周期蛋白和周期蛋白依赖性激酶及相关激酶抑制剂在细胞周期进程中的调控机制研究进展

在细胞发育过程中,细胞周期起着至关重要的作用。细胞周期进程主要受细胞周期蛋白依赖性激酶(cyclin dependent kinase, CDK)、周期蛋白和内源性CDK抑制剂(cyclin-dependent kinase inhibitors,CKI)调控。其中,CDK是主要的细胞周期调节因子,可与周期蛋白结合形成周期蛋白-CDK复合物,从而使数百种底物磷酸化,调控分裂间期和有丝分裂进程。各类细胞周期蛋白的活性异常,可引起不受控制的癌细胞增殖,导致癌症的发生与发展。因此,了解CDK的活性变化情况、周期蛋白-CDK的组装以及CKI的作用,将有助于了解细胞周期进程中潜在的调控过程,为癌症与疾病的治疗和CKI治疗药物的研发提供基础。本文关注了CDK激活和灭活的关键事件,并总结了周期蛋白-CDK在特定时期及位置的调控过程,以及相关CKI治疗药物在癌症及疾病中的研究进展,最后简单阐述了细胞周期进程研究面临的问题和存在的挑战,以期为后续细胞周期进程的深入研究提供参考和思路。     

细胞周期蛋白依赖性激酶2的功能及其抑制剂的研究

细胞周期蛋白依赖性激酶2(cyclin-dependent kinase 2,CDK2)是CDK家族中的重要成员之一.CDK2的表达或功能异常与多种疾病(如肿瘤、病毒复制与感染、免疫缺陷性疾病和雄性不育等)发生机制密切相关.CDK2抑制剂已成为抗肿瘤药物研发中的一个重要靶点.该文对CDK2在细胞周期调控、细胞增殖、细胞...     

高等植物细胞周期调控研究进展

高等植物的细胞周期（cell cycle)在其生长发育过程中受严格调控的,细胞周期的运转是基因有序表达的结果,并受的因素的影响,植物细胞周期研究近年来已取得的较大的进展,本文综述了近几年与植物细胞周期调控相关的细胞周期蛋白（cyclins),细胞周期蛋白依赖性激酶（CDKs)等内部调控因子及外源影响因素的研究进展。     

糖原合酶激酶3β以细胞周期蛋白D1依赖性方式引发人肺腺癌细胞A549细胞周期阻滞

对糖原合酶激酶3β（glycogen synthase kinase 3β,6SK3β）在细胞增殖中的作用研究,在不同细胞系和不同刺激因素作用下得出了不同结论,本文旨在探讨GSK3β在人肺腺癌细胞系A549细胞生长中的直接作用。A549细胞瞬时转染持续激活型S9A-GSK3β以及显性负突变型KM-GSK3β两种GSK3β突变型质粒,改变GSK3β活性。24 h后,分别进行细胞计数,流式细胞术及Western blot检测。结果显示,增强GSK3β活性可导致细胞数量下降,G．期细胞百分比升高。细胞周期蛋白D1表达水平被GSK3β下调。结果提示,GSK3β可能以细胞周期蛋白D1依赖性方式引发A549细胞的G,期阻滞,从而发挥生长抑制效应。     

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。     

黏附分子在肿瘤发生及发展中的作用

细胞黏附分子是以配体和受体相结合的形式,介导细胞与细胞间或细胞与基质间相互作用的一类分子,参与机体的多种重要生理和病理过程.近年来,在对肿瘤发生和发展的研究中发现,黏附分子可通过多种途径影响肿瘤的生长、浸润及转移过程.因此.对黏附分子在肿瘤发生和发展中作用及机制的深入研究,可为肿瘤早期诊断提供重要的分子指标和发现新的治疗靶标.并为进而形成临床诊疗新策略提供重要理论支持.现就几种重要黏附分子在肿瘤生长与转移中的作用进行综述.     

