We have studied the molecular mechanisms of spontaneous mutations in mouse cells carrying a selectable bacterial gene. The mouse cells carry the Escherichia coli xanthine (guanine) phosphoribosyltransferase (gpt) gene in a retroviral shuttle vector integrated into chromosomal DNA in a proviral form. Cells with spontaneous mutations in the gpt gene were selected as resistant to 6-thioguanine and then were fused with COS cells for recovery of the mutant genes. Out of a total of 77 independent 6-thioguanine-resistant cell lines isolated in this study, vector sequences could be rescued from 43 of the mutant lines, and the base sequences were determined for the gpt genes in all 43 of these lines. There was a variety of mutational events among the mutant gpt genes sequenced. The most frequent mutational event was a deletion (in 29 of the 43 mutant genes), and the next most frequent event was a base substitution mutation (in 11 of the 43 mutant genes). Among the deletion mutants, the great majority represent deletions of less than 10 base pairs. In fact, 19 of the 29 deletion mutants had deletions of 3 base pairs, and among the mutants with 3-base-pair deletions, there was a very strong deletion hot spot appearing in 16 independent mutants. All 19 of the 3-base-pair deletions resulted in the "in frame" loss of an aspartic acid codon. Among the base substitution mutations, transitions and transversions occurred with approximately equal frequency. Our results raise the possibility that small deletions represent the predominant mechanisms by which spontaneous mutations occur in mammalian cells.