复制阻滞应激引发的ARTEMIS蛋白磷酸化调控CYCLIN E蛋白的稳定性

Artemis是1个具有多种生物学功能的磷酸化蛋白,它在基因毒性应激引发的细胞周期检测点调控中起重要作用,但其调控机制知之甚少.为了探讨UVC等DNA复制阻滞应激引发的Artemis磷酸化及蛋白表达水平对细胞周期蛋白 E的调控作用和调控机制.首先以Western印迹方法检测Artemis S516-645A突变细胞和Artemis表达降低细胞的细胞周期蛋白E的表达水平,发现ArtemisS516-645A突变细胞和多种Artemis siRNA转染细胞的细胞周期蛋白E表达水平均高于对照细胞.在此基础上,为分析细胞周期蛋白E表达受调控的分子机制,在稳定表达各种磷酸化状态Artemis的HEK-293细胞中导入外源性启动子转录驱动的细胞周期蛋白E表达质粒,发现表达Artemis S516-645A突变体的细胞中外源性的细胞周期蛋白E蛋白表达水平也高于野生型细胞.进一步的研究发现在Artemis蛋白表达降低的细胞中与泛素结合的细胞周期蛋白E减少而蛋白稳定性增加.本研究还发现Artemis蛋白对细胞周期蛋白E的调控过程是不依赖于p53和p21表达的.这些结果表明,Artemis S516-645A突变和Artemis表达降低都可以引起细胞周期蛋白E蛋白水平升高,该调控作用是在转录后水平发生的,可能是干扰了细胞周期蛋白E的泛素化介导的蛋白降解过程,并且该调控作用是独立于p53-p21信号通路的.     

DNA损伤反应中细胞周期检查点蛋白p27~(Kip1)表达及其调控机制

为了研究DNA损伤反应中p2 7Kip1的表达及其调控机制 ,应用免疫印迹的实验结果表明 :10Gy 60 Coγ射线照射后 3h ,HeLa细胞中p2 7Kip1蛋白水平开始下降并持续到 2 4h ,进而失去它对CDKs的抑制功能 .Northern印迹结果显示 ,电离辐射 (IR)对p2 7Kip1mRNA表达水平无明显影响 ,说明电离辐射诱导p2 7Kip1表达水平的降低主要与蛋白质降解相关 ,但其具体的调控机制还不清楚 .已知在G1—S期p2 7Kip1蛋白的降低主要依赖细胞周期蛋白E Cdk2激酶将其磷酸化后的泛素化蛋白酶体途径 (ubiquitin proteasomepathway) .酶动力学研究结果揭示 :电离辐射后细胞周期蛋白E Cdk2激酶活性增高 ,12h细胞周期蛋白E Cdk2激酶活性达到最大 .当在照前用细胞周期蛋白E Cdk2抑制剂olomoucine (10 μmol L)抑制细胞周期蛋白E Cdk2激酶活性时 ,p2 7Kip1蛋白表达水平增加 .此外 ,还观察到电离辐射可诱导p2 7Kip1泛素化水平的增高 ,而在使用蛋白酶体抑制剂MG 132 (5 μmol L)处理HeLa细胞后 ,可抑制辐射诱导p2 7Kip1蛋白水平的下调 .研究结果提示 :泛素化蛋白酶体途径参与了辐射诱导P2 7Kip1蛋白表达下调的降解机制 .     

p16INK4a基因的功能及其调控

p16INK4a蛋白能抑制CDK4和CDK6的活性,使pRb处于非磷酸化或低磷酸化状态而能与转录因子E2Fs结合,从而抑制DNA 的合成,阻止细胞由G1期进入S期.p16INK4a的表达受Ets1和Ets2的正调控,受Bmi-1的负调控.p16INK4a基因缺失、突变、甲基化、RNA剪接加工错误可导致细胞周期失控和癌变.应用p16INK4a对某些肿瘤进行基因治疗的研究正在进行中.     