Polo样激酶1在细胞周期及细胞周期监测点中的功能

Plk1（Polo-like kinase 1）是一类从酵母到人类都高度保守的丝氨酸/苏氨酸蛋白激酶,是真核细胞有丝分裂的重要调控因子.Plk1随有丝分裂进程定位于不同位点,调节分裂期进入、纺锤体形成和胞质分裂等过程.Plk1能够与磷酸化的停靠蛋白结合,从而在不同空间被激活以满足其在细胞周期中的不同功能.Plk1还参与G2和M期DNA损伤监测点的调节,对于DNA损伤恢复后重新进入有丝分裂期是必须的.目前,Plk1的重要功能尤其是在DNA损伤监测点中发挥的重要功能正在被广泛研究.Plk1在多种恶性肿瘤中存在过表达且与肿瘤发生密切相关,对于Plk1功能的深入研究为以Plk1为靶的肿瘤治疗提供理论依据     

Cdk6在维持ES细胞自我更新中的作用

细胞周期蛋白依赖性激酶6（cyclin dependent kinase 6,Cdk6）对胚胎早期发育有着重要的作用.然而,它在胚胎干（embryonic stem,ES）细胞中的生物学功能仍不清楚.在该研究中,我们运用RNA干扰技术和基因表达分析方法探索了Cdk6在小鼠胚胎干细胞中的功能及分子机制.结果表明：Cdk6的表达水平与小鼠ES细胞的自我更新密切相关.首先,维甲酸（RA）处理和白血病抑制因子（LIF）去除实验显示 ,随着ES细胞的分化,Cdk6的表达水平明显降低.更为重要的是,RNA干扰介导的Cdk6表达抑制导致ES细胞自我更新相关基因的显著下调,同时伴随细胞分化基因的表达激活,提示Cdk6对维持ES细胞自我更新至关重要.     

D类细胞周期素在细胞周期中的作用

细胞周期进程由周期性表达的细胞周期素和细胞周期素信号性激酶推动完成,CyclinD在G1期中期开始表达,是最早合成的细胞周期素,它与Cdk4或Cdk6形成的活性复合物,不仅可促进pRb的磷酸化,也可隔离P27对cyclinE-Cdk2活性的抑制,使细胞顺利越过G1期进入S期,除此之外,cyclinD过度表达还可抑制细胞增殖,在细胞分化和衰老过程中发挥重要作用。     

The role of mitochondrial electron transport in tumorigenesis and metastasis

Background

Tumor formation and spread via the circulatory and lymphatic drainage systems is associated with metabolic reprogramming that often includes increased glycolytic metabolism relative to mitochondrial energy production. However, cells within a tumor are not identical due to genetic change, clonal evolution and layers of epigenetic reprogramming. In addition, cell hierarchy impinges on metabolic status while tumor cell phenotype and metabolic status will be influenced by the local microenvironment including stromal cells, developing blood and lymphatic vessels and innate and adaptive immune cells. Mitochondrial mutations and changes in mitochondrial electron transport contribute to metabolic remodeling in cancer in ways that are poorly understood.

Scope of Review

This review concerns the role of mitochondria, mitochondrial mutations and mitochondrial electron transport function in tumorigenesis and metastasis.

Major Conclusions

It is concluded that mitochondrial electron transport is required for tumor initiation, growth and metastasis. Nevertheless, defects in mitochondrial electron transport that compromise mitochondrial energy metabolism can contribute to tumor formation and spread. These apparently contradictory phenomena can be reconciled by cells in individual tumors in a particular environment adapting dynamically to optimally balance mitochondrial genome changes and bioenergetic status.

General Significance

Tumors are complex evolving biological systems characterized by genetic and adaptive epigenetic changes. Understanding the complexity of these changes in terms of bioenergetics and metabolic changes will permit the development of better combination anticancer therapies. This article is part of a Special Issue entitled Frontiers of Mitochondrial Research.     

The role of the epidermal growth factor receptor family in mammary tumorigenesis and metastasis

A number of receptor systems have been implicated to play an important role in the development and progression of many human cancers. The epidermal growth factor (EGF) receptor tyrosine kinase family has been found to consistently play a leading role in tumor progression. Indeed, in human breast cancer cases the prognosis of a patient is inversely correlated with the overexpression and/or amplification of this receptor family. Furthermore, downstream signaling components such as the Src kinases, PI3'K, and the Ras pathway display evidence of deregulation that can accelerate tumor progression. The transgenic mouse system has been ideal in elucidating the biological significance of this receptor family in mammary tumorigenesis. Molecular events involved in mammary tumorigenesis such as ligand binding, receptor dimerization, and the activation of downstream pathways have been addressed using this system. Although there are many molecular steps that appear to drive each stage of tumor development, the EGF receptor family appears to play a causal role in the progression to a transformed phenotype.     

