Increased mutation rate at the hprt locus accompanies microsatellite instability in colon cancer.

Hereditary Non-Polyposis Colon Cancer (HNPCC) tumors and some sporadic colon cancers acquire somatic changes in the length of microsatellite sequences. We hypothesized that this 'replication error' (RER) phenotype in these cancers reflects a more general defect which should result in hypermutability of expressed genes. To test this hypothesis mutations of hprt were studied in RER and non-RER tumor cell lines. Increased mutation rates of greater than 100-fold were found in RER compared to non-RER lines. Heterogeneity within the RER group suggests the likely existence of different classes of RER tumors. One non-RER cell line demonstrated a greater than 10-fold increase in mutation rate, suggesting that a novel mutator phenotype may exist in some non-RER tumors.

Diverse hypermutability of multiple expressed sequence motifs present in a cancer with microsatellite instability.

Colon cancer and an increasing number of other cancers have been found to exhibit instability of DNA microsatellite sequences. Such tumors have been designated as replication errors (RER) tumors. However, as microsatellites are only rarely found within coding regions of the genome, instability of these sequences cannot directly contribute to carcinogenesis. Recently, we have shown RER colon cancers also demonstrate a marked 100-fold increase in mutation rates measured within an expressed gene, hprt, suggesting the mutator phenotype in these tumors extends beyond microsatellite sequences. To determine whether the RER phenotype indeed destabilizes non-repetitive DNA sequences we have sequenced hprt gene mutations recovered from the RER colon cancer cell line RKO. Greater than 10% of hprt mutants proved to be a single 3 bp deletion located in a nonrepetitive ATTAT sequence motif. Additionally, 1-4 bp deletions or insertions were found to be randomly located throughout the hprt gene. Lastly, one third of hprt mutations proved to be transitions or transversions. The microsatellite instability demonstrated in RKO is thus a global mutator phenotype which destabilizes DNA sequences both inside and outside of repetitive sequence elements and which augments base substitutions as well as frameshifts. These findings extend the characteristics of mutations associated with RER tumors and suggest additional mechanisms by which mutator phenotypes may alter oncogenes and tumor suppressor genes.