The p53-family member, p73, plays a key role in the development of the central nervous system (CNS), in senescence, and in tumor formation. The role of p73 in neuronal differentiation is complex and i Show more
The p53-family member, p73, plays a key role in the development of the central nervous system (CNS), in senescence, and in tumor formation. The role of p73 in neuronal differentiation is complex and involves several downstream pathways. Indeed, in the last few years, we have learnt that TAp73 directly or indirectly regulates several genes involved in neural biology. In particular, TAp73 is involved in the maintenance of neural stem/progenitor cell self-renewal and differentiation throughout the regulation of SOX-2, Hey-2, TRIM32 and Notch. In addition, TAp73 is also implicated in the regulation of the differentiation and function of postmitotic neurons by regulating the expression of p75NTR and GLS2 (glutamine metabolism). Further still, the regulation of miR-34a by TAp73 indicates that microRNAs can also participate in this multifunctional role of p73 in adult brain physiology. However, contradictory results still exist in the relationship between p73 and brain disorders, and this remains an important area for further investigation. Show less
In the presence of a Wnt signal beta-catenin is spared from proteasomal degradation through a complex mechanism involving GSK3beta, resulting in the transcription of Wnt target genes. In this study we Show more
In the presence of a Wnt signal beta-catenin is spared from proteasomal degradation through a complex mechanism involving GSK3beta, resulting in the transcription of Wnt target genes. In this study we have explored whether GSK3alpha, a related isoform, can also regulate nuclear beta-catenin levels and whether this and the tau-directed kinase activity of GSK3alpha are modulated by Wnt. GSK3alpha or GSK3beta and their substrates, beta-catenin and tau, were transiently expressed in mammalian cells. Immunoblotting revealed that GSK3alpha reduces nuclear levels of beta-catenin, whilst reporter gene assays demonstrated that GSK3alpha inhibits beta-catenin-directed Tcf/Lef-dependent transcription. Moreover, activation of the Wnt pathway was found to attenuate both the beta-catenin- and the tau-directed kinase activities of GSK3alpha and GSK3beta. By immunoprecipitation we also found that axin-1, the beta-catenin destruction complex scaffold protein, binds GSK3alpha. In the light of these findings GSK3alpha warrants further investigation regarding its involvement in Wnt signalling and tauopathies such as Alzheimer's disease. Show less