A critical role of Gbetagamma in tumorigenesis and metastasis of breast cancer

A growing body of evidence indicates that G protein-coupled receptors (GPCRs) are involved in breast tumor progression and that targeting GPCRs may be a novel adjuvant strategy in cancer treatment. However, due to the redundant role of multiple GPCRs in tumor development, it may be necessary to target a common signaling component downstream of these receptors to achieve maximum efficacy. GPCRs transmit signals through heterotrimeric G proteins composed of Gα and Gβγ subunits. Here we evaluated the role of Gβγ in breast tumor growth and metastasis both in vitro and in vivo. Our data show that blocking Gβγ signaling with Gα(t) or small molecule inhibitors blocked serum-induced breast tumor cell proliferation as well as tumor cell migration induced by various GPCRs in vitro. Moreover, induced expression of Gα(t) in MDA-MB-231 cells inhibited primary tumor formation and retarded growth of existing breast tumors in nude mice. Blocking Gβγ signaling also dramatically reduced the incidence of spontaneous lung metastasis from primary tumors and decreased tumor formation in the experimental lung metastasis model. Additional studies indicate that Gβγ signaling may also play a role in the generation of a tumor microenvironment permissive for tumor progression, because the inhibition of Gβγ signaling attenuated leukocyte infiltration and angiogenesis in primary breast tumors. Taken together, our data demonstrate a critical role of Gβγ signaling in promoting breast tumor growth and metastasis and suggest that targeting Gβγ may represent a novel therapeutic approach for breast cancer.     

Cdk5与学习和记忆的研究进展

越来越多的证据表明,Cdk5通过与大量蛋白相互作用而在学习和记忆过程中发挥重要作用。近来,关于Cdk5的研究结果不仅证实其参与药物成瘾过程中细胞间的通路改变,且其活性与一些神经退行性疾病的发生有关。本文就Cdk5对学习和记忆的影响及其相关机制的研究进展予以综述。     

The emerging role for Cullin 4 family of E3 ligases in tumorigenesis

As a member of the Cullin-RING ligase family, Cullin-RING ligase 4 (CRL4) has drawn much attention due to its broad regulatory roles under physiological and pathological conditions, especially in neoplastic events. Based on evidence from knockout and transgenic mouse models, human clinical data, and biochemical interactions, we summarize the distinct roles of the CRL4 E3 ligase complexes in tumorigenesis, which appears to be tissue- and context-dependent. Notably, targeting CRL4 has recently emerged as a noval anti-cancer strategy, including thalidomide and its derivatives that bind to the substrate recognition receptor cereblon (CRBN), and anticancer sulfonamides that target DCAF15 to suppress the neoplastic proliferation of multiple myeloma and colorectal cancers, respectively. To this end, PROTACs have been developed as a group of engineered bi-functional chemical glues that induce the ubiquitination-mediated degradation of substrates via recruiting E3 ligases, such as CRL4 (CRBN) and CRL2 (pVHL). We summarize the recent major advances in the CRL4 research field towards understanding its involvement in tumorigenesis and further discuss its clinical implications. The anti-tumor effects using the PROTAC approach to target the degradation of undruggable targets are also highlighted.     

The role of tenascin-C in tissue injury and tumorigenesis

The extracellular matrix molecule tenascin-C is highly expressed during embryonic development, tissue repair and in pathological situations such as chronic inflammation and cancer. Tenascin-C interacts with several other extracellular matrix molecules and cell-surface receptors, thus affecting tissue architecture, tissue resilience and cell responses. Tenascin-C modulates cell migration, proliferation and cellular signaling through induction of pro-inflammatory cytokines and oncogenic signaling molecules amongst other mechanisms. Given the causal role of inflammation in cancer progression, common mechanisms might be controlled by tenascin-C during both events. Drugs targeting the expression or function of tenascin-C or the tenascin-C protein itself are currently being developed and some drugs have already reached advanced clinical trials. This generates hope that increased knowledge about tenascin-C will further improve management of diseases with high tenascin-C expression such as chronic inflammation, heart failure, artheriosclerosis and cancer.