TP53, which encodes the tumour-suppressor protein p53, is the most frequently mutated gene across all cancer types. The presence of mutant p53 predisposes to cancer development, promotes the survival of cancer cells, and is associated with ineffective therapeutic responses and unfavourable prognoses. Despite these effects, no drug that abrogates the oncogenic functions of mutant p53 has yet been approved for the treatment of cancer. Current investigational therapeutic strategies are mostly aimed at restoring the wild-type activity of mutant p53, based on the assumption that all p53 mutants are functionally equal. Our increasing knowledge of mutant forms of p53, however, supports the antithetical hypothesis that not all p53 mutants have equivalent cellular effects; hence, a judicious approach to therapeutic targeting of mutant p53 is required. In this Review, we propose a categorization of the major classes of p53 mutants based on their functionality in tumour suppression and response to therapy. The emerging picture is that the mutations across TP53 form a 'rainbow of mutants', with varying degrees of functionality and different pathobiological consequences, necessitating the use of diverse therapeutic strategies to selectively target specific classes of mutation. The utility of this knowledge of TP53 mutations in developing selective therapeutic options, and in facilitating clinical decision-making is discussed.
Different c-Jun N-terminal kinases (JNKs) are activated by a plethora of signals and phosphorylate substrates such as c-Jun, which is required for efficient cell cycle progression. Although JNK1 and JNK2 were shown to differentially regulate fibroblast proliferation, the underlying mechanistic basis remains unclear. We found that Jnk2-/- fibroblasts exit G1 and enter S phase earlier than wild-type counterparts, while Jnk1-/- cells show the inverse phenotype. Moreover, Jnk2-/- erythroblasts also exhibit a proliferative advantage. JNK2 deficiency results in elevated c-Jun phosphorylation and stability, whereas the absence of JNK1 reduces c-Jun phosphorylation and stability. Re-expression of JNK2 in Jnk2-/- cells reverses the JNK2 null phenotype, whereas ectopic expression of JNK1 augments it. JNK2 is preferentially bound to c-Jun in unstimulated cells, thereby contributing to c-Jun degradation. In contrast, JNK1 becomes the major c-Jun interacting kinase after cell stimulation. These data provide mechanistic insights into the distinct roles of different JNK isoforms.
Mice lacking both c-Jun-NH(2)-terminal kinases (JNK1 and JNK2) were generated to define their roles in development. Jnk1/jnk2 double mutant fetuses die around embryonic day 11 (E11) and were found to display an open neural tube (exencephaly) at the hindbrain level with reduced apoptosis in the hindbrain neuroepithelium at E9.25. In contrast, a dramatic increase in cell death was observed one day later at E10.5 in both the hindbrain and forebrain regions. Moreover, about 25% of jnk1-/-jnk2+/- fetuses display exencephaly probably due to reduced levels of JNK proteins, whereas jnk1+/-jnk2-/- mice are viable. These results assign both pro- and anti-apoptotic functions for JNK1 and JNK2 in the development of the fetal brain.
JNK2 is essential for efficient activation of peripheral T cells but not B cells. Peripheral T-cell activation is probably required indirectly for induction of thymocyte apoptosis resulting from administration of anti-CD3 antibody in vivo. JNK2 functions in a cell-type-specific and stimulus-dependent manner, being required for apoptosis of immature thymocytes induced by anti-CD3 antibody but not for apoptosis induced by anti-Fas antibody, UVC or dexamethasone. JNK2 is not required for activation-induced cell death of mature T cells.
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