Substitutions that compromise the ionizing radiation-induced association of p53 with 14-3-3 proteins also compromise the ability of p53 to induce cell cycle arrest.

Ionizing radiation (IR) induces an increase in the levels and activity of the p53 tumor suppressor protein. The increased activity is attributed to IR-induced posttranslational modifications, some of which regulate the interaction of p53 with other proteins. One of these modifications is dephosphorylation of Ser(376), which leads to association of p53 with 14-3-3 proteins. To establish the significance of this interaction, we examined the function of mutant p53 proteins that do not interact with 14-3-3 proteins in vivo. These p53 mutants retained sequence-specific DNA binding activity. However, their ability to activate transcription of the endogenous p21/waf1/cip1 gene and to induce G(1) arrest was compromised, suggesting that the dephosphorylation of Ser(376) and the association of p53 with 14-3-3 proteins contribute to the activation of p53 in response to IR.

Phosphorylation of Ser-20 mediates stabilization of human p53 in response to DNA damage.

Stabilization of p53 in response to DNA damage is caused by its dissociation from Mdm2, a protein that targets p53 for degradation in the proteasome. Dissociation of p53 from Mdm2 could be caused by DNA damage-induced p53 posttranslational modifications. The ATM and ATR kinases, whose activation in response to ionizing radiation (IR) and UV light, respectively, is required for p53 stabilization, directly phosphorylate p53 on Ser-15. However, phosphorylation of Ser-15 is critical for the apoptotic activity of p53 and not for p53 stabilization. Thus, whether any p53 modifications, and which, underlie disruption of the p53-Mdm2 complex after DNA damage remains to be determined. We analyzed the IR- and UV light-induced stabilization of p53 proteins with substitutions of Ser known to be posttranslationally modified after DNA damage. Substitution of Ser-20 was sufficient to abrogate p53 stabilization in response to both IR and UV light. Furthermore, both IR and UV light induced phosphorylation of p53 on Ser-20, which involved the majority of nuclear p53 protein and weakened the interaction of p53 with Mdm2 in vitro. ATM and ATR cannot phosphorylate p53 on Ser-20. We therefore propose that ATM and ATR activate an, as yet unidentified, kinase that stabilizes p53 by phosphorylating it on Ser-20.

Change in oligomerization specificity of the p53 tetramerization domain by hydrophobic amino acid substitutions.

The tumor suppressor function of the wild-type p53 protein is transdominantly inhibited by tumor-derived mutant p53 proteins. Such transdominant inhibition limits the prospects for gene therapy approaches that aim to introduce wild-type p53 into cancer cells. The molecular mechanism for transdominant inhibition involves sequestration of wild-type p53 subunits into inactive wild-type/mutant hetero-tetramers. Thus, p53 proteins, whose oligomerization specificity is altered so they cannot interact with tumor-derived mutant p53, would escape transdominant inhibition. Aided by the known three-dimensional structure of the p53 tetramerization domain and by trial and error we designed a novel domain with seven amino acid substitutions in the hydrophobic core. A full-length p53 protein bearing this novel domain formed homo-tetramers and had tumor suppressor function, but did not hetero-oligomerize with tumor-derived mutant p53 and resisted transdominant inhibition. Thus, hydrophobic core residues influence the oligomerization specificity of the p53 tetramerization domain.

ATM-dependent activation of p53 involves dephosphorylation and association with 14-3-3 proteins.

The p53 tumour-suppressor protein is a sequence-specific DNA-binding transcription factor that induces cell cycle arrest or apoptosis in response to genotoxic stress. Activation of p53 by DNA-damaging agents is critical for eliminating cells with damaged genomic DNA and underlies the apoptotic response of human cancers treated with ionizing radiation (IR) and radiomimetic drugs. The molecular mechanisms by which DNA damage activates p53 have not been elucidated. Both the levels of p53 protein and its affinity for specific DNA sequences increase in response to genotoxic stress. In vitro, the affinity of p53 for DNA is regulated by its carboxy-terminus. We therefore examined whether this region of p53 is targeted by DNA-damage signalling pathways in vivo. In nonirradiated cells, serines 376 and 378 of p53 were phosphorylated. IR led to dephosphorylation of Ser376, creating a consensus binding site for 14-3-3 proteins and leading to association of p53 with 14-3-3. In turn, this increased the affinity of p53 for sequence-specific DNA. Consistent with the lack of p53 activation by IR in ataxia telangiectasia (AT; refs 14,15), neither Ser376 dephosphorylation, nor the interaction of p53 with 14-3-3 proteins occurred in AT cells.

