The p53 C terminus controls site-specific DNA binding and promotes structural changes within the central DNA binding domain.

DNA binding by numerous transcription factors including the p53 tumor suppressor protein constitutes a vital early step in transcriptional activation. While the role of the central core DNA binding domain (DBD) of p53 in site-specific DNA binding has been established, the contribution of the sequence-independent C-terminal domain (CTD) is still not well understood. We investigated the DNA-binding properties of a series of p53 CTD variants using a combination of in vitro biochemical analyses and in vivo binding experiments. Our results provide several unanticipated and interconnected findings. First, the CTD enables DNA binding in a sequence-dependent manner that is drastically altered by either its modification or deletion. Second, dependence on the CTD correlates with the extent to which the p53 binding site deviates from the canonical consensus sequence. Third, the CTD enables stable formation of p53-DNA complexes to divergent binding sites via DNA-induced conformational changes within the DBD itself.

p53 binding to nucleosomes within the p21 promoter in vivo leads to nucleosome loss and transcriptional activation.

It is well established that p53 contacts DNA in a sequence-dependent manner in order to transactivate its myriad target genes. Yet little is known about how p53 interacts with its binding site/response element (RE) within such genes in vivo in the context of nucleosomal DNA. In this study we demonstrate that both distal (5') and proximal (3') p53 REs within the promoter of the p21 gene in unstressed HCT116 colon carcinoma cells are localized within a region of relatively high nucleosome occupancy. In the absence of cellular stress, p53 is prebound to both p21 REs within nucleosomal DNA in these cells. Treatment of cells with the DNA-damaging drug doxorubicin or the p53 stabilizing agent Nutlin-3, however, is accompanied by p53-dependent subsequent loss of nucleosomes associated with such p53 REs. We show that in vitro p53 can bind to mononucleosomal DNA containing the distal p21 RE, provided the binding site is not close to the diad center of the nucleosome. In line with this, our data indicate that the p53 distal RE within the p21 gene is located close to the end of the nucleosome. Thus, low- and high-resolution mapping of nucleosome boundaries around p53 REs within the p21 promoter have provided insight into the mechanism of p53 binding to its sites in cells and the consequent changes in nucleosome occupancy at such sites.