旦出现失调就可能导致癌症的发生,并且也有一系列的内在和外在的信号调控着这个复合物.Cdk4以及它的调控因子在肿瘤的发生和转移中都显示了重要的作用.     

植物D型细胞周期蛋白

D型细胞周期蛋白(cyclinD,CycD)调控着细胞周期G1/S的转换,基本过程为CycD在外界环境刺激下积累,并与周期蛋白依赖激酶(cyclin-dependentkinase,CDK)形成有活性的激酶,促进成视网膜细胞瘤蛋白(retinoblastoma,Rb)磷酸化,使E2F因子释放,由此促使G1/S转换,这一调控系统在高等真核生物中具有很高的保守性。CycD与其他细胞周期蛋白表达有所不同,其受到生长因子的强烈诱导,去掉生长因子后,表达水平迅速下降,导致细胞被抑制在G1期。大量研究表明,CycD是细胞周期中一个关键的“感受因子”,CycD基因的表达是细胞周期进程中的限速因子,影响着植物的生长发育。现对植物CycD的特征以及在细胞周期中的功能进行综述,并探讨了其在植物生长发育中的作用。     

BmCyclin B和BmCyclin B3是家蚕细胞周期进程所必需的

B型细胞周期蛋白(Cyclin B)是细胞G2期向M期转化的重要调节因子. 家蚕基因组数据分析表明, 家蚕有2个Cyclin B基因, 即BmCyclin B和BmCyclin B3. 利用家蚕EST数据, 成功克隆了家蚕Cyclin B3基因(EU074796), 该基因全长1665 bp, ORF长1536 bp, 由6个内含子和7个外显子构成, 编码511个氨基酸, 含有1个蛋白破坏盒和2个周期蛋白盒, 预测分子量57.8 kD. 家蚕卵巢细胞系BmN-SWU1的BmCyclin B和BmCyclin B3基因RNA干涉结果表明, BmCyclin B和BmCyclin B3是家蚕细胞完成细胞周期进程所必需的, 二者干涉后均能导致细胞周期阻滞于G2/M期, 抑制细胞的增殖.     

杨树CYCD基因的功能鉴定及其对糖和植物激素的响应

G1到S期的转换是植物细胞周期中一个关键的调控点,而D型细胞周期蛋白(CYCD)在这一转换过程中起着重要作用.CYCD通过感受外界信号的刺激,调控细胞周期进程,进而影响植物的生长发育.为研究木本植物中不同CYCD基因家族的功能,从黑杨中克隆出6个CYCD基因,并将其转化至酵母G1期细胞周期蛋白突变体进行功能鉴定.各家族...     

葡萄糖6-磷酸脱氢酶调控细胞周期蛋白E1和细胞周期蛋白依赖性激酶2促进细胞增殖及其在肾透明细胞癌中的预后价值

肾透明细胞癌(clear cell renal cell carcinoma,ccRCC)是一种转移率高、预后差的细胞代谢性疾病,对其有效诊疗及预后分子标志物的研究十分重要。葡萄糖6-磷酸脱氢酶(glucose 6-phosphatedehydrogenase, G6PD)在ccRCC中高表达,并提示患者不良预后,其促进ccRCC细胞增殖的分子机制有待进一步揭示。本研究发现,降低G6PD可抑制细胞周期G₁/S期转化并显著抑制ccRCC细胞增殖。G6PD可在细胞水平调控G₁/S期转化及增殖相关因子Cyclin D1,CDK4,CDK6,Cyclin E1和CDK2基因表达。TCGA数据库分析结果表明,ccRCC 中Cyclin D1,Cyclin E1 和 CDK2的mRNA 水平显著升高,而CDK4表达无明显差异,CDK6表达却显著降低。相关性分析结果显示,G6PD与Cyclin D1呈显著负相关(P<0.0001),G6PD与CDK4,CDK6之间无显著相关性(P>0.05),G6PD与Cyclin E1(P<0.0001)以及CDK2(P<0.05)显著正相关。进一步免疫组化检测结果表明,Cyclin E1和 CDK2在ccRCC肿瘤组织中表达显著升高。生存预后分析结果显示,Cyclin D1高表达提示ccRCC患者整体预后更为良好,CDK4和CDK6表达水平在ccRCC患者总生存率预测中无意义;而Cyclin E1和CDK2高表达均可提示ccRCC患者预后不良。进一步细胞水平检测发现,Cyclin E1、CDK2表达降低可显著逆转G6PD促进ccRCC细胞增殖的能力。综上,与增殖相关因子Cyclin D1,CDK4和CDK6相比,G6PD有可能通过促进Cyclin E1和CDK2表达升高而发挥促进 ccRCC肿瘤细胞增殖的作用,并且这3者的异常高表达有望成为ccRCC患者不良预后的独立生存预测因素。     