RNA沉默抑制子p19调控细胞周期相关蛋白表达

番茄丛矮病毒的P19蛋白不仅是一个重要的病毒致病因子,而且还可作为RNA干扰(RNAi)的抑制子．这种作用是通过限制细胞内的小RNA,比如小干扰RNA(siRNAs)和微RNA(miRNAs)来实现．但是目前对P19蛋白在哺乳动物细胞上的作用还未见报道．构建了一株p19稳定表达的293细胞系,即293-p19．流式细胞仪分析发现在293细胞中过量表达P19蛋白可显著引发细胞周期的G2/M阻滞．细胞增殖实验显示,293-p19细胞的DNA复制及细胞生长均受到显著的抑制． 此外,研究还发现p19可使人胚肾293细胞内的细胞周期调控子的表达谱发生改变． 其中包括上调cyclin A1,CDK2,CDK4,CDK6,p18,cyclin D2,p19INK4d和E2F1,及下调p15,cyclin A,cyclin B1和cyclin E1的表达．上述研究结果提示,p19有可能靶向多个G2/M调控蛋白从而引发细胞的G2/M阻滞．     

HBXIP基因对乙肝病毒X蛋白诱导细胞凋亡的影响

探讨乙型肝炎病毒X蛋白结合蛋白(hepatitisBXinteractingprotein ,HBXIP)基因在乙型肝炎病毒X蛋白(HBX)诱导肝癌细胞凋亡时对细胞周期的影响.构建HBXIP基因真核表达载体pcDNA3 hbxip ,进行瞬时基因转染,将克隆有HBx基因的pCMV X (分别为1μg、2 μg和3μg)和pcDNA3 hbxip质粒分别和共转染至人H74 0 2肝癌细胞中(总体积分别为5 0 μl) .发现瞬时转染3μgpCMV X质粒后,肝癌细胞凋亡发生率为34 4 % ,肝癌细胞的细胞周期相关蛋白p2 7表达水平发生明显上调;与对照组相比,瞬时转染1μg、2 μg和3μg时,细胞周期蛋白D和细胞周期蛋白E的表达水平均发生明显上调,但随着HBX水平的增加细胞周期蛋白D和细胞周期蛋白E的表达水平发生明显下降;在稳定转染pCMV X质粒的H74 0 2 X肝癌细胞中无明显的细胞凋亡发生,研究发现p2 7的表达水平发生了明显下调,而细胞周期蛋白D和细胞周期蛋白E的表达水平发生了明显上调;当pcDNA3 hbxip质粒与pCMV X质粒进行共瞬时转染时,细胞凋亡发生率由pcDNA3质粒与pCMV X质粒共转染时的2 9 2 %下降为13 3% ,p2 7的表达水平发生了下调,但细胞周期蛋白D和细胞周期蛋白E的表达水平无明显变化.研究结果表明,瞬时转染一定剂量的x基因可导致肝癌细胞发生凋亡,细胞周期相关蛋白p2 7、细胞周期蛋白D和     

ATM介导的蛋白磷酸化与DNA损伤的信号转导机制

细胞周期检定点激酶ATM蛋白属于磷酸肌醇3激酶（PI－3K）家族成员,也是哺乳动物细胞BASC高分子蛋白复合物的组成之一。ATM调整由于DNA损伤引发的DNA修复和凋亡通路,该通路主要表现为DNA损伤激活ATM激酶,ATM激酶磷酸化其下游的相应蛋白,使细胞在细胞周期关卡处停滞分裂,主要是G1－S期和G2－M期的阻滞,使损伤的DNA得以修复,当修复失败时,细胞进入凋亡进程。ATM磷酸化的蛋白质很多,如p53,cdc25A,cdc25C等,这些蛋白质对细胞周期关卡调控都非常重要,因此也就证明了ATM在细胞周期调控中的重要作用。     

肿瘤抑制蛋白p53的活性调控

p53 又称为分子警察或基因的保护神.在面对不同类型和强度的应激时,细胞究竟选择细胞周期停滞、凋亡还是衰老时 p53发挥中心调节作用.作为一种转录调控因子它主要通过对下游的目的基因进行转录调控来发挥功能.p53 结合 DNA 启动子能力也可通过多种方式被调节.这些调节机制主要包括 p53 的亚细胞定位调控、p53 的蛋白稳定性调控和 p53 的翻译后修饰.     

乙型肝炎病毒X蛋白结合蛋白（HBXIP）对细胞周期的影响

与乙肝病毒X蛋白（HBX）的C端结合,它具有抑制HBX活性的作用. 为进一步阐明HBXIP对细胞增殖的作用及其分子机制,构建了HBXIP的真核表达载体,并将其稳定转染至正常人肝细胞系L-O2细胞中,建立了稳定表达HBXIP蛋白的肝细胞系,命名为L-O2-hbxip. 然后,应用MTT、BrdU标记实验和流式细胞术等方法,发现HBXIP过表达后,L-O2细胞的生长速度明显加快,可促进细胞由G₁期进入到S期,表明HBXIP具有促进L-O2-hbxip细胞增殖的作用.应用免疫印迹对有关细胞周期相关蛋白进行了检测. 结果显示,HBXIP过表达时可上调细胞周期蛋白D₁、细胞周期蛋白E的表达,并下调p21和p27的表达,从而调节细胞周期,产生对细胞增殖的影响.     

