The coordinated interaction of multifunctional members of p53 family determines many key processes in multicellular organisms

First time p53 was found in the complex with viral large T-antigene in the cells transformed by small DNA virus SV40. The cloning of p53 cDNA was done in the beginning of eighties and soon after that the whole p53 gene was cloned. The p53 family is comprised of three genes: TP53,TP63 and TP73, each of which is expressed as a set of structurally and functionally different isoforms. All of them intensively interact with each other forming a united functional network of proteins. In this review we discuss evolution of the p53 family and significance of all its members in embryonic development, reproduction, regeneration, regulation of aging and life span, as well as in the body's defense against cancer. With special attention we review the role of less studied members of the p53 family: p63 and p73, in oncogenesis and tumor progression and show that different isoforms of these proteins might exert a contrary effect on these processes.     

p53家族及其通路相关蛋白调节母性生殖的新功能

p53是一种重要的抗癌基因,同时它也是机体感受环境压力并进行相应调节的关键基因之一。最近的研究发现东亚人群p53 Arg72Pro受到冬季温度自然选择,表明p53可能在生殖中发挥作用。同时,p53及其通路中的癌基因鼠双微体2(Murinedoubleminute2,Mdm2)、MdmX和Hausp(Herpesvirus-associated ubiquitin-specific protease)基因的单核苷酸多态性(Single nucleotide polymorphisms,SNP)与女性生殖疾病易感性相关。P53蛋白通过其DNA结合区(DNA-binding domain,DBD)调控白血病抑制因子(Leukaemiainhibitory factor,LIF)表达,从而影响胚胎植入过程,实现其在母性生殖中的作用。p53通路中Mdm2、MdmX和Hausp可以调控P53蛋白的表达水平和活性,同时还可以在胚胎植入时准确的调控p53的表达水平,促进胚胎植入;P53家族成员P63、P73具有P53相似的DBD区,但P63和P73是通过别的途径影响到母性生殖;在卵母细胞受到射线或者化学损伤后,P63能促进其凋亡,减少畸型的产生;P73能影响纺锤体复合物的组装,而纺锤体复合物缺失将导致胚泡质量低下,微管结合的动粒缺失和细胞非整倍性的增加。文章主要综述了p53家族、p53通路中的相关蛋白对母性生殖的影响,为提高IVF-ET成功指出了新方法,同时也为不明原因的不孕患者提供了新的诊断思路,将有助于制定合理的个性化治疗不孕方案。     

Coordinated interaction of multifunctional members of the p53 family determines many key processes in multicellular organisms

For the first time, p53 was found in complex with the viral large T-antigen in cells transformed with the small DNA virus SV40. p53 cDNA was cloned in the early 1980s, and the full-length p53 gene was cloned soon afterwards. The p53 family is comprised of three genes—TP53, TP63, and TP73—each of which is expressed as a set of structurally and functionally different isoforms. All of them intensely interact with each other, forming a united functional network of proteins. The review discusses the evolution of the p53 family and the significance of all its members in embryo development, reproduction, regeneration, regulation of aging and lifespan, and defense against cancer. Special attention is paid to the role of poorly studied members of the p53 family, p63 and p73, in carcinogenesis and tumor progression. Different isoforms of these proteins might exert opposite effects on these processes.     

p63/p73 in the control of cell cycle and cell death

The p53 family apparently derives from a common ancient ancestor that dates back over a billion years, whose function was protecting the germ line from DNA damage. p63 and p73 would maintain this function through evolution while acquiring novel roles in controlling proliferation and differentiation of various tissues. p53 on the other hand would appear in early vertebrates to protect somatic cells from DNA damage with similar mechanism used by its siblings to protect germ line cells. For the predominant role played by p53 mutations in cancer this was the first family member to be identified and soon became one of the most studied genes. Its siblings were identified almost 20 years later and interestingly enough their ancestral function as guardians of the germ-line was one of the last to be identified. In this review we shortly summarize the current knowledge on the structure and function of p63 and p73.     

Regulating the genome surveillance system: miRNAs and the p53 super family

The p53 gene super family consists of three members; TP53, TP63 and TP73, encoding proteins p53, p63 and p73. Whilst p63 appears to have an essential role in embryonic development with a less clear role in carcinogenesis, irregularities in p53 and p73 signalling are implicated in tumour formation. As such, p53 is a tumour suppressor which is mutated in over 50% cancers and p73 was recently formally classified as a tumour suppressor based on data showing p73 deficient mice generate spontaneous tumours similar to those observed in p53 null mice. Dysregulation of both p53 and p73 has been correlated with cancer progression in many cell types and although mutation of these genes is often observed, some form of p53/p73 deregulation likely occurs in all tumour cells. The discovery that complementary micro RNAs (miRNAs) are able to target both of these genes provides a potential new means of perturbing p53/p73 signalling networks in cancer cells. Here we summarise the current literature regarding the involvement of miRNAs in the modulation of p53 family proteins and cancer development and detail the use of in silico methods to reveal key miRNA targets.     

Structure and Stability Insights into Tumour Suppressor p53 Evolutionary Related Proteins

The p53 family of genes and their protein products, namely, p53, p63 and p73, have over one billion years of evolutionary history. Advances in computational biology and genomics are enabling studies of the complexities of the molecular evolution of p53 protein family to decipher the underpinnings of key biological conditions spanning from cancer through to various metabolic and developmental disorders and facilitate the design of personalised medicines. However, a complete understanding of the inherent nature of the thermodynamic and structural stability of the p53 protein family is still lacking. This is due, to a degree, to the lack of comprehensive structural information for a large number of homologous proteins and to an incomplete knowledge of the intrinsic factors responsible for their stability and how these might influence function. Here we investigate the thermal stability, secondary structure and folding properties of the DNA-binding domains (DBDs) of a range of proteins from the p53 family using biophysical methods. While the N- and the C-terminal domains of the p53 family show sequence diversity and are normally targets for post-translational modifications and alternative splicing, the central DBD is highly conserved. Together with data obtained from Molecular Dynamics simulations in solution and with structure based homology modelling, our results provide further insights into the molecular properties of evolutionary related p53 proteins. We identify some marked structural differences within the p53 family, which could account for the divergence in biological functions as well as the subtleties manifested in the oligomerization properties of this family.     

p63 and p73: roles in development and tumor formation

The tumor suppressor p53 is critically important in the cellular damage response and is the founding member of a family of proteins. All three genes regulate cell cycle and apoptosis after DNA damage. However, despite a remarkable structural and partly functional similarity among p53, p63, and p73, mouse knockout studies revealed an unexpected functional diversity among them. p63 and p73 knockouts exhibit severe developmental abnormalities but no increased cancer susceptibility, whereas this picture is reversed for p53 knockouts. Neither p63 nor p73 is the target of inactivating mutations in human cancers. Genomic organization is more complex in p63 and p73, largely the result of an alternative internal promoter generating NH2-terminally deleted dominant-negative proteins that engage in inhibitory circuits within the family. Deregulated dominant-negative p73 isoforms might play an active oncogenic role in some human cancers. Moreover, COOH-terminal extensions specific for p63 and p73 enable further unique protein-protein interactions with regulatory pathways involved in development, differentiation, proliferation, and damage response. Thus, p53 family proteins take on functions within a wide biological spectrum stretching from development (p63 and p73), DNA damage response via apoptosis and cell cycle arrest (p53, TAp63, and TAp73), chemosensitivity of tumors (p53 and TAp73), and immortalization and oncogenesis (DeltaNp73).