p21 (WAF1) is component of a positive feedback loop that maintains the p53 transcriptional program

The regulation of p53 activity through the MDM2 negative feedback loop is driven in part by an extrinsic ATM-pulse that maintains p53 oscillations in response to DNA damage. We report here that the p53 pathway has evolved an intrinsic positive feedback loop that is maintained by the p53-inducible gene product p21WAF1. p21-null cancer cells have defects in p53 protein turnover, reductions in MDM2-mediated degradation of p53, and reduced DNA damage-induced ubiquitination of p53. TLR3-IRF1 or ATM-dependent signaling to p53 is defective in p21-null cells and complementation of the p21 gene in p21-null cancer cells restores the p53 transcriptional response. The mechanism of p53 inactivity in p21-null cells is linked to a p53 protein equilibrium shift from chromatin into cytosolic fractions and complementation of the p21 gene into p21-null cells restores the nuclear localization of p53. A loss of p53 transcriptional function in murine B-cells heterozygous or homozygous null for p21 highlights a p21-gene dosage effect that maintains the full p53 transcriptional response. ATM inhibition results in nuclear exclusion of p53 highlighting a positive genetic interaction between ATM and p21. P21 protein oscillates in undamaged proliferating cells, and reductions of p21 protein using siRNA eliminate the DNA damage-induced p53 pulse. The p53 transcription program has evolved a negative feedback loop maintained by MDM2 that is counteracted by a positive feedback loop maintained by ATM-p21 the balance of which controls the specific activity of p53 as a transcription factor

Feline mammary carcinoma stem cells are tumorigenic, radioresistant, chemoresistant and defective in activation of the ATM/p53 DNA damage pathway

AbstractCancer stem cells were identified in a feline mammary carcinoma cell line by demonstrating expression of CD133 and utilising the tumour sphere assay. A population of cells was identified that had an invasive, mesenchymal phenotype, expressed markers of pluripotency and enhanced tumour formation in the NOD-SCID mouse and chick embryo models. This population of feline mammary carcinoma stem cells was resistant to chemotherapy and radiation, possibly due to aberrant activation of the ATM/p53 DNA damage pathway. Epithelial–mesenchymal transition was a feature of the invasive phenotype. These data demonstrate that cancer stem cells are a feature of mammary cancer in cats

DNA damage triggers DRB-resistant phosphorylation of human p53 at the CK2 site

The sequence-specific DNA binding activity of p53 is negatively regulated by a C-terminal domain whose phosphorylation in vitro can activate the latent DNA binding function of the protein. The DNA binding activity of p53 is a core component of its stress-activated transcription function, yet it is not yet clear whether phosphorylation within the C-terminal domain plays a role in the p53 damage response in vivo. As the casein kinase 2 (CK2) site at serine 392 is the C-terminal phosphorylation motif that exhibits the most pronounced conservation at the primary amino acid level, we have focused on determining whether the CK2 site is modified in vivo and whether radiation effects the extent of that phosphorylation. Using antibodies that can detect serine 392-phosphorylation of p53, we demonstrate that UV radiation can trigger extensive phosphorylation at the CK2 site. The CK2 inhibitor, 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB), can partially inhibit the UV-induced phosphorylation at serine 392, suggesting that CK2 is one of the major serine 392-kinases. However, a striking increase in UV-induced serine 392 phosphorylation and p53 transactivation function at higher levels of DRB suggests that a DRB-resistant/stress-activated pathway may target serine 392 in vivo. These data demonstrate that radiation-induced phosphorylation of p53 can occur in vivo at serine 392 and implicate a CK2-independent signal cascade that can function to modulate serine 392 phosphorylation in cells

Activation of p53 protein function in response to cellular irradiation

p53 protein is a key regulatory component of a stress-inducible cell-cycle checkpoint pathway in mammalian cells, which can promote either cell-growth arrest or apoptosis, depending on the type of cell and damaging agent utilized. Environmental insults that can activate the p53 pathway are quite distinct, and include ionizing and nonionizing radiation (1–5), antimetabolites which inhibit ribonucleotide biosynthesis (6), inhibitors of spindle formation (7), microtubule-affecting drugs (8), factors inducing differentiation (9), signaling pathways activated in transformed cells during anchorage-independent growth (10), heat shock (11), and hypoxia (12)

Dephosphorylation of p53 at Ser20 after cellular exposure to low levels of non-ionizing radiation

Induction of the transactivation function of p53 after cellular irradiation was studied under conditions in which upstream signaling events modulating p53 activation were uncoupled from those regulating stabilization. This investigation prompted the discovery of a novel radiation-responsive kinase pathway targeting Ser20 that results in the masking of the DO-1 epitope in undamaged cells. Unmasking of the DO-1 epitope via dephosphorylation occurs in response to low doses of non-ionizing radiation. Our data show that phosphorylation at Ser20 reduces binding of the mdm2 protein, suggesting that a function of the Ser20-kinase pathway may be to produce a stable pool of inactive p53 in undamaged cells which can be readily activated after cellular injury. Phospho-specific monoclonal antibodies were used to determine whether the Ser20 signaling pathway is coupled to the Ser15 and Ser392 radiation-responsive kinase pathways. These results demonstrated that: (1) dephosphorylation at Ser20 is co-ordinated with an increased steady-state phosphorylation at Ser392 after irradiation, without p53 protein stabilization, and (2) stabilization of p53 protein can occur without Ser15 phosphorylation at higher doses of radiation. These data show that the Ser20 and Ser392 phosphorylation sites are both targeted by an integrated network of signaling pathways which is acutely sensitive to radiation injury

Identification of a second Nutlin-3 responsive interaction site in the N-terminal domain of MDM2 using hydrogen/deuterium exchange mass spectrometry

10.1002/pmic.201300029Proteomics13162512-2525PROT