细胞周期蛋白和细胞周期

细胞周期是当前细胞生物学和分子生物学的热门研究课题之一。细胞生物学家、分子生物学家和遗传学家们运用了不同的材料对细胞周期G_1→S、S→G_2、G_2→M和M→G_1等过渡的调控问题进行了研究,其中以周期蛋白和p34~(cdc2)相互作用的研究最为引人注目。在G_2→M过渡期,p34~(cdc2)和周期蛋白B结合,经历一系列的磷酸化和去磷酸化过程,形成有活性的MPF,实现G_2→M期的过渡,在M期中/后期,周期蛋白B降解,致使MPF失活,细胞离开M期;在G_1→S期过渡时,p34~(cdc2)和G_1周期蛋白结合,引起DNA的复制,使细胞进入S期。此外还发现不少cdc 2的类似物在细胞周期各过渡期也有作用。因此,不同的周期蛋白和不同的cdc 2产物,参与细胞周期的方式不同。细胞周期的调控是多途径的和多层次的,这已成为进一步揭示细胞周期调控活动所必需研究的问题。     

p16INK4a基因的功能及其调控

p16^INK4a蛋白能抑制CDK4和CDK6的活性,使pRb处于非磷酸化或低磷酸化状态而能与转录因子E2Fs结合,从而抑制DNA 的合成,阻止细胞由G1期进入S期.p16^INK4a的表达受Ets1和Ets2的正调控,受Bmi-1的负调控.p16^INK4a基因缺失、突变、甲基化、RNA剪接加工错误可导致细胞周期失控和癌变.应用p16^INK4a对某些肿瘤进行基因治疗的研究正在进行中.     

小干扰RNA抑制LRP16基因表达限制了MCF-7乳腺癌细胞增殖

雌激素雌二醇上调人乳腺癌细胞MCF 7中LRP16基因表达 ,该基因过表达促进MCF 7细胞增殖 .为进一步探讨LRP16基因不同表达水平对MCF 7细胞增殖的影响以及对雌激素的反应性增殖能力 ,采用针对LRP16基因特异的小干扰RNA策略 ,通过逆转录病毒介导及抗性筛选构建了LRP16基因被稳定抑制的 2个MCF 7细胞系 ,针对绿色荧光蛋白的干扰序列作为阴性对照 .Northern印迹实验检测了LRP16基因在各个细胞株中mNRA的水平 ,与对照组细胞比较 ,针对LRP16基因不同位置的 2个小干扰RNA可分别将该基因抑制 90 %和 6 0 % .细胞增殖试验结果显示 ,MCF 7细胞中LRP16基因表达抑制率越高 ,细胞增殖速率减慢越显著 (P <0 0 5 ) ;软琼脂集落形成试验结果显示 ,抑制LRP16基因在MCF 7细胞中表达 ,限制了细胞锚定非依赖性生长 ;细胞周期分析结果表明 ,LRP16基因抑表达使MCF 7细胞G1 S周期转换受抑 ;Western印迹结果表明 ,LRP16基因表达抑制的细胞中细胞周期蛋白E及细胞周期蛋白D1蛋白水平显著下调 ,但未检测到P5 3及Rb蛋白表达水平的影响 .雌二醇刺激的增殖实验结果显示 ,抑制LRP16基因表达没有消除MCF 7细胞的反应性增殖特征 .上述结果表明 ,LRP16基因表达量与MCF 7细胞增殖能力密切相关 ,抑制其表达可有效限制MCF 7细胞的增殖能力 ,提     

Cyclin E as molecular marker in the management of breast cancer: a review

Over the past decade numerous molecular markers have been identified that may play a role in breast carcinogenesis and prognosis. The most commonly used markers in clinical practice are the estrogen receptor, progesterone receptor and HER-2/neu. Recent studies found cyclin E to be a promising prognostic indicator in breast cancer and examined its potential as a target for therapy. Further studies demonstrated that cyclin E levels were periodic during the cell cycle, with levels of protein peaking in the G1 phase. This peak in cyclin E levels also correlated with maximum enzymatic function of the cyclin E-cdk2 complex, suggesting a critical role of cyclin E in regulating G1 to S-phase transition. Studies examining the relevance of cyclin E alterations in breast cancer have shown gene amplifications in some breast cancer cell lines, data that provide strong support for the role of cyclin E in breast carcinogenesis. It is believed that the most significant cyclin E alteration is post-translational cleavage of full-length cyclin E into low molecular weight forms that are hyperactive compared to the 50-kDa, full-length protein and correlate with increasing stage and grade of breast cancer. The role of cyclin E in the prognosis and therapy of breast cancer is reviewed according to recent publications.     