G6PD通过细胞周期蛋白D1/D2调控人黑色素瘤细胞周期的进程

葡萄糖-6-磷酸脱氢酶(G6PD)在人皮肤黑色素瘤A375细胞中处于高表达与高活性状态, 但G6PD在黑色素瘤发生发展过程中的作用及其具体机制尚不明确.本文在前期运用 siRNA方法构建G6PD敲减的黑色素瘤A375稳转细胞(A375-G6PDΔ)基础上,构建表达载体pBabe-puro-G6PDWT在A375-G6PDΔ细胞中过表达野生型的G6PD基因,从而构建G6PD表达恢复的稳转细胞(A375-G6PDΔ-G6PDWT).3株细胞A375-WT、A375-G6PDΔ和 A375-G6PDΔ-G6PDWT经G6PD酶活性测定、MTT测定、克隆形成实验、流式细胞仪分析细胞周期和Western 印迹检测.结果显示,A375-G6PDΔ-G6PDWT细胞的G6PD蛋白表达量 (0.847 ± 0.080)及其活性(0.394 ± 0.029)分别是A375-G6PDΔ的3.28倍(P＜0.01) 和7.34倍(P＜0.01),分别是A375-WT细胞的91-57%和2.12倍(P＜0.05).与A375-WT细 胞相比,A375-G6PDΔ细胞G0/G1期细胞数增加,S期细胞数减少,增殖指数PI降低了25-70%（P＜0.05）,细胞周期蛋白D1/D2、细胞周期蛋白E表达分别下降37.4%、54.3% (P＜0.01)和17.3%;而A375-G6PDΔ-G6PDWT细胞呈现G1/S期阻滞解除,细胞周期蛋白D1/D2蛋白分别恢复到A375-WT细胞的89.5%和87.6%,细胞周期蛋白E表达未见 恢复,呈现生长增殖和克隆形成率的恢复并接近于A375-WT细胞. 结果提示,G6PD通 过细胞周期蛋白D1/D2调控人皮肤黑色素瘤A375细胞G1期向S期转换的进程,这为黑色 素瘤发病机制的研究提供了新的思路.     

NF-κB信号转导通路对细胞周期的调控

核转录因子NF-κB是哺乳动物Rel蛋白家族成员,属DNA结合蛋白,具有结合某些基因启动子κB序列并启动靶基因转录的功能。静息状态下,NF-κB二聚体在胞浆肉没有活性,当细胞受刺激后,它在NF-κB信号转导通路的上游激酶级联作用下被激活,并易位到细胞核内,增强靶基因表达。NF-κB是细胞分裂和生存的关键调节因子,参与调控细胞周期、细胞增殖和细胞分化。现就NF-κB对细胞周期的影响作一综述,着重阐述NF-κB通过细胞周期蛋白和CDK／CKI作用G1/S期检测点、G2/M期检测点,调控细胞周期进程。     

