p53与Ras协同及其在肿瘤发生中的作用

肿瘤发生是抑癌基因失活和原癌基因激活共同作用的结果。p53基因被认为是目前最重要的抑癌基因, 50%以上的肿瘤中存在p53基因的点突变现象; 而Ras基因是肿瘤中突变率较高的原癌基因, 其突变率在某些肿瘤中高达30%~90%。研究发现, 肿瘤发生过程中抑癌基因p53与原癌基因Ras之间存在复杂的相互协同作用。根据目前的文献报道, p53与Ras之间的协同作用可以分为3种：第一, p53对Ras的调节作用; 第二, Ras对p53的调节作用; 第三, p53和Ras共同调控某些与肿瘤发生相关的关键基因。了解p53与Ras之间的3种调控作用将有助于我们进一步认识p53失活与Ras激活协同促进肿瘤发生的分子通路和机制, 同时也将为癌症的个性化治疗和药物靶点的选择提供重要依据。因此, 文章将对近年来所发现的p53与Ras的各种协同作用机制及其与肿瘤发生的关系进行概括和综述。     

p53在诱导性多潜能干细胞向肿瘤细胞转化中的作用

p53基因是抑制肿瘤形成的抑癌基因,p53通过阻断细胞周期、诱导衰老细胞凋亡和修复受损的DNA从而抑制肿瘤的形成。而突变的p53则具有相反的功能,被认为是促进细胞重编程的关键。这些发现表明p53在去分化过程中具有重要的作用,而肿瘤的形成与细胞重编程存在高度的相似性,所以探讨p53与诱导性多能干细胞(induced pluripotent stem cell,iPSC)和肿瘤形成之间的联系具有一定的意义。     

p53在肿瘤发生过程中的功能研究及进展

p53是迄今为止细胞中最为重要的肿瘤抑制因子之一.p53能够响应细胞内外众多的信号刺激,通过抑制细胞生长、诱导细胞凋亡、促进DNA损伤修复等过程抑制肿瘤的发生发展.近年来发现p53在细胞自噬、细胞代谢,尤其在葡萄糖代谢中也发挥重要作用.p53在超过1/2的人类肿瘤中,发生缺失或突变,提示p53突变和肿瘤发生是紧密相关的.本文将主要结合本研究组近十年来围绕p53所开展的相关研究,从p53自身稳定性的调控机制、p53与肿瘤发生、p53与细胞代谢以及p53调控非编码RNA方面进行简要综述,并展望p53研究的新方向.     

miRNA调控恶性黑色素瘤细胞上皮-间充质转化的分子网络及机制

黑色素瘤是一种极易发生转移的恶性皮肤肿瘤,具有高度的致死性。上皮-间充质细胞转化(Epithelial-mesenchymal transition, EMT)在胚胎发育过程中起到非常重要的作用,同时在肿瘤的发生和恶化过程中也扮演着重要的角色。miRNA具有广谱的调节能力,对于肿瘤发生和EMT形成都能产生不同程度的影响。本文整合黑色素瘤细胞系转录组和miRNA组测序数据,在转录组数据中筛选得到参与肿瘤EMT过程的基因,通过Mirsystem软件预测并从miRNA组数据中筛选出与之负相关的11个miRNA,包括miR-130a-3p、miR-130b-3p、miR-125a-5p、miR-30a-3p、miR-195-5p、miR-345-5p、miR-509-3-5p、miR-374a-5p、miR-509-5p、miR-148a-3p和miR-330-3p。经过生物信息学分析miRNA靶基因富集的分子网络和信号途径,发现了两个与细胞发育和细胞间相互作用密切相关的网络,以及多个参与调控EMT过程的信号通路。对11个miRNA进行分子生物学验证,发现miR-195-5p、miR-130a-3p、miR-509-5p和miR-509-3-5p共4个可以调节重要肿瘤基因的miRNA。本研究运用mRNA和miRNA两种转录组的测序数据筛选EMT相关miRNA的方法,为肿瘤多组学数据整合分析提供了新的研究思路,并以期能为肿瘤精准基因组学的发展发挥重要的推进作用。     

衰老或肿瘤: 端粒酶和p53的相互作用

端粒酶和p53两者在肿瘤和衰老的发生发展过程中都起着关键的作用。在人类大多数的肿瘤中都发现了这一现象: p53基因发生突变和端粒酶的重新激活。端粒酶和p53基因的治疗逐渐成为肿瘤治疗的重要手段之一。文章论述了端粒酶或p53基因敲除的不同组合的小鼠模型(mTR-/-p53+/+; mTR-/-P53-/-)的衰老与肿瘤表型, 对端粒功能异常可抑制或促进肿瘤发生的辩证作用作一综述, 以期理解p53与端粒酶在衰老与肿瘤发生中的辩证相互作用, 寻求一种治疗肿瘤的新思路。     

含p53保守结合位点的microRNA表达载体的构建及应用

目的:构建含p53保守结合位点的microRNA(miRNA)表达载体,促进相关miRNA在具有野生型p53蛋白细胞中的高效表达。方法:改构miRNA表达载体pCMV-miR,在其多克隆位点前插入p53保守结合位点,分别将miR-138、miR-34a和miR-21前体序列pre-miR-138、pre-miR-34a和pre-miR-21插入上述改构的载体pCMV/p53-miR,将构建的pCMV/p53-miR-138、pCMV/p53-miR-34a和pCMV/p53-miR-21表达载体转染具有野生型p53的HeLa细胞和不表达p53的H1299细胞,分析p53对上述miRNA表达调控的影响。结果:转染改构的miRNA表达载体后,HeLa细胞中miR-138、miR-34a和miR-21的表达水平明显提高,它们对应的已知靶基因Cyclin D3、CDK2和PTEN的表达同时被显著下调。结论:在p53转录调控作用下,具有p53保守结合位点的miRNA表达载体能够更加有效地提高miRNA的表达水平;构建的载体不但可用于促进相关miRNA的表达,也能用于miRNA是否受p53调控的检测。     

军事医学科学院肿瘤研究进展

本文从肝癌易感基因发现、炎症与肿瘤发生及其调控、p53与细胞凋亡调控、肿瘤标志物和治疗靶标发现等方面,综述军事医学科学院近年来关于肿瘤研究的进展.     

p53与肿瘤治疗

p53是目前发现的与人类肿瘤发病相关性最大的抑癌基因之一。野生型p53参与DNA损伤修复、细胞周期调控、细胞凋亡及抑制血管生成等。p53基因的突变会使上述功能丧失,从而导致肿瘤的形成。随着分子生物学技术的发展,对肿瘤抑制基因p53的研究越来越深入。本文综合近年来国内外的研究进展,就p53与肿瘤形成的关系及其在肿瘤治疗中的应用等作一综述。     

MicroRNA与肿瘤相关的信号转导通路

信号转导通路在细胞代谢、生长、增殖、应激、发育和凋亡等生命活动中具有极为重要的作用。干扰这些通路将可能影响细胞的正常发育, 甚至导致肿瘤。MicroRNA(miRNA)是近年来在真核生物中发现的、在转录后水平负调节基因表达的一类长度约22个核苷酸的非编码小RNA, 其靶基因数目众多, 生物学功能广泛。在多种肿瘤中发现了miRNA的异常表达, 提示后者与肿瘤发生有关, 可能机制为调控癌基因或肿瘤抑制基因的表达。此外亦发现miRNA的靶基因有许多作用于肿瘤相关的信号转导通路。miRNA在肿瘤发生过程中的重要调控功能预示其将成为人类癌症诊断和治疗方面的新星。     

MicroRNA 与肿瘤的相关研究进展

微小RNA(microRNAs,miRNA)是一类22个核苷酸左右的非编码调控RNA。可以通过切割mRNA或者是抑制翻译两种机制,在转录后水平发挥调控生物生长发育的重要作用。目前的研究已经发现microRNA参与调控发育、细胞分化、细胞凋亡等多种生理过程。目前已证实miRNA参与肿瘤发生和进展,miRNA表达谱是肿瘤诊断和预后的指标,miRNA突变、缺失或表达水平的异常与人类肿瘤密切相关,它发挥类似于癌基因或抑癌基因的作用,参与肿瘤细胞的增殖、分化和细胞凋亡过程。本文就miRNA在肿瘤发生发展以及诊断治疗方面的研究进展作一综述。     

Micro-RNA mediated regulation of proliferation,self-renewal and differentiation of mammalian stem cells

Metazoan growth and development is maintained by populations of undifferentiated cells, commonly known as stem cells. Stem cells possess several characteristic properties, including dividing through self-renewing divisions and generating progeny that differentiate to have specialized cell fates. Multiple signaling pathways have been identified which coordinate stem cell proliferation with maintenance and differentiation. Relatively recently, the small, non-protein coding microRNAs (miRNAs) have been identified to function as important regulators in stem cell development. Individual miRNAs are capable of directing the translational repression of many mRNAs targets, generating widespread changes in gene expression. In addition, dysfunction of miRNA expression is commonly associated with cancer development. Cancer stem cells, which are likely responsible for initiating and maintaining tumorigenesis, share many similarities with stem cells and some mechanisms of miRNA function may be in common between these two cell types.Key words: stem cell, miRNA, mammalian, neuroblast, pluripotency, cancer, ESC, self-renewal     

MicroRNA参与下的p53调控网络

p53作为肿瘤致病的关键因子人们已经进行了广泛的研究,microRNA参与肿瘤的发生也已经成为了不争的事实,但目前关于p53与miRNA的调控关系还不是很清楚。就p53与miRNA存在的可能调控模式及p53对miRNA功能与合成方面的影响进行了综述,并结合已有的研究绘制了可能的p53与miRNA调控模式图。     

Multifaceted p21 in carcinogenesis,stemness of tumor and tumor therapy

Cancer cells possess metabolic properties that are different from those of benign cells. p21, encoded by CDKN1A gene, also named p21^Cip1/WAF1, was first identified as a cyclin-dependent kinase regulator that suppresses cell cycle G1/S phase and retinoblastoma protein phosphorylation. CDKN1A (p21) acts as the downstream target gene of TP53 (p53), and its expression is induced by wild-type p53 and it is not associated with mutant p53. p21 has been characterized as a vital regulator that involves multiple cell functions, including G1/S cell cycle progression, cell growth, DNA damage, and cell stemness. In 1994, p21 was found as a tumor suppressor in brain, lung and colon cancer by targeting p53 and was associated with tumorigenesis and metastasis. Notably, p21 plays a significant role in tumor development through p53-dependent and p53-independent pathways. In addition, expression of p21 is closely related to the resting state or terminal differentiation of cells. p21 is also associated with cancer stem cells and acts as a biomarker for such cells. In cancer therapy, given the importance of p21 in regulating the G1/S and G2 check points, it is not surprising that p21 is implicated in response to many cancer treatments and p21 promotes the effect of oncolytic virotherapy.     

Micro-RNA mediated regulation of proliferation,self-renewal and differentiation of mammalian stem cells

Metazoan growth and development is maintained by populations of undifferentiated cells, commonly known as stem cells. Stem cells possess several characteristic properties, including dividing through self-renewing divisions and generating progeny that differentiate to have specialized cell fates. Multiple signaling pathways have been identified which coordinate stem cell proliferation with maintenance and differentiation. Relatively recently, the small, non-protein coding microRNAs (miRNAs) have been identified to function as important regulators in stem cell development. Individual miRNAs are capable of directing the translational repression of many mRNAs targets, generating widespread changes in gene expression. In addition, dysfunction of miRNA expression is commonly associated with cancer development. Cancer stem cells, which are likely responsible for initiating and maintaining tumorigenesis, share many similarities with stem cells and some mechanisms of miRNA function may be in common between these two cell types.