Microbial Regulation of p53 Tumor Suppressor

p53 tumor suppressor has been identified as a protein interacting with the large T antigen produced by simian vacuolating virus 40 (SV40). Subsequent research on p53 inhibition by SV40 and other tumor viruses has not only helped to gain a better understanding of viral biology, but also shaped our knowledge of human tumorigenesis. Recent studies have found, however, that inhibition of p53 is not strictly in the realm of viruses. Some bacterial pathogens also actively inhibit p53 protein and induce its degradation, resulting in alteration of cellular stress responses. This phenomenon was initially characterized in gastric epithelial cells infected with Helicobacter pylori, a bacterial pathogen that commonly infects the human stomach and is strongly linked to gastric cancer. Besides H. pylori, a number of other bacterial species were recently discovered to inhibit p53. These findings provide novel insights into host–bacteria interactions and tumorigenesis associated with bacterial infections.     

抑癌蛋白p53乙酰化修饰的调控网络

p53是细胞内最重要的抑癌蛋白质之一;细胞对p53分子功能的调控主要通过一系列翻译后修饰(PTMs)完成。其中,乙酰化修饰既可在总体水平调控p53的转录活性,又可位点特异性地调控p53依赖的转录选择性,进而精确控制p53在细胞周期阻滞、凋亡、衰老、自噬和代谢等关键生物学过程中的作用。本综述以p53乙酰化修饰研究的时间脉络为轴,首先总结了发生在p53各结构域内乙酰化修饰的建立机制,包括催化p53位点特异性乙酰化发生的乙酰基转移酶,以及各位点乙酰化修饰对p53分子功能调节的机制。其次,本综述总结了参与去除p53乙酰化修饰的关键去乙酰基酶家族,以及这些因子参与调控p53分子功能的生物学意义。同时,本文综述了能够特异性读取p53乙酰化修饰状态的识别蛋白质,以及这些识别蛋白质与p53互作,进而协同调控下游靶基因转录的分子调控网络。此外,本文概述了p53乙酰化修饰与其它类型翻译后修饰之间的“交谈”,以及这些修饰之间通过时空特异互作方式影响p53功能的分子机制。最后,本文基于p53乙酰化修饰,对肿瘤分子医学的研究前景进行讨论与展望。     

抑癌因子ARF的非p53调节通路

ARF蛋白是INK4a基因位点编码产物之一,是一种重要的肿瘤抑制因子。ARF可结合原癌蛋白Mdm2,稳定p53,将细胞周期阻断在G1期和G2/M转换期,或诱导细胞凋亡。有关ARF的p53依赖性作用已有较多报道。该文主要以ARF对E2F1、DP1、E2F1/DP1、NPM/B23和c-Myc等的调控为例,对ARF的非p53调节通路做一综述。     

Control of Tumor Suppressor p53 Function by Endoplasmic Reticulum Stress

Alterations in the homeostasis of the endoplasmic reticulum (ER) by various forms of stress can lead to the accumulation of unfolded proteins and protein aggregates that are detrimental to cell survival. Eukaryotic cells can adapt to ER stress by activating specific signalling pathways and mechanisms, whose primary purpose is to limit the accumulation of unfolded proteins in the ER. We recently reported a novel mechanism of cell adaptation to ER stress, which proceeds through the inhibition of the apoptotic function of the tumour suppressor p53 [Genes & Development 2004;18:261-277]. We found that ER stress increases the cytoplasmic localization and enhances the destabilization of the tumour suppressor. This process requires the phosphorylation of p53 at serine 315 and serine 376, which is mediated by the activation of glycogen synthase kinase-3beta (GSK-3?). ER stress also prevents p53 activation and p53-mediated apoptosis in response to DNA damage. These findings demonstrate that ER stress utilizes mechanisms that are distinct from other types of stress to modulate p53. In addition, they reveal that ER stress and nuclear DNA damage can induce inter-organellar cross-talk pathways targeting p53 with important implications for the treatment of tumours with dysfunctional ER.     

Paracrine Apoptotic Effect of p53 Mediated by Tumor Suppressor Par-4

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The Ubiquitin Ligase COP1 Promotes Glioma Cell Proliferation by Preferentially Downregulating Tumor Suppressor p53

Human glioma causes substantial morbidity and mortality worldwide. However, the molecular mechanisms underlying glioma progression are still largely unknown. COP1 (constitutively photomorphogenic 1), an E3 ubiquitin ligase, is important in cell survival, development, cell growth, and cancer biology by regulating different substrates. As is well known, both tumor suppressor p53 and oncogenic protein c-JUN could be ubiquitinated and degraded by ubiquitin ligase COP1, which may be the reason that COP1 serves as an oncogene or a tumor suppressor in different cancer types. Up to now, the possible role of COP1 in human glioma is still unclear. In the present study, we found that the expression of COP1 was upregulated in human glioma tissues. The role of COP1 in glioma cell proliferation was investigated using COP1 loss- and gain-of-function. The results showed that downregulation of COP1 by short hairpin RNA (shRNA) inhibited glioma cell proliferation, while overexpression of COP1 significantly promoted it. Furthermore, we demonstrated that COP1 only interacted with and regulated p53, but not c-JUN. Taken together, these results indicate that COP1 may play a role in promoting glioma cell proliferation by interacting with and downregulating tumor suppressor p53 rather than oncogenic protein c-JUN.     

抑癌基因的负转录调控

抑癌基因在正常细胞中适度表达,抑制细胞永生及转化,其转录下调见于某些肿瘤,而在衰老细胞中常见表达上调或活性增强。抑癌基因INK4a／ARF、p53和p21^Cipl的表达及其负调控与肿瘤及细胞衰老的关系十分密切。     

抑癌蛋白PTEN及PDZ蛋白对其的调节

pten基因是迄今为止发现的第1个具有双特异性磷酸酶活性的抑癌基因,该基因的编码产物PTEN蛋白,是具有蛋白与脂质磷酸酯酶活性的双特异性磷酸酯酶,作为1种重要的信号分子参与细胞增殖、分化、黏附、迁移、凋亡以及基因转录的调控. 最近,关于PTEN在信号转导中的作用以及细胞内PTEN的调节机制研究较多,尤其是PDZ蛋白对PTEN的调节作用. PTEN蛋白包括1个氨基端（N端）磷酸酯酶区域,1个与脂质结合的C2区域和1个含有PDZ结合序列的羧基端（C端）区域. PDZ结构域通过识别目标蛋白羧基端PDZ结合序列与目标蛋白相互作用,调控多种重要的细胞生理过程和信号传导途径.本文就抑癌基因pten编码产物PTEN蛋白的结构、PTEN的生物学功能和PDZ蛋白对PTEN调节的研究进展进行综述.     

肿瘤抑制因子p53功能及其抗病毒作用研究进展

肿瘤抑制因子p53 作为基因组的守护者,能通过细胞周期调控和促进细胞凋亡而阻止癌细胞及机体肿瘤的发生,p53还能参与DNA损伤修复、调节机体代谢及调节繁殖生育等功能。除此以外,近年来研究发现,p53能通过促进病毒感染的细胞凋亡而起到抗病毒作用以及p53受IFN的调控和p53作为转录调控因子还能直接转录激活IRF9、IRF5、ISG15和TLR3等抗病毒基因,从而确定了p53在抗病毒反应中起到重要作用。这表明p53可能参与先天性免疫、获得性免疫及炎症反应而起到抗病毒的作用。     

Posttranslational Modifications Affect the Interaction of S100 Proteins with Tumor Suppressor p53

Proteins of the S100 family bind to the intrinsically disordered transactivation domain (TAD; residues 1-57) and C-terminus (residues 293-393) of the tumor suppressor p53. Both regions provide sites that are subject to posttranslational modifications, such as phosphorylation and acetylation, that can alter the affinity for interacting proteins such as p300 and MDM2. Here, we found that S100A1, S100A2, S100A4, S100A6, and S100B bound to two subdomains of the TAD (TAD1 and TAD2). Both subdomains were mandatory for high-affinity binding to S100 proteins. Phosphorylation of Ser and Thr residues increased the affinity for the p53 TAD. Conversely, acetylation and phosphorylation of the C-terminus of p53 decreased the affinity for S100A2 and S100B. In contrast, we found that nitrosylation of S100B caused a minor increase in binding to the p53 C-terminus, whereas binding to the TAD remained unaffected. As activation of p53 is usually accompanied by phosphorylation and acetylation at several sites, our results suggest that a shift in binding from the C-terminus in favor of the N-terminus occurs upon the modification of p53. We propose that binding to the p53 TAD might be involved in the stimulation of p53 activity by S100 proteins.