Prediction-based threading of the hMSH2 DNA mismatch repair protein

Identification of transdominant-negative genetic suppressor elements derived from hMSH2 that mediate resistance to 6-thioguanine

Using random screening for genetic suppressor elements, we sought to identify portions of hMSH2 important to the ability of the mismatch repair system to recognize and process DNA adducts that mimic mismatches. All recovered candidate genetic suppressor elements were derived from the region containing amino acids 782 to 844. Expression of a peptide corresponding to this region partially disabled mismatch repair as evidenced by 1.5- to 3.3-fold resistance to 6-thioguanine, cisplatin, and N-methyl-N'-nitrosoguanidine, an increase in the rate of generation of drug resistant variants, and the appearance of microsatellite instability. Even low-level expression of this protein was sufficient to partially impair mismatch repair. The results suggest that this region is important to the ability of the mismatch repair system to mediate drug sensitivity and to maintain genomic stability.

DNA mismatch repair: MutS structures bound to mismatches

When DNA mismatch repair fails, the result is a mutator phenotype, which can lead to cancer in humans. Functional repair is dependent on the recognition of mismatches by a dimeric MutS protein, a homodimer in bacteria but a heterodimer in humans. Recent crystal structures of Thermus aquaticus and Escherichia coli MutS have revealed the structural heterodimeric nature of the bacterial proteins and provide new insights into their complicated ATP-dependent repair mechanism.

Evolutionary origin, diversification and specialization of eukaryotic MutS homolog mismatch repair proteins

Most eubacteria, and all eukaryotes examined thus far, encode homologs of the DNA mismatch repair protein MutS. Although eubacteria encode only one or two MutS-like proteins, eukaryotes encode at least six distinct MutS homolog (MSH) proteins, corresponding to conserved (orthologous) gene families. This suggests evolution of individual gene family lines of descent by several duplication/specialization events. Using quantitative phylogenetic analyses (RASA, or relative apparent synapomorphy analysis), we demonstrate that comparison of complete MutS protein sequences, rather than highly conserved C-terminal domains only, maximizes information about evolutionary relationships. We identify a novel, highly conserved middle domain, as well as clearly delineate an N-terminal domain, previously implicated in mismatch recognition, that shows family-specific patterns of aromatic and charged amino acids. Our final analysis, in contrast to previous analyses of MutS-like sequences, yields a stable phylogenetic tree consistent with the known biochemical functions of MutS/MSH proteins, that now assigns all known eukaryotic MSH proteins to a monophyletic group, whose branches correspond to the respective specialized gene families. The rooted phylogenetic tree suggests their derivation from a mitochondrial MSH1-like protein, itself the descendent of the MutS of a symbiont in a primitive eukaryotic precursor.