Common tumour p53 mutations in immortalized cells from Hupki mice heterozygous at codon 72.

Codon 72 of human p53 gene is polymorphic, encoding arginine or proline. Here we report construction of a human p53 knock-in (Hupki) mouse encoding the codon 72(pro) variant. The new strain was crossed with the original Hupki mice (codon 72(arg/arg)) to obtain primary embryonic fibroblasts polymorphic at codon 72 or homozygous for codon 72(pro). The fibroblasts, cultured under standard conditions, immortalized within 12 weeks and acquired p53 mutations similarly to Hupki codon 72(arg/arg) cells investigated previously. Sequencing of human p53 exons 4-9 in immortalized cultures revealed missense mutations found repeatedly in human tumours. In cell lines ensuing from benzo(a)pyrene-treated cultures the combined p53 mutation pattern from experiments with the 3 codon 72 genotypes showed a predominance of strand-biased G to T transversions (18 of 36 mutations), and mutations recurring at smokers' lung tumour hotspot codons 157 and 273, supporting involvement of tobacco carcinogens in shaping the mutation signature in lung cancers of smokers. Mutations in cell lines from unexposed cultures did not cluster at these codons and G to T transversions were uncommon (2 of 52 mutations) (Fisher's exact test P<0.0001). Most mutations (13/16) in cell lines derived from cells polymorphic at codon 72 were found on the proline allele, with loss of the arginine allele.

Further studies with a cell immortalization assay to investigate the mutation signature of aristolochic acid in human p53 sequences.

To test hypotheses on the origins of p53 mutations in human tumors, novel strategies are needed for generating mutation spectra experimentally. To this end we developed an assay employing Hupki (Human p53 knock-in) mouse embryonic fibroblasts (HUFs). Here we examine p53 mutations induced by aristolochic acid I (AAI)), the carcinogen probably responsible for Chinese herbal nephropathy. Six immortalized cultures (cell lines) from 18 HUF primary cultures exposed at passage 1 for 48 h to 50 microM AAI harbored p53 mutations in the human DNA binding domain sequence of the Hupki p53 tumor suppressor gene. The most frequently observed mutation was A to T transversion, corroborating our previous mutation study with AAI, and consistent with the presence of persistent AAI-adenine adducts found both in DNA of exposed patients and in DNA of AAI-exposed HUF cells. One of the mutations was identical in position (codon 139) and base change (A to T on the non-transcribed strand) to the single p53 mutation that has thus far been characterized in a urothelial tumor of a nephropathy patient with documented AAI exposure. Of the seven p53 mutations identified thus far in >60 HUF cell lines that immortalized spontaneously (no carcinogen treatment), none were A:T to T:A transversions. In addition, no A to T substitutions were identified among the previously reported set of 18 mutations in HUF cell lines derived from B(a)P treatment in which transversions at G:C base pairs predominated.