Perp is a p63-regulated gene essential for epithelial integrity

p63 is a master regulator of stratified epithelial development that is both necessary and sufficient for specifying this multifaceted program. We show here that Perp, a tetraspan membrane protein originally identified as an apoptosis-associated target of the p53 tumor suppressor, is the first direct target of p63 clearly involved in mediating this developmental program in vivo. During embryogenesis, Perp is expressed in an epithelial pattern, and its expression depends on p63. Perp-/- mice die postnatally, with dramatic blistering in stratified epithelia symptomatic of compromised adhesion. Perp localizes specifically to desmosomes, adhesion junctions important for tissue integrity, and numerous structural defects in desmosomes are observed in Perp-deficient skin, suggesting a role for Perp in promoting the stable assembly of desmosomal adhesive complexes. These findings demonstrate that Perp is a key effector in the p63 developmental program, playing an essential role in an adhesion subprogram central to epithelial integrity and homeostasis.     

High thermostability and lack of cooperative DNA binding distinguish the p63 core domain from the homologous tumor suppressor p53

The p53 protein is the major tumor suppressor in mammals. The discovery of the p53 homologs p63 and p73 defined a family of p53 members with distinct roles in tumor suppression, differentiation, and development. Here, we describe the biochemical characterization of the core DNA-binding domain of a human isoform of p63, p63-delta, and particularly novel features in comparison with p53. In contrast to p53, the free p63 core domain did not show specific binding to p53 DNA consensus sites. However, glutathione S-transferase-fused and thus dimerized p63 and p53 core domains had similar affinity and specificity for the p53 consensus sites p21, gadd45, cyclin G, and bax. Furthermore, the fold of p63 core was remarkably stable compared with p53 as judged by differential scanning calorimetry (T(m) = 61 degrees C versus 44 degrees C for p53) and equilibrium unfolding ([urea](50%) = 5.2 m versus 3.1 m for p53). A homology model of p63 core highlights differences at a segment near the H1 helix hypothetically involved in the formation of the dimerization interface in p53, which might reduce cooperativity of p63 core DNA binding compared with p53. The model also shows differences in the electrostatic and hydrophobic potentials of the domains relevant to folding stability.     

DeltaNp63 plays an anti-apoptotic role in ventral bladder development

The bladder, the largest smooth-muscle organ in the human body, is responsible for urine storage and micturition. P63, a homolog of the p53 tumor-suppressor gene, is essential for the development of all stratified epithelia, including the bladder urothelium. The N-terminal truncated isoform of p63, DeltaNp63, is known to have anti-apoptotic characteristics. We have established that DeltaNp63 is not only the predominant isoform expressed throughout the bladder, but is also preferentially expressed in the ventral bladder urothelium during early development. We observed a host of ventral defects in p63-/- embryos, including the absence of the abdominal and ventral bladder walls. This number of ventral defects is identical to bladder exstrophy, a congenital anomaly exhibited in human neonates. In the absence of p63, the ventral urothelium was neither committed nor differentiated, whereas the dorsal urothelium was both committed and differentiated. Furthermore, in p63-/- bladders, apoptosis in the ventral urothelium was significantly increased. This was accompanied by the upregulation of mitochondrial apoptotic mediators Bax and Apaf1, and concurrent upregulation of p53. Overexpression of DeltaNp63gamma and DeltaNp63beta in p63-/- bladder primary cell cultures resulted in a rescue, evidenced by significantly reduced expressions of Bax and Apaf1. We conclude that DeltaNp63 plays a crucial anti-apoptotic role in normal bladder development.     

Control of Keratinocyte Proliferation and Differentiation by p63

The p53 family member p63 has been implicated in both the development and maintenance of stratified epithelial tissues, including the epidermis. Increasing data support p63 function in the regenerative capacity of basal keratinocytes by maintaining cell proliferation. Recent studies further suggest this regulation relies on inhibition of p53 activity. In addition, p63 appears to exert separate control over epidermal differentiation, which may involve control of such key signaling molecules as IKKα and Notch. While studies over the past decade have greatly expanded our knowledge of p63 function, much remains to be understood regarding how p63 regulates epidermal homeostasis. Future efforts to identify and validate direct p63 target genes as well as to understand the expression and function of individual p63 isoforms will be important to further define how p63 functions in the control of keratinocyte proliferation and differentiation.     

Differential recognition of response elements determines target gene specificity for p53 and p63

p63 is a member of the p53 tumor suppressor gene family, which regulates downstream target gene expression by binding to sequence-specific response elements similar to those of p53. By using oligonucleotide expression microarray analysis and analyzing the promoters of p63-induced genes, we have identified novel p63-specific response elements (p63-REs) in the promoter regions of EVPL and SMARCD3. These p63-REs exhibit characteristic differences from the canonical p53-RE (RRRCWWGYYY) in both the core-binding element (CWWG) as well as the RRR and/or YYY stretches. Luciferase assays on mutagenized promoter constructs followed by electromobility shift analysis showed that p53 preferentially activates and binds to the RRRCATGYYY sequence, whereas p63 preferentially activates RRRCGTGYYY. Whereas EVPL protein is highly expressed in epithelial cells of the skin and pharynx in the p63+/+ mouse, it is undetectable in these tissues in the p63-/- mouse. Our results indicate that p63 can regulate expression of specific target genes such as those involved in skin, limb, and craniofacial development by preferentially activating distinct p63-specific response elements.     

p63基因的结构与功能

p63基因是肿瘤抑制基因p53家族成员之一,与p53基因表现出高度同源性.较之p53基因,p63基因更为复杂.p63的两个不同启动子和多种内含子剪接方式,导致p63基因编码产生多种亚型P63蛋白.这些P63亚型蛋白,在不同的组织不同的发育阶段发挥不同的生物学功能.本文就p63基因结构、p63在细胞周期和凋亡中的作用,以及在表皮发育中的功能等方面的研究进展作一概述.     

Early diversification and complex evolutionary history of the p53 tumor suppressor gene family

The p53 tumor suppressor plays the leading role in malignancy and in maintaining the genome's integrity and stability. p53 belongs to a gene family that in vertebrates includes two additional members, p63 and p73. Although similar in sequence, gene structure, and expression potential, the three p53 members differ in domain organization (in addition to the transactivation, DNA-binding, and tetramerization domains, p63 and p73 encode a sterile alpha motif, SAM, domain) and functional roles (with p63 and p73 assuming additional key roles in development). It is interesting to note that outside vertebrates, p53-like sequences have only been found as single genes, of either the p53 or the p63/p73 type (i.e., without or with a SAM domain, respectively). In this paper, we report that the diversification of this family is not restricted to the vertebrate lineage, as both a p53- and a p63/p73-type sequence are present in the unicellular choanoflagellate, Monosiga brevicollis. Furthermore, multiple independent duplication events involving p53-type sequences took place in several other animal lineages (cnidarians, flat worms, insects). These findings argue that selective factors other than those associated with the evolution of vertebrates are also relevant to the diversification of this family. Understanding the selective pressures associated with the multiple independent duplication events that took place in the p53 family and the roles of p53-like proteins outside vertebrates will provide further insight into the evolution of this very important family. In addition, the presence of both a p53 and a p63/73 copy in the unicellular M. brevicollis argues for its suitability as a model system for elucidating the functions of the p53 members and the mechanisms associated with their functional diversification.     

The p53 family: same response, different signals?

TP53, the gene that encodes p53, is a well-defined tumor suppressor gene that is frequently mutated in human cancers. Recently, two proteins homologous to p53, termed p73 and p63, were identified. Current data indicate that both p73 and p63, like p53, can induce cell-cycle arrest and apoptosis, suggesting that they might also be tumor suppressors. However, the physiological signals that can regulate p53, for example, DNA damage, have no effect on p73, as tested in several cell lines. Furthermore, the signaling pathways by which p73 (and possibly p63) induces cell-cycle arrest and apoptosis appear to be similar to those of p53, but also have important differences. Thus, the p53 family proteins are closely related but might have distinct physiological functions.