Hydrophobic side-chain size is a determinant of the three-dimensional structure of the p53 oligomerization domain.

The p53 tumor suppressor oligomerization domain, a dimer of two primary dimers, is an independently folding domain whose subunits consist of a beta-strand, a tight turn and an alpha-helix. To evaluate the effect of hydrophobic side-chains on three-dimensional structure, we substituted residues Phe341 and Leu344 in the alpha-helix with other hydrophobic amino acids. Substitutions that resulted in residue 341 having a smaller side-chain than residue 344 switched the stoichiometry of the domain from tetrameric to dimeric. The three-dimensional structure of one such dimer was determined by multidimensional NMR spectroscopy. When compared with the primary dimer of the wild-type p53 oligomerization domain, the mutant dimer showed a switch in alpha-helical packing from anti-parallel to parallel and rotation of the alpha-helices relative to the beta-strands. Hydrophobic side-chain size is therefore an important determinant of a protein fold.

CREB-binding protein and p300/CBP-associated factor are transcriptional coactivators of the p53 tumor suppressor protein.

The structurally related transcriptional coactivators p300 and CBP possess histone acetyltransferase activity and associate with P/CAF, which is also a histone acetyltransferase. CBP and p300 have properties of tumor suppressor proteins; their interaction with P/CAF is disrupted by the adenoviral E1A oncoprotein, and the genes encoding CBP and p300 are mutated in human cancer. We observed a physical interaction between the transactivation domain of the p53 tumor suppressor protein and CBP. Furthermore, CBP and P/CAF enhanced the ability of p53 to activate expression of the endogenous p21(cip1/waf1) gene, whereas E1A and dominant negative CBP mutants suppressed p53-dependent p21(cip1/waf1) expression. These studies link two tumor suppressor families and provide a framework for understanding the molecular mechanism by which p53 activates transcription.

Structural change in alpha-chymotrypsin induced by complexation with alpha 1-antichymotrypsin as seen by enhanced sensitivity to proteolysis.

Both human neutrophil elastase (HNE) and free chymotrypsin (Chtr) proteolyze Chtr within the complex that Chtr forms with antichymotrypsin (ACT). As free Chtr is stable both to self-digestion and to digestion by HNE, these results are indicative of a stability and/or conformational change in Chtr that accompanies complex formation. As determined by both N-terminal sequence analysis and matrix-assisted laser desorption ionization mass spectroscopy (MALDI-MS), the major initial sites of HNE cleavage of complexed Chtr are between gamma-chain residues A158/S159 and V188/S189. Significantly, this latter site is at the base of the S1 site that recognizes the P1 position of the serpin. A slower cleavage in the beta-chain between T139/G140 is also found. In addition, rACT is cleaved between residues V22/D23. The gamma-chain of complexed Chtr is also cleaved by free Chtr, but at different sites: L162/L163 and W172/G173. beta-Chain cleavages were also found between residues Q81/K82 and F114/S115. Cleavages similar to those described above were also found when Chtr was complexed with the L358F-rACT variant, but not for Chtr complexed with either of the smaller inhibitors bovine pancreatic trypsin inhibitor or turkey ovomucoid third domain, nor for the covalent adduct of Chtr with N-p-tosylphenylalanyl chloromethyl ketone. We conclude that the structural change in Chtr making it a proteinase substrate is coupled with the large conformational change in ACT following complex formation. Complexed Chtr is much less reactive toward proteolytic digestion in the presence of high salt than in its absence, in accord with the high-salt induced release of active enzyme from the Chtr.rACT complex and the suggestion that electrostatic interactions mediate the coupling of structural change between rACT and Chtr within the Chtr.rACT complex. Potential physiological consequences of this work are explored.