In 1 case, the same mutation (R248Q) was detected in both cancer and stromal tissues, and p53 protein expression was detected in both the cancer cells and the cancer stroma.
To evaluate the role of aggregation in cancer, we asked whether wild-type (WT) p53 and the hot-spot mutant R248Q could aggregate as amyloids under physiological conditions and whether the mutant could seed aggregation of the wild-type form.
The results show that: (i) the p53 mutants H115N and S116M are thermally more stable than wild-type p53; (ii) H115N but not S116M is capable of rescuing the DNA binding of one of the most frequent p53 mutants in cancer, R248Q, as shown by binding of R248Q/H115N to gadd45 (the promoter of a gene involved in cell-cycle arrest); (iii) the double mutant R248Q/H115N is more stable than wild-type p53; (iv) the effect of H115N as a second-site suppressor to restore DNA-binding activity is specific to R248Q, but not to R248W; (v) molecular-dynamics simulations indicate that R248Q/H115N has a conformation similar to wild-type p53, which is distinct from that of R248Q.
Our results show: (1) wild-type p53 stimulates the transcription of reporter genes with p53CON and RGC in their 5' region while most p53 mutants occurring in human cancers have lost this activity; (2) the R273H mutant retains transcriptional activity for the p53CON sequence but not RGC; (3) some mutants are temperature-sensitive for the transcriptional activity with the p53CON but not the RGC sequence; (4) p53 mutants vary in their ability to inhibit wild-type p53 transactivation but there is no difference between p53CON and RGC sequences; (5) lung cancer cells with endogenous mutant p53 proteins (M246I in H23 cells and R248L in H322 cells) retain transcriptional activity for the p53CON but not the RGC sequence.