重楼皂苷Ⅰ对肝癌细胞的增殖及凋亡的影响

探讨重楼皂苷Ⅰ(paris saponinⅠ,PSⅠ)在体外对人肝癌SMMC-7721细胞株增殖和凋亡的影响及相关机制.MTT法检测PSⅠ对肝癌SMM-C7721细胞株的增殖抑制作用,Hoechst 33528染色法观察细胞核的形态学变化,流式细胞术Propidium iodide(PI)染色检测细胞周期及凋亡的情况,免疫印迹的方法检测Fas、Bcl-2、Bax、细胞周期素D1(cell cycle regulatory factor D1,Cyclin D1)和细胞周期素E(cell cycle regulatory factor E,Cy-clin E)的表达情况.PSⅠ能时间和浓度依赖性的抑制肝癌SMMC-7721细胞的增殖,与对照组比较,差异有统计学意义(P<0.05).干预后的SMMC-7721细胞染色质浓缩,核碎裂,凋亡小体形成,呈典型的凋亡变化.细胞周期阻滞于G1期,并且有凋亡峰形成,呈浓度依赖性.PSⅠ能浓度依赖性地上调Fas和Bax的表达,下调Bcl-2、Cyclin D1和Cyclin E蛋白的表达水平.PSⅠ可能是通过阻滞肿瘤细胞的生长及诱导细胞凋亡等机制,从而抑制肝癌细胞的增殖.     

CyclinE-CDK2相关蛋白与细胞周期调控

细胞周期蛋白(cyclin)E和周期蛋白依赖性激酶(CDK)2的复合物CyclinE-CDK2为细胞从G1期进入S期的关键激酶复合物,在细胞从G1期进入S期过程中起着至关重要的作用.它通过磷酸化其下游一系列底物如Rb、CDC6、NPAT和P107等而使细胞启动DNA合成,从而使细胞不可逆转地进入S期.CyclinE-CDK2除了受到其下游RB/E2F通路的正调控外,同时也受细胞中其他一些因子的调控,如CIP/KIP家族蛋白的负调控作用,以及Skp2-SCF介导的泛素化降解作用等.     

Who guards the guardian? Mechanisms that restrain APC/C during the cell cycle

The cell cycle is principally controlled by Cyclin Dependent Kinases (CDKs), whose oscillating activities are determined by binding to Cyclin coactivators. Cyclins exhibit dynamic changes in abundance as cells pass through the cell cycle. The sequential, timed accumulation and degradation of Cyclins, as well as many other proteins, imposes order on the cell cycle and contributes to genome maintenance. The destruction of many cell cycle regulated proteins, including Cyclins A and B, is controlled by a large, multi-subunit E3 ubiquitin ligase termed the Anaphase Promoting Complex/Cyclosome (APC/C). APC/C activity is tightly regulated during the cell cycle. Its activation state increases dramatically in mid-mitosis and it remains active until the end of G1 phase. Following its mandatory inactivation at the G1/S boundary, APC/C activity remains low until the subsequent mitosis. Due to its role in guarding against the inappropriate or untimely accumulation of Cyclins, the APC/C is a core component of the cell cycle oscillator. In addition to the regulation of Cyclins, APC/C controls the degradation of many other substrates. Therefore, it is vital that the activity of APC/C itself be tightly guarded. The APC/C is most well studied for its role and regulation during mitosis. However, the APC/C also plays a similarly important and conserved role in the maintenance of G1 phase. Here we review the diverse mechanisms counteracting APC/C activity throughout the cell cycle and the importance of their coordinated actions on cell growth, proliferation, and disease.     

沉默Smad4基因表达抑制猪卵巢颗粒细胞增殖并使细胞G_1期阻滞

Smad4是TGF-β/Smad信号通路的核心下游信号分子.为探明Smad4基因对猪卵巢颗粒细胞增殖及细胞周期的影响,采用RNA干扰技术,设计并合成猪Smad4基因的靶向小分子干扰RNA,由LipofectamineTMRNAiMix介导转染体外培养的猪卵巢颗粒细胞.应用实时荧光定量PCR检测Smad4mRNA的干扰效果,应用MTT法、流式细胞术检测细胞增殖和细胞周期的变化,同时应用荧光定量PCR检测转染前后CyclinD1、CyclinB、CyclinA2、CDK1、CDK2、CDK4等周期相关基因的mRNA表达量的变化.实验结果显示,靶向猪Smad4的特异性siRNA序列对Smad4mRNA表达的抑制率为79.85%(P0.01);沉默Smad4可以显著抑制猪卵巢颗粒细胞增殖,并且改变细胞周期分布,G0/G1期细胞比例显著高于各对照组(P0.05),S期细胞比例显著低于各对照组(P0.05),细胞分裂被阻滞;转染36h后CyclinD1、CDK1的mRNA表达量显著低于对照组,CyclinA2、CDK2、CDK4极显著低于对照组,CyclinB差异不显著.综上所述,Smad4是影响猪卵巢颗粒细胞增殖及细胞周期进程的重要基因之一.     

