Single nucleotide instability without microsatellite instability in rat mammary carcinomas

Mutation frequencies (MnFs) of the lad transgene and mutation rates (MRs) of the endogenous hprt gene were analyzed in two mammary carcinoma cell lines that me established from mammary carcinomas that had been induced by 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP) in female lacI-transgenic rats. Using the lad transgene, corrected MnF, which is the number of independent lad mutations that occurred while 10(2) cells expanded into 10(7) cells and which reflect the dynamic increase of point mutations, was measured. The corrected MnFs in the two mammary carcinoma cell lines (59 x 10(-6) and 72 x 10(-6) mutations) were significantly higher than that in the primary culture of normal mammary epithelium (4.7 x 10(-6)). MRs of the hprt gene in the two mammary carcinoma cell lines (8.2 x 10(-7) and 11 x 10(-7) mutations/hprt/cell division) were also higher than the same control (1.4 x 10(-7)). A:T to C:G transversion was observed at significantly higher frequencies in the two cell lines (6 of 24 and 6 of 25 for lad; 10 of 67 and 19 of 92 for hprt) than in the control (0 of 6 for lad; 0 of 4 for hprt). Taking advantage of the lad transgene, high frequencies of A:T to C:G transversion (6 of 38 and 8 of 33, respectively) was also confirmed in the primary carcinomas of the two cell lines, which indicated the presence of a common abnormality in the cell lines and in the primary carcinomas. Both the established cell lines and their primary carcinomas were negative for microsatellite instability, which is known to be caused mainly by mismatch repair insufficiency and to increase point mutations, and for p53 mutations. These findings showed that the two cell lines, and possibly their primary carcinomas, had increases in the MRs of point mutations attributable to a mechanism(s) different from mismatch repair insufficiency, and we would suggest that such a state be designated as single nucleotide instability (SNI).