Mouse mutants reveal that putative protein interaction sites in the p53 proline-rich domain are dispensable for tumor suppression

The stability and activity of tumor suppressor p53 are tightly regulated and partially depend on the p53 proline-rich domain (PRD). We recently analyzed mice expressing p53 with a deletion of the PRD (p53(DeltaP)). p53(DeltaP), a weak transactivator hypersensitive to Mdm2-mediated degradation, is unable to suppress oncogene-induced tumors. This phenotype could result from the loss of two motifs: Pin1 sites proposed to influence p53 stabilization and PXXP motifs proposed to mediate protein interactions. We investigated the importance of these motifs by generating mice encoding point mutations in the PRD. p53(TTAA) contains mutations suppressing all putative Pin1 sites in the PRD, while p53(AXXA) lacks PXXP motifs but retains one intact Pin1 site. Both mutant proteins accumulated in response to DNA damage, although the accumulation of p53(TTAA) was partially impaired. Importantly, p53(TTAA) and p53(AXXA) are efficient transactivators and potent suppressors of oncogene-induced tumors. Thus, Pin1 sites in the PRD may modulate p53 stability but do not significantly affect function. In addition, PXXP motifs are not essential, but structure dictated by the presence of prolines, PXXXXP motifs that may mediate protein interactions, and/or the length of this region appears to be functionally significant. These results may explain why the sequence of the p53 PRD is so variable in evolution.     

Tight DNA binding and oligomerization are dispensable for the ability of p53 to transactivate target genes and suppress transformation.

The p53 tumor suppressor protein can bind tightly to specific sequence elements in the DNA and induce the transactivation of genes harboring such p53 binding sites. Various lines of evidence suggest that p53 binds to its target site as an oligomer. To test whether oligomerization is essential for the biological and biochemical activities of p53, we deleted a major part of the dimerization domain of mouse wild-type p53. The resultant protein, termed p53wt delta SS, was shown to be incapable of forming detectable homo-oligomers in vitro and is, therefore, likely to be predominantly if not exclusively monomeric. In agreement with the accepted model, p53wt delta SS indeed failed to exhibit measurable DNA binding in vitro. Surprisingly, though, it was still capable of suppressing oncogene-mediated transformation and of transactivating in vivo a target gene containing p53 binding sites. These findings indicate that dimerization-defective p53 is biologically active and may engage in productive sequence-specific DNA interactions in vivo. Furthermore, p53 dimerization probably leads to cooperative binding to specific DNA sequences.     

p21Waf1 is required for cellular senescence but not for cell cycle arrest induced by the HDAC inhibitor sodium butyrate

Cell senescence is characterized by senescent morphology and permanent loss of proliferative potential. HDAC inhibitors (HDACI) induce senescence and/or apoptosis in many types of tumor cells. Here, we studied the role of cyclin-kinase inhibitor p21^waf1(Cdkn1n gene) in cell cycle arrest, senescence markers (cell hypertrophy, SA-bGal staining and accumulation of gH2AX foci) in p21^Waf1+/+ versus p21^Waf1-/- mouse embryonic fibroblast cells transformed with E1A and cHa-Ras oncogenes (mERas). While short treatment with the HDACI sodium butyrate (NaB) induced a reversible G1 cell cycle arrest in both parental and p21^Waf1-/- cells, long-term treatment led to dramatic changes in p21^Waf1+/+ cells only: cell cycle arrest became irreversible and cells become hypertrophic, SA-bGal-positive and accumulated gH2AX foci associated with mTORC1 activation. The p21^Waf1+/+ cells lost their ability to migrate into the wound and through a porous membrane. Suppression of migration was accompanied by accumulation of vinculin-staining focal adhesions and Ser3-phosphorylation of cofilin, incapable for F-actin depolymerization. In contrast, the knockout of the p21^Waf1 abolished most of the features of NaB-induced senescence, including irreversibility of cell cycle arrest, hypertrophy, additional focal adhesions and block of migration, gH2AX foci accumulation and SA-bGal staining. Rapamycin, a specific inhibitor of mTORC1 kinase, decreased cellular hypertrophy, canceled coffilin phosphorylation and partially restored cell migration in p21^Waf1+/+ cells. Taken together, our data indicate a new role of p21^Waf1 in cell senescence, which may be connected not with execution of cell cycle arrest, but also with the development of mTOR-dependent markers of cellular senescence.     

Spatial compartmentalization of tumor necrosis factor (TNF) receptor 1-dependent signaling pathways in human airway smooth muscle cells. Lipid rafts are essential for TNF-alpha-mediated activation of RhoA but dispensable for the activation of the NF-kappaB and MAPK pathways

Tumor necrosis factor (TNF)-alpha-induced activation of RhoA, mediated by TNF receptor 1 (TNFR1), is a prerequisite step in a pathway that leads to increased 20-kDa light chain of myosin (MLC20) phosphorylation and airway smooth muscle contraction. In this study, we have investigated the proximal events in TNF-alpha-induced RhoA activation. TNFR1 is localized to both lipid raft and nonraft regions of the plasma membrane in primary human airway smooth muscle cells. TNF-alpha engagement of TNFR1 recruited the adaptor proteins TRADD, TRAF-2, and RIP into lipid rafts and activated RhoA, NF-kappaB, and MAPK pathways. Depletion of cholesterol from rafts with methyl-beta-cyclodextrin caused a redistribution of TNFR1 to nonraft plasma membrane and prevented ligand-induced RhoA activation. By contrast, TNF-alpha-induced activation of NF-kappaB and MAPKs was unaffected by methyl-beta-cyclodextrin indicating that, in airway smooth muscle cells, activation of these pathways occurred independently of lipid rafts. Targeted knockdown of caveolin-1 completely abrogated TNF-alpha-induced RhoA activation, identifying this raft-resident protein as a positive regulator of the activation process. The signaling adaptors TRADD and RIP were also found to be necessary for ligand-induced RhoA activation. Taken together, our results suggest that in airway smooth muscle cells, spatial compartmentalization of TNFR1 provides a mechanism for generating distinct signaling outcomes in response to ligand engagement and define a mechanistic role for lipid rafts and caveolin-1 in TNF-alpha-induced activation of RhoA.     

ω-3 and ω-6 fatty acids and PGE2 stimulate the growth of normal but not tumor mouse mammary epithelial cells: Evidence for alterations in the signaling pathways in tumor cells

The direct effect of ω-3 and ω-6 fatty acids on the proliferation of mouse mammary tumor cells (MTC) was examined in a serum-free cell culture system. While the EGF-induced proliferation of normal mammary epithelial cells was shown to be enhanced by ω-3 and ω-6 fatty acids and prostaglandins (PGs), a majority (75–80%) of primary mammary tumors were not stimulated by these agents. Compared to normal cells, some MTC cultures showed a higher susceptibility to inhibition by ω-3 fatty acids. The general lack of response of MTC cultures to PGE₂ and cyclic adenosine monophosphate (cAMP) suggests some alterations in the cAMP-mediated pathway. However, the PGE₂-induced cAMP levels and cAMP-dependent protein kinase (PKA) activities in the tumor cells were comparable to normal cells. We conclude that the proliferation of mammary tumor cells either follow a cAMP-PKA-independent pathway or have some alterations in the serine/threonine kinase mediated signaling pathway.