Ty at these loci additionally makes them useful for loss-ofheterozygosity (LOH) analysis in both AZD-8835 manufacturer cancers and preneoplastic fields [56]. Polymerase errors made when copying across microsatellites are predominantly corrected by the cell’s mismatch repair (MMR) system. Hereditary nonpolyposis coli, also known as Lynch syndrome, is an inherited deficiency in MMR associated with a >80 lifetime risk of colorectal and other cancers [57]. Somatic loss of MMR activity is also observed in 10?5 of sporadic colorectal cancers in patients without hereditary disorders of DNA repair [58]. On a biochemical level, deficiency of MMR elevates microsatellite slippage rates between 100 and 1000-fold [59], making MMR- tumors one of the most definitive examples of a cancer-associated mutator phenotype [8]. The enormous number of passenger mutations arising in MMR- cancers annotates their genomes with an especially thorough record of the past. Tsao and colleagues capitalized on this unique phenomenon by using slipped microsatellite loci as a molecular clock to study the mitotic age of MMR- tumors [60]. A similar concept was recently used to phylogenetically map the cell lineages of tumor metastases in an MMR-compromised mouse [61]. Even with intact MMR, microsatellites exhibit mitotic frameshift rates several orders of magnitude above that of non-repetitive sequences [62,63]. Length altering microsatellite mutations have been identified in a variety of non-MMR deficient cancers and adjacent tissues [64]. In Barrett’s Esophagus they have been observed in fields that temporally precede adenocarcinoma [65]. The detection of low-frequency microsatellite slippage in cancers or preneoplastic fields has often been reported as “microsatellite instability” [66?68]. While this wording may not be precisely correct, given that the detection of a mutation is not absolute evidence that the rate of mutation is necessarily elevated [69], the ubiquity of slipped alleles speaks to their potential usefulness as clonal markers. A concern, however, is that many studies which have used microsatellite slippage to identify expansions have only been able to detect a fraction of known clonal entities defined by other types of mutations. This is not wholly unexpected given that mutational marking is stochastic: the probability of being able to detect a clonal population is a function of the number of sites screened, the per-cell-division rate of mutation at these sites and the number of divisions order HS-173 undergone by a cell lineage prior to the last expansion bottleneck. Improved sensitivity should thus always be attainable by assessing a larger number of markers sites and those of greater mutability. The rate of mitotic microsatellite slippage depends on the repeat type, length and other less predictable factors involving adjacent sequence context, transcriptional status and chromatin structure [63,70]. Values for different loci are quite variable, ranging from less than 10-6 to nearly 10-4 in normal human cells in culture [62,63]. Monomeric repeats of polydeoxyguanosine [poly(dG) tracts] are particularly unstable, with long tracts on the upper end of this range. Several years ago our group developed a technique for constructing fate maps of mouse development by phylogenetically analyzing the mutational relationships of hundreds of poly(dG) tracts among many individual cells [71,72]. We recently adapted ourNIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author ManuscriptSemin Cancer.Ty at these loci additionally makes them useful for loss-ofheterozygosity (LOH) analysis in both cancers and preneoplastic fields [56]. Polymerase errors made when copying across microsatellites are predominantly corrected by the cell’s mismatch repair (MMR) system. Hereditary nonpolyposis coli, also known as Lynch syndrome, is an inherited deficiency in MMR associated with a >80 lifetime risk of colorectal and other cancers [57]. Somatic loss of MMR activity is also observed in 10?5 of sporadic colorectal cancers in patients without hereditary disorders of DNA repair [58]. On a biochemical level, deficiency of MMR elevates microsatellite slippage rates between 100 and 1000-fold [59], making MMR- tumors one of the most definitive examples of a cancer-associated mutator phenotype [8]. The enormous number of passenger mutations arising in MMR- cancers annotates their genomes with an especially thorough record of the past. Tsao and colleagues capitalized on this unique phenomenon by using slipped microsatellite loci as a molecular clock to study the mitotic age of MMR- tumors [60]. A similar concept was recently used to phylogenetically map the cell lineages of tumor metastases in an MMR-compromised mouse [61]. Even with intact MMR, microsatellites exhibit mitotic frameshift rates several orders of magnitude above that of non-repetitive sequences [62,63]. Length altering microsatellite mutations have been identified in a variety of non-MMR deficient cancers and adjacent tissues [64]. In Barrett’s Esophagus they have been observed in fields that temporally precede adenocarcinoma [65]. The detection of low-frequency microsatellite slippage in cancers or preneoplastic fields has often been reported as “microsatellite instability” [66?68]. While this wording may not be precisely correct, given that the detection of a mutation is not absolute evidence that the rate of mutation is necessarily elevated [69], the ubiquity of slipped alleles speaks to their potential usefulness as clonal markers. A concern, however, is that many studies which have used microsatellite slippage to identify expansions have only been able to detect a fraction of known clonal entities defined by other types of mutations. This is not wholly unexpected given that mutational marking is stochastic: the probability of being able to detect a clonal population is a function of the number of sites screened, the per-cell-division rate of mutation at these sites and the number of divisions undergone by a cell lineage prior to the last expansion bottleneck. Improved sensitivity should thus always be attainable by assessing a larger number of markers sites and those of greater mutability. The rate of mitotic microsatellite slippage depends on the repeat type, length and other less predictable factors involving adjacent sequence context, transcriptional status and chromatin structure [63,70]. Values for different loci are quite variable, ranging from less than 10-6 to nearly 10-4 in normal human cells in culture [62,63]. Monomeric repeats of polydeoxyguanosine [poly(dG) tracts] are particularly unstable, with long tracts on the upper end of this range. Several years ago our group developed a technique for constructing fate maps of mouse development by phylogenetically analyzing the mutational relationships of hundreds of poly(dG) tracts among many individual cells [71,72]. We recently adapted ourNIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author ManuscriptSemin Cancer.