Drug Targets for Cell Cycle Dysregulators in Leukemogenesis: In Silico Docking Studies

Alterations in cell cycle regulating proteins are a key characteristic in neoplastic proliferation of lymphoblast cells in patients with Acute Lymphoblastic Leukemia (ALL). The aim of our study was to investigate whether the routinely administered ALL chemotherapeutic agents would be able to bind and inhibit the key deregulated cell cycle proteins such as - Cyclins E1, D1, D3, A1 and Cyclin Dependent Kinases (CDK) 2 and 6. We used Schrödinger Glide docking protocol to dock the chemotherapeutic drugs such as Doxorubicin and Daunorubicin and others which are not very common including Clofarabine, Nelarabine and Flavopiridol, to the crystal structures of these proteins. We observed that the drugs were able to bind and interact with cyclins E1 and A1 and CDKs 2 and 6 while their docking to cyclins D1 and D3 were not successful. This binding proved favorable to interact with the G1/S cell cycle phase proteins that were examined in this study and may lead to the interruption of the growth of leukemic cells. Our observations therefore suggest that these drugs could be explored for use as inhibitors for these cell cycle proteins. Further, we have also highlighted residues which could be important in the designing of pharmacophores against these cell cycle proteins. This is the first report in understanding the mechanism of action of the drugs targeting these cell cycle proteins in leukemia through the visualization of drug-target binding and molecular docking using computational methods.     

A breath of fresh air for cyclin D/Cdk4: triggering growth via Hph

Activation of Cyclin D/Cdk4 stimulates progression through the G1-S phase of the cell cycle in many organisms. In Drosophila, Cyclin D/Cdk4 also induces cell growth independently of cell cycle progression. In this issue of Developmental Cell, Frei and Edgar reveal that Cyclin D/Cdk4-stimulated growth requires Hph, a prolyl hydroxylase that is a key component of a cell's ability to respond to hypoxia.     

Sister chromatids fail to separate during an induced endoreplication cycle in Drosophila embryos

When mitosis is bypassed, as in some cancer cells or in natural endocycles, sister chromosomes remain paired and produce four-stranded diplochromosomes or polytene chromosomes. Cyclin/Cdk1 inactivation blocks entry into mitosis and can reset G2 cells to G1, allowing another round of replication. Reciprocally, persistent expression of Cyclin A/Cdk1 or Cyclin E/Cdk2 blocks Drosophila endocycles. Inactivation of Cyclin A/Cdk1 by mutation or overexpression of the Cyclin/Cdk1 inhibitor, Roughex (Rux), converts the 16(th) embryonic mitotic cycle to an endocycle; however, we show that Rux expression fails to convert earlier cell cycles unless Cyclin E is also downregulated. Following induction of a Rux transgene in Cyclin E mutant embryos during G2 of cell cycle 14 (G2(14)), Cyclins A, B, and B3 disappeared and cells reentered S phase. This rereplication produced diplochromosomes that segregated abnormally at a subsequent mitosis. Thus, like the yeast CKIs Rum1 and Sic1, Drosophila Rux can reset G2 cells to G1. The observed cyclin destruction suggests that cell cycle resetting by Rux was associated with activation of the anaphase-promoting complex (APC), while the presence of diplochromosomes implies that this activation of APC outside of mitosis was not sufficient to trigger sister disjunction.     

microRNA-16-5p enhances radiosensitivity through modulating Cyclin D1/E1–pRb–E2F1 pathway in prostate cancer cells

