MDM2反义寡核苷酸联合紫杉醇对乳腺癌MCF-7细胞株的作用

目的:探讨靶向MDM2反义寡核苷酸(ASON)联合紫杉醇对乳腺癌MCF-7细胞株的影响。方法:合成一段与MDM2 mRNA特异性结合的反义寡核苷酸和与反义寡核苷酸有4个碱基不同的的错义寡核苷酸(MON),脂质体2000介导不同浓度的MDM2ASON转染MCF-7乳腺癌细胞系,转染的乳腺癌细胞通过1μmol/L紫杉醇药物处理后,采用RT-PCR和Western Blot方法检测MDM2 ASON联合紫杉醇的协同作用及对乳腺癌MCF-7细胞株的抑制效率,MTT观察给药后MCF-7细胞的增殖能力和药物敏感性。结果:MDM2反义寡核苷酸联合紫杉醇明显下调MDM2 mRNA及MDM2蛋白表达水平,抑制MCF-7细胞的生长,随着MDM2 ASON浓度的增加,MDM2表达越来越低,协同作用越来越强,呈剂量依赖关系,A500联合紫杉醇的协同作用最明显,MTT显示紫杉醇处理的转染MCF-7细胞增殖抑制率明显增高,A500抑制增殖作用最明显,抑制率达(13.0±0.84)%。结论:不同浓度MDM2 ASON转染后的乳腺癌MCF-7细胞,等浓度紫杉醇处理后,乳腺癌MCF-7细胞MDM2表达明显降低,细胞凋亡增加,,MDM2 ASON联合紫杉醇对MCF-7细胞有协同作用,提高了乳腺癌MCF-7细胞对紫杉醇的药物敏感性。     

人MDM2基因真核表达载体的构建及其与p53的相互作用

目的:构建带Flag标签的MDM2真核表达载体,并检测MDM2与p53的相互作用。方法:从人乳腺文库中PCR扩增MDM2编码序列,将其插入pcDNA3.0-Flag载体,转染293T细胞后用Western印迹检测其在293T细胞中的表达,并通过免疫共沉淀实验检测MDM2与p53的相互作用。结果:双酶切和测序结果表明,Flag-MDM2真核表达载体构建成功,转染293T细胞后成功表达;免疫共沉淀实验证明Flag-MDM2与p53存在相互作用。结论:构建了带Flag标签的人MDM2真核表达载体,并检测了MDM2与p53之间的相互作用,为研究MDM2的功能奠定了基础。     

羽扇豆醇介导MDM2-p53通路对胃癌细胞生物学行为的影响

目的:探讨羽扇豆醇介导鼠双微基因2(Mouse double microgene 2,MDM2)-p53通路对胃癌细胞生物学行为的影响及相关机制。方法:对数生长期的胃癌小鼠MFC细胞株随机分为三组。实验1组与实验2组给予10 mg/L和20 mg/L的羽扇豆醇处理,对照组以等体积的1×磷酸盐缓冲液处理。对比三组MFC细胞细胞增殖、凋亡、迁移与侵袭,及MDM2-p53通路蛋白表达。结果:细胞处理后6 h与12 h,实验1组与实验2组的细胞增殖指数、细胞迁移与侵袭指数、MDM2蛋白相对表达水平显著低对于对照组,实验2组也低于实验1组,对比差异都有统计学意义(P<0.05)。细胞处理后6 h与12 h,实验1组与实验2组的细胞凋亡指数、p53蛋白相对表达水平显著高于对照组,实验2组也高于实验1组,对比差异都有统计学意义(P<0.05)。结论:羽扇豆醇能促进胃癌细胞p53蛋白的表达,抑制MDM2蛋白的表达,从而促进细胞凋亡,抑制胃癌的增殖、侵袭与转移,且具有剂量依赖性。     

Cyclin G1、MDM2和p53在胃腺癌组织中的表达及相关性研究

目的探讨细胞周期蛋白G1(cyclinG1)、鼠双微体基因(MDM2)和p53在胃腺癌组织中的表达意义及相关性。方法采用免疫组织化学方法(SP法)检测54例胃腺癌组织中cyclinG1、MDM2和p53的表达,以20例正常胃粘膜组织作为对照。结果cyclinG1、MDM2、p53在胃腺癌组织中的阳性表达率分别为62.96%、53.70%、44.44%,而在正常胃粘膜组织中的阳性表达率分别为0%,15.00%,0%,两者比较差异均有显著性(P均<0.05),cyclinG1、MDM2在胃腺癌中的表达与肿瘤的分化程度相关(P均<0.05)。胃癌组织中MDM2蛋白的表达与p53的表达呈正相关(r=0.307),而cyclinG1蛋白的表达与p53的表达无明显相关性。结论CyclinG1、MDM2、p53的阳性表达在胃癌的发生、发展过程中起着重要的的作用。MDM2可能是通过调控p53的活性而促进胃癌的发生、发展,cyclinG1可能以不依赖p53的途径发挥作用。     

泛素蛋白连接酶MDM2活性及稳定性调控的研究进展

泛素蛋白连接酶MDM2(Murine double minute 2)具有癌基因活性, MDM2高表达会导致抑癌基因p53失活而诱发肿瘤, 但在至少7%的肿瘤中p53基因正常而mdm2异常扩增, 表明MDM2还具有其他底物分子, 以p53不依赖的方式促进肿瘤的发生。鉴于MDM2的重要作用, 文章在基因水平、转录水平、翻译后修饰水平、相互作用分子的调节等方面系统总结了目前对MDM2调控的主要研究机制及其进展。     

温阳化瘀法对月经周期紊乱患者p53,p21,MDM2蛋白表达的影响

目的:通过对月经周期紊乱患者的细胞周期相关基因的表达水平进行分析,得出温阳化瘀法在此病上的治疗效果。方法:选取我院妇科收治的月经周期紊乱患者120例,参照随机原则共分为2组,其中西医治疗组59例,给予醋酸甲羟孕酮片和克罗米芬口服;实验组61例,在西医治疗基础上给予温阳化瘀中药治疗,每日1剂;另外随机选取同期体检健康的60名女性作为正常对照组,在治疗结束后,应用免疫组化方法对全部受试者进行p53、p21以及MDM2蛋白表达检测,同时应用统计学软件对相关结果进行分析。结果:1p53和p21蛋白的阳性表达主要在细胞核,MDM2蛋白阳性表达定位在细胞核和(或)胞质;2正常子宫内膜组织中p53蛋白阳性表达率为(36.67%),p21表达率为(33.33%),显著高于月经周期紊乱患者,中药治疗组的p53蛋白阳性表达率为(19.67%),p21达率为(18.03%),显著高于西医治疗组,P0.05,差异有统计学意义;3正常子宫内膜组织中MDM2蛋白阳性表达率为(1.67%),显著低于月经周期紊乱患者,中药治疗组的MDM2蛋白阳性表达率为(32.77%),显著低于西医治疗组(50.85%),P0.05,差异有统计学意义。结论:与健康妇女相比,月经周期紊乱患者的p53和p21蛋白阳性表达率显著降低,MDM2蛋白阳性率显著升高,应用温阳化瘀法能够显著改善月经周期紊乱患者细胞周期相关基因的表达水平。     

MDM2-P53蛋白质相互作用的小分子抑制物

p53作为重要的抑癌基因已经成为一个治疗癌症重点的突破目标之一。直接调节p53基因或调节P53和MDM2蛋白质相互作用是再激活p53基因的两种重要机制。对于表达野生型P53的癌症设计小分子阻断剂阻断MDM2与P53蛋白相互作用是一个很有前景的治疗癌症的方向。文章主要总结了作为治疗癌症的新方法-MDM2-P53蛋白相互作用小分子抑制物的最新研究进展,其中最新的是人工合成化合物Nutlin-3和MI-219。     

MDM2在原发性肝细胞癌中的表达

目的检测MDM2蛋白及其mRNA在原发性肝细胞癌中的表达,探讨MDM2在原发性肝细胞癌发生发展中作用及意义.方法采用免疫组织化学、原位分子杂交和细胞图像分析技术,检测肝细胞癌组织及其对应癌旁肝组织(各20例),正常肝组织(5例)中MDM2蛋白及其mRNA 表达情况.结果在肝细胞癌组织、癌旁肝组织和正常肝组织中,MDM2蛋白免疫组织化学阳性反应颗粒的平均光密度分别为:0.404±0.105, 0.302±0.067, 0.087±0.034.肝细胞癌组织与癌旁肝组织、正常肝组织相比,差异均有显著性意义(P<0.05).MDM2 mRNA在肝细胞癌组织中呈阳性表达,而癌旁肝组织及正常肝组织均呈阴性.结论 MDM2过度表达在原发性肝细胞癌的发生发展过程中可能发挥了重要作用.     

Nucleostemin与MDM2在肺腺癌组织中的表达及意义

核干细胞因子(Nucleostemin,NS)是细胞增殖的调节因子,在肺腺癌组织中的表达及与鼠双微染色体2(murine double minute 2,MDM2)表达的相关性不清楚.通过反转录聚合酶链反应(RT-PCR)检测22对肺腺癌和癌旁正常组织NS mRNA的表达;应用免疫组织化学SP法检测45例肺腺癌和22例癌旁正常组织NS与MDM2蛋白的表达,分析其相关性及意义.研究发现,肺腺癌组织中NS mRNA的相对表达强度明显高于癌旁正常组织(P0.01).NS和MDM2蛋白在肺腺癌组织中的阳性表达率分别为73.3%(33/45)、57.8%(26/45),而癌旁正常组织中无阳性表达(P0.01).二者的阳性表达均与组织学分级相关(P0.05),并且表达呈正相关(P0.05),而与患者性别、年龄、肿瘤大小、TNM分期及淋巴结转移无关(P0.05).结果表明NS基因的高表达对肺腺癌细胞的恶性增殖发挥了重要作用,可能是通过p53通路对细胞周期影响所实现的.     

RyR反义寡核苷酸对气道平滑肌细胞增殖及细胞内钙离子浓度的影响

目的:观察RyR(Ryanodme受体)反义寡核苷酸(ASODN)对大鼠ASMCs(airway smooth muscle cells,气道平滑肌细胞)增殖的抑制作用及对细胞内钙离子浓度的影响.方法:采用胶原酶消化法培养大鼠ASMCs,利用LipofectamineTM2000将正义、反义RyR寡核苷酸导入大鼠ASMCs,MTS/PES法检测不同寡核苷酸对大鼠ASMCs增殖的抑制作用,RT-PCR检测大鼠ASMCs中RyR的mRNA表达,流式细胞仪测定不同寡核苷酸对细胞内钙离子浓度的影响.结果:RyR反义寡核苷酸可抑制大鼠ASMCs的增殖,降低其RyR受体mRNA的表达,并能降低兴奋后的细胞内钙离子浓度的升高.结论:RyR反义寡核苷酸可能通过降低兴奋后的细胞内钙离子浓度来抑制大鼠ASMCs的增殖.     

The MDM2 RING Domain and Central Acidic Domain Play Distinct Roles in MDM2 Protein Homodimerization and MDM2-MDMX Protein Heterodimerization

The oncoprotein murine double minute 2 (MDM2) is an E3 ligase that plays a prominent role in p53 suppression by promoting its polyubiquitination and proteasomal degradation. In its active form, MDM2 forms homodimers as well as heterodimers with the homologous protein murine double minute 4 (MDMX), both of which are thought to occur through their respective C-terminal RING (really interesting new gene) domains. In this study, using multiple MDM2 mutants, we show evidence suggesting that MDM2 homo- and heterodimerization occur through distinct mechanisms because MDM2 RING domain mutations that inhibit MDM2 interaction with MDMX do not affect MDM2 interaction with WT MDM2. Intriguingly, deletion of a portion of the MDM2 central acidic domain selectively inhibits interaction with MDM2 while leaving intact the ability of MDM2 to interact with MDMX and to ubiquitinate p53. Further analysis of an MDM2 C-terminal deletion mutant reveals that the C-terminal residues of MDM2 are required for both MDM2 and MDMX interaction. Collectively, our results suggest a model in which MDM2-MDMX heterodimerization requires the extreme C terminus and proper RING domain structure of MDM2, whereas MDM2 homodimerization requires the extreme C terminus and the central acidic domain of MDM2, suggesting that MDM2 homo- and heterodimers utilize distinct MDM2 domains. Our study is the first to report mutations capable of separating MDM2 homo- and heterodimerization.     

Posttranslational modification of MDM2

The functions of the MDM2 protein, in particular its E3 ubiquitin ligase activity and its ability to interact with a number of cellular proteins intimately involved in growth regulation, are modulated by sumoylation and multisite phosphorylation. These posttranslational mechanisms not only regulate the intrinsic activity of MDM2 in response to cellular stresses, but also govern its subcellular localization, differentiate between MDM2-mediated ubiquitination of p53 and autoubiquitination, integrate the stress response with mechanisms that mediate cell survival, and modulate the interaction of MDM2 with cellular and viral proteins. In this review, we summarize our current knowledge of the role of posttranslational modifications of MDM2 and their functional relevance.     

MDM2, an introduction

The murine double minute 2 (mdm2) gene encodes a negative regulator of the p53 tumor suppressor. Amplification of mdm2 or increased expression by unknown mechanisms occurs in many tumors. Thus, increased levels of MDM2 would inactivate the apoptotic and cell cycle arrest functions of p53, as do deletion or mutation of p53, common events in the genesis of many kinds of tumors. MDM2 functions as an E3 ubiquitin ligase to degrade p53. MDM2 also binds another tumor suppressor, ARF. This interaction sequesters MDM2 in the nucleolus away from p53, thus activating p53. Many additional MDM2 interacting proteins have been identified. Functions of MDM2 independent of p53 have also been identified. This article is an introduction to MDM2, its structure and biological functions, as well as its relationship to its binding partners.     

The RING finger domain of MDM2 is essential for MDM2-mediated TGF-beta resistance

In this study, we attempt to gain insights into the molecular mechanism underlying MDM2-mediated TGF-beta resistance. MDM2 renders cells refractory to TGF-beta by overcoming a TGF-beta-induced G1 cell cycle arrest. Because the TGF-beta resistant phenotype is reversible upon removal of MDM2, MDM2 likely confers TGF-beta resistance by directly targeting the cellular machinery involved in the growth inhibition by TGF-beta. Investigation of the structure-function relationship of MDM2 reveals three elements essential for MDM2 to confer TGF-beta resistance in both mink lung epithelial cells and human mammary epithelial cells. One of these elements is the C-terminal half of the p53-binding domain, which at least partially retained p53-binding and inhibitory activity. Second, the ability of MDM2 to mediate TGF-beta resistance is disrupted by mutation of the nuclear localization signal, but is restored upon coexpression of MDMX. Finally, mutations of the zinc coordination residues of the RING finger domain abrogates TGF-beta resistance, but not the ability of MDM2 to inhibit p53 activity or to bind MDMX. These data suggest that RING finger-mediated p53 inhibition and MDMX interaction are not sufficient to cause TGF-beta resistance and imply a crucial role of the E3 ubiquitin ligase activity of this domain in MDM2-mediated TGF-beta resistance.     

MDM2 inhibitors for cancer therapy

The tumor suppressor p53 is a powerful antitumoral molecule frequently inactivated by mutations or deletions in cancer. However, half of all human tumors express wild-type p53, and its activation by antagonizing its negative regulator murine double minute 2 (MDM2) might offer a new therapeutic strategy. Proof-of-concept experiments have demonstrated the feasibility of this approach in vitro but the development of pharmacological inhibitors has been challenging. Recently, potent and selective small-molecule MDM2 inhibitors have been identified. Studies with these compounds have strengthened the concept that selective, non-genotoxic p53 activation is a viable alternative to current cytotoxic chemotherapy but clinical validation is still pending. Here, the new developments in the quest for pharmacological p53 activators are reviewed with an emphasis on small-molecule inhibitors of the p53-MDM2 interaction.     

The MDM2-p53 interaction

Activation of the p53 protein protects the organism against the propagation of cells that carry damaged DNA with potentially oncogenic mutations. MDM2, a p53-specific E3 ubiquitin ligase, is the principal cellular antagonist of p53, acting to limit the p53 growth-suppressive function in unstressed cells. In unstressed cells, MDM2 constantly monoubiquitinates p53 and thus is the critical step in mediating its degradation by nuclear and cytoplasmic proteasomes. The interaction between p53 and MDM2 is conformation-based and is tightly regulated on multiple levels. Disruption of the p53-MDM2 complex by multiple routes is the pivotal event for p53 activation, leading to p53 induction and its biological response. Because the p53-MDM2 interaction is structurally and biologically well understood, the design of small lipophilic molecules that disrupt or prevent it has become an important target for cancer therapy.     

The tumour suppressor RASSF1A promotes MDM2 self-ubiquitination by disrupting the MDM2-DAXX-HAUSP complex

The tumour suppressor p53, which accumulates in response to DNA damage and induces cell-cycle arrest and apoptosis, has a key function in the maintenance of genome integrity. Under normal conditions, the antiproliferative effects of p53 are inhibited by MDM2, a ubiquitin ligase that promotes p53 ubiquitination and degradation. MDM2 is also self-ubiquitinated and degraded. Here, we show that the tumour suppressor RASSF1A regulates G(1)-S cell-cycle progression in a p53-dependent manner by promoting MDM2 self-ubiquitination and preventing p53 degradation. Importantly, RASSF1A associates with MDM2 and death-domain-associated protein (DAXX) in the nucleus, thereby disrupting the interactions between MDM2, DAXX, and the deubiquitinase, HAUSP, and enhancing the self-ubiquitin ligase activity of MDM2. Moreover, RASSF1A partially contributes to p53-dependent checkpoint activation at early time points in response to DNA damage. These findings reveal a new and important function for RASSF1A in regulating the p53-MDM2 pathway.