Rictor regulates FBXW7-dependent c-Myc and cyclin E degradation in colorectal cancer cells

Rictor (Rapamycin-insensitive companion of mTOR) forms a complex with mTOR and phosphorylates and activates Akt. Activation of Akt induces expression of c-Myc and cyclin E, which are overexpressed in colorectal cancer and play an important role in colorectal cancer cell proliferation. Here, we show that rictor associates with FBXW7 to form an E3 complex participating in the regulation of c-Myc and cyclin E degradation. The Rictor-FBXW7 complex is biochemically distinct from the previously reported mTORC2 and can be immunoprecipitated independently of mTORC2. Moreover, knocking down of rictor in serum-deprived colorectal cancer cells results in the decreased ubiquitination and increased protein levels of c-Myc and cyclin E while overexpression of rictor induces the degradation of c-Myc and cyclin E proteins. Genetic knockout of FBXW7 blunts the effects of rictor, suggesting that rictor regulation of c-Myc and cyclin E requires FBXW7. Our findings identify rictor as an important component of FBXW7 E3 ligase complex participating in the regulation of c-Myc and cyclin E protein ubiquitination and degradation. Importantly, our results suggest that elevated growth factor signaling may contribute to decrease rictor/FBXW7-mediated ubiquitination of c-Myc and cyclin E, thus leading to accumulation of cyclin E and c-Myc in colorectal cancer cells.     

MiRNA-27a controls FBW7/hCDC4-dependent cyclin E degradation and cell cycle progression

The F-box protein FBW7/hCDC4 is a tumor suppressor that acts as the substrate recognition component of an SCF ubiquitin ligase that targets numerous oncoproteins for proteasomal degradation. In this study, we investigated whether FBW7 is regulated by microRNAs, using a screen combining bioinformatic analysis, luciferase reporters and microRNA libraries. The ubiquitous miR-27a was identified as a major suppressor of FBW7 and in line with this, miR-27a prohibited ubiquitylation and turnover of the key FBW7 substrate cyclin E. Notably, we found that miR-27a only suppresses FBW7 during specific cell cycle phases, relieving its negative impact at the G1 to S-phase transition, prior to cyclin E protein degradation. We also demonstrate that attenuation of FBW7 by miR-27a overexpression leads to improper cell cycle progression and DNA replication stress, consistent with dysregulation of cyclin E expression. Finally, in the context of human cancer, miR-27a was discovered to be generally overexpressed in pediatric B-ALL and its expression to be inversely correlated with that of FBW7 in hyperdiploid cases of B-ALL. These data provide evidence for microRNA-mediated regulation of FBW7, and highlight the role of miR-27a as a novel factor fine-tuning the periodic events regulating cell cycle progression.     

Artemis interacts with the Cul4A-DDB1DDB2 ubiquitin E3 ligase and regulates degradation of the CDK inhibitor p27

Artemis, a member of the SNM1 gene family, is a multifunctional phospho-protein that has been shown to have important roles in V(D)J recombination, DNA double strand break repair, and stress-induced cell-cycle checkpoint regulation. We show here that Artemis interacts with the Cul4A-DDB1 E3 ubiquitin ligase via a direct interaction with the substrate-specificity receptor DDB2. Furthermore, Artemis also interacts with the CDK inhibitor and tumor suppressor p27, a substrate of the Cul4A-DDB1 ligase, and both DDB2 and Artemis are required for the degradation of p27 mediated by this complex. We also show that the regulation of p27 by Artemis and DDB2 is important for cell cycle progression in normally proliferating cells and in response to serum deprivation. These findings thus define a function for Artemis as an effector of Cullin-based E3 ligase-mediated ubiquitylation, demonstrate a novel pathway for the regulation of p27, and show that Cul4A-DDB1^DDB2-Artemis regulates G₁ phase cell cycle progression in mammalian cells.