Prostate cancer (CaP) is the second most common cancer in men worldwide in 2012, and radiation therapy is one of the most common definitive treatment options for localized CaP. However, radioresistance is a major challenge for the current radiotherapy, accumulating evidences suggest microRNAs (miRNAs), as an important regulator in cellular ionizing radiation (IR) responses, are closely correlated with radiosensitivity in many cancers. Here, we identified microRNA-16-5p(miR-16-5p) is significantly upregulated in CaP LNCaP cells following IR and can enhance radiosensitivity through modulating Cyclin D1/E1–pRb–E2F1 pathway. To identify the expression profile of miRNAs in CaP cells exposed to IR, we performed human miRNA probe hybridization chip analysis and miR-16-5p was found to be significantly overexpressed in all treatment groups that irradiated with different doses of X-rays and heavy ions (¹²C⁶⁺). Furthermore, overexpression of miR-16-5p suppressed cell proliferation, reduced cell viability, and induced cell cycle arrest at G0/G1 phase, resulting in enhanced radiosensitivity in LNCaP cells. Additionally, miR-16-5p specifically targeted the Cyclin D1/E1–3′-UTR in LNCaP cells and affected the expression of Cyclin D1/E1 in both mRNA and protein levels. Taken together, miR-16-5p enhanced radiosensitivity of CaP cells, the mechanism may be through modulating Cyclin D1/Cyclin E1/pRb/E2F1 pathway to cause cell cycle arrest at G0/G1 phase. These findings provided new insight into the correlation between miR-16-5p, cell cycle arrest, and radiosensitivity in CaP, revealed a previously unrecognized function of miR-16-5p–Cyclin D1/E1–pRb–E2F1 regulation in response to IR and may offer an alternative therapy to improve the efficiency of conventional radiotherapy.     

D cyclins in lymphocytes.

BACKGROUND: D cyclins are essential for the progression of cells through the G1 phase of the cell cycle. There are three distinct D cyclins. Cyclin D1 has been shown to be expressed by many different types of cells but not by lymphocytes. Cyclins D2 and D3 have been found in lymphocytes. METHODS: We used high-resolution enzymatic amplification staining technology in conjunction with flow cytometry and confocal microscopy and with immunoblotting to reassess the expression of the D cyclins in human lymphocytes. RESULTS: Using high-resolution technology for flow cytometry, we found all three D cyclins in quiescent human peripheral blood lymphocytes. Cyclin D1 was expressed in quiescent and activated cells at levels commensurate with those of actively proliferating tumor cell lines. Cyclin D1 was functional inasmuch as it was complexed with CDK4. In the quiescent cells, cyclin D1 was expressed in the cytoplasm but, after activation, was found in the nucleus. CONCLUSIONS: These findings demonstrate that lymphocytes express cyclin D1 and necessitate a reappraisal of the hypothesis that the D cyclins subsume redundant activities with tissue-specific expression.     

Antiproliferative action of valproate is associated with aberrant expression and nuclear translocation of cyclin D3 during the C6 glioma G1 phase

Cell cycle progression is tightly regulated by cyclins, cyclin-dependent kinases (cdks) and related inhibitory phophatases. Here, we employed mitotic selection to synchronize the C6 glioma cell cycle at the start of the G1 phase and mapped the temporal regulation of selected cyclins, cdks and inhibitory proteins throughout the 12 h of G1 by immunoblot analysis. The D-type cyclins, D3 and D1, were differentially expressed during the C6 glioma G1 phase. Cyclin D1 was up-regulated in the mid-G1 phase (4-6 h) while cyclin D3 expression emerged only in late G1 (9-12 h). The influence of the anticonvulsant agent valproic acid (VPA) on expression of cyclins and related proteins was determined, since its teratogenic potency has been linked to cell cycle arrest in the mid-G1 phase. Exposure of C6 glioma to VPA induced a marked up-regulation of cyclin D3 and decreased expression of the proliferating cell nuclear antigen. In synchronized cell populations, increased expression of cyclin D3 by VPA was detected in the mid-G1 phase (3-5 h). Immunocytochemical localization demonstrated rapid intracellular translocation of cyclin D3 to the nucleus following VPA exposure, suggesting that VPA-induced cell cycle arrest may be mediated by precocious activation of cyclin D3 in the G1 phase.