Microsatellite alterations within genomic DNA frameshift as a result of defective DNA mismatch repair(MMR). About 15% of sporadic colorectal cancers(CRCs) manifest hypermethylation of the DNA MMR gene MLH1, resulting ...Microsatellite alterations within genomic DNA frameshift as a result of defective DNA mismatch repair(MMR). About 15% of sporadic colorectal cancers(CRCs) manifest hypermethylation of the DNA MMR gene MLH1, resulting in mono-and di-nucleotide frameshifts to classify it as microsatellite instability-high(MSI-H) and hypermutated, and due to frameshifts at coding microsatellites generating neo-antigens, produce a robust protective immune response that can be enhanced with immune checkpoint blockade. More commonly, approximately 50% of sporadic nonMSI-H CRCs demonstrate frameshifts at di-and tetra-nucleotide microsatellites to classify it as MSIlow/elevated microsatellite alterations at selected tetranucleotide repeats(EMAST) as a result of functional somatic inactivation of the DNA MMR protein MSH3 via a nuclear-to-cytosolic displacement. The trigger for MSH3 displacement appears to be inflammation and/or oxidative stress, and unlike MSI-H CRC patients, patients with MSI-L/EMAST CRCs show poor prognosis. These inflammatory-associated microsatellite alterations are a consequence of the local tumor microenvironment, and in theory, if the microenvironment is manipulated to lower inflammation, the microsatellite alterations and MSH3 dysfunction should be corrected. Here we describe the mechanisms and significance of inflammatory-associated microsatellite alterations, and propose three areas to deeply explore the consequences and prevention of inflammation's effect upon the DNA MMR system.展开更多
基金Supported by United States Public Health Service,Nos.DK067287,CA162147 and CA206010the A.Alfred Taubman Medical Research Institute of the University of Michigan
文摘Microsatellite alterations within genomic DNA frameshift as a result of defective DNA mismatch repair(MMR). About 15% of sporadic colorectal cancers(CRCs) manifest hypermethylation of the DNA MMR gene MLH1, resulting in mono-and di-nucleotide frameshifts to classify it as microsatellite instability-high(MSI-H) and hypermutated, and due to frameshifts at coding microsatellites generating neo-antigens, produce a robust protective immune response that can be enhanced with immune checkpoint blockade. More commonly, approximately 50% of sporadic nonMSI-H CRCs demonstrate frameshifts at di-and tetra-nucleotide microsatellites to classify it as MSIlow/elevated microsatellite alterations at selected tetranucleotide repeats(EMAST) as a result of functional somatic inactivation of the DNA MMR protein MSH3 via a nuclear-to-cytosolic displacement. The trigger for MSH3 displacement appears to be inflammation and/or oxidative stress, and unlike MSI-H CRC patients, patients with MSI-L/EMAST CRCs show poor prognosis. These inflammatory-associated microsatellite alterations are a consequence of the local tumor microenvironment, and in theory, if the microenvironment is manipulated to lower inflammation, the microsatellite alterations and MSH3 dysfunction should be corrected. Here we describe the mechanisms and significance of inflammatory-associated microsatellite alterations, and propose three areas to deeply explore the consequences and prevention of inflammation's effect upon the DNA MMR system.
