Abstract
Microsatellite instability promotes colonic tumorigenesis through generating frameshift mutations at coding microsatellites of tumor suppressor genes, such as TGFBR2 and ACVR2. As a consequence, signaling through these TGFβ family receptors is abrogated in DNA Mismatch repair (MMR)-deficient tumors. How these mutations occur in real time and mutational rates of these human coding sequences have not previously been studied. We utilized cell lines with different MMR deficiencies (hMLH1−/−, hMSH6−/−, hMSH3−/−, and MMR-proficient) to determine mutation rates. Plasmids were constructed in which exon 3 of TGFBR2 and exon 10 of ACVR2 were cloned +1 bp out of frame, immediately after the translation initiation codon of an enhanced GFP (EGFP) gene, allowing a −1 bp frameshift mutation to drive EGFP expression. Mutation-resistant plasmids were constructed by interrupting the coding microsatellite sequences, preventing frameshift mutation. Stable cell lines were established containing portions of TGFBR2 and ACVR2, and nonfluorescent cells were sorted, cultured for 7–35 days, and harvested for flow cytometric mutation detection and DNA sequencing at specific time points. DNA sequencing revealed a −1 bp frameshift mutation (A9 in TGFBR2 and A7 in ACVR2) in the fluorescent cells. Two distinct fluorescent populations, M1 (dim, representing heteroduplexes) and M2 (bright, representing full mutants) were identified, with the M2 fraction accumulating over time. hMLH1 deficiency revealed 11 (5.91×10−4) and 15 (2.18×10−4) times higher mutation rates for the TGFBR2 and ACVR2 microsatellites compared to hMSH6 deficiency, respectively. The mutation rate of the TGFBR2 microsatellite was ∼3 times higher in both hMLH1 and hMSH6 deficiencies than the ACVR2 microsatellite. The −1 bp frameshift mutation rates of TGFBR2 and ACVR2 microsatellite sequences are dependent upon the human MMR background.
Highlights
The DNA Mismatch repair (MMR) system consists of proteins that act in concert to recognize and coordinate repair of nucleotide base mismatches and slippage mistakes at microsatellite sequences on newly synthesized DNA [1]
MMR activity requires the proper functioning of hMutSa and hMutSb to recognize defects, and hMutLa to coordinate repair. hMutSa recognizes single nucleotide interstrand mispairs and insertion/deletion loops (IDLs) containing 1 or 2 looped nucleotides, whereas hMutSb recognizes IDLs containing 2 or more looped nucleotides that occur at microsatellite sequences [2]
The plasmid pIREShyg2-enhanced GFP (EGFP) allows the expression of EGFP under the control of a constitutive cytomegalovirus promoter, which is active throughout the cell cycle [25]
Summary
The DNA MMR system consists of proteins that act in concert to recognize and coordinate repair of nucleotide base mismatches and slippage mistakes at microsatellite sequences on newly synthesized DNA [1]. MMR activity requires the proper functioning of hMutSa and hMutSb to recognize defects, and hMutLa to coordinate repair. HMutSa (heterodimer of hMSH2 and hMSH6) recognizes single nucleotide interstrand mispairs and insertion/deletion loops (IDLs) containing 1 or 2 looped nucleotides, whereas hMutSb (heterodimer of hMSH2 and hMSH3) recognizes IDLs containing 2 or more looped nucleotides that occur at microsatellite sequences [2]. The hMutS complexes interact with the hMutLa protein complex (heterodimer of hMLH1 and hPMS2) to coordinate excision and repair of the mispair or IDL [3,4,5]. Epigenetic inactivation of hMLH1 through promoter hypermethylation occurs in 15–20% of sporadic colorectal cancers [12,13]. The resulting colorectal cancers display the phenotype of MSI observed as novel length mutations at microsatellites [7]
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