Physical and functional interaction between hMSH5 and c-Abl.

Despite being a member of the mismatch repair family of proteins, the biological functions of hMSH5 in human cells are presently elusive. Here, we report a novel physical and functional interaction between hMSH5 and c-Abl; the latter is a critical non-receptor tyrosine kinase involved in many critical cellular functions including DNA damage response, in which the kinase activity is normally suppressed in the absence of biological challenges. Our data indicate that hMSH5 associates with c-Abl in vivo, which is mediated by a direct physical interaction between the NH2 terminus (residues 1-109) of hMSH5 and the c-Abl SH3 domain. This physical interaction facilitates the activation of c-Abl tyrosine kinase and the phosphorylation of hMSH5 in response to ionizing radiation. Our data also indicate that the hMSH5 P29S variant