Mouse p63 variants and chondrogenesis.

As a critical member of the p53 family of transcription factors, p63 has been implicated a role in development than in tumor formation, because p63 is seldom mutated in human cancers, while p63 null mice exhibit severe developmental abnormalities without increasing cancer susceptibility. Notably, besides the major epithelial and cardiac defect, p63 deficient mice show severe limb and craniofacial abnormalities. In addition, humans with p63 mutations also show severe limb and digit defects, suggesting a putative role of p63 in skeletal development. There are eight p63 variants which encode for the TAp63 and ΔNp63 isoforms by alternative promoters. How these isoforms function during skeletal development is currently largely unknown. Our recent transgenic studies suggest a role of TAP63α, but not ΔNP63α, during embryonic long bone development. However, the moderate skeletal phenotypes in the TAP63α transgenic mice suggest requirement of additional p63 isoform(s) for the limb defects in p63 null mice. Here, we report analysis of mouse p63 variants in MCT and ATDC5 cells, two cell models undergo hypertrophic differentiation and mimic the process of endochondral bone formation upon growth arrest or induction. We detected increased level of p63 variants in hypertrophic MCT cells by regular RT-PCR analysis. Further analysis by qRT-PCR, we detected significantly upregulated level of γ variant (p<0.05), but not α or ß variant (p>0.05), in hypertrophic MCT cells than in proliferative MCT cells. Moreover, we detected upregulated TAP63γ in ATDC5 cells undergoing hypertrophic differentiation. Our results suggest that TAp63γ plays a positive role during endochondral bone formation.

Upregulation of URI/RMP gene expression in cervical cancer by high-throughput tissue microarray analysis.

URI, or RMP, is a RNA polymerase II subunit RPB5-associated protein known to play essential roles in ubiquitination and transcription. Recently, we and others have shown that URI/RMP is also important for progression of hepatocellular carcinoma, ovarian, and prostate cancers. To identify the mechanistic basis of URI/RMP during multiple cellular processes, we investigated URI/RMP expression in a tissue microarray (TMA) containing multiple normal human tissues. The results showed that URI/RMP is ubiquitously but differentially expressed in these human tissues which partially explains its multiple cellular functions. To elucidate the role of URI/RMP during oncogenesis of multiple malignancies, especially the tumors of reproductive system, we analyzed URI/RMP expression in a TMA containing multiple reproductive system tumors. We did not observe significant difference of URI/RMP expression between cancerous and adjacent tissues of the prostate, breast, ovarian, and endometrial cancers. However, increased URI/RMP expression was observed in two of the three cases of cervical SCC (squamous cell carcinoma) cells compared to their adjacent epithelial cells. Moreover, we detected significantly upregulated URI/RMP expression not only in cervical cancers but also in pre-cancerous CINs (cervical intra-epithelial neoplasias) in a TMA that covers the whole spectrum of normal cervix, CINs, and cervical cancers. No difference of URI/RMP expression was observed between CINs and cervical cancers. Given the high risk of CINs (especially CIN3) turning into cervical cancer if left untreated, the increased URI/RMP expression in CINs as well as in cervical cancers suggest a clinical relevance of URI/RMP upon cervical cancer tumorigenesis and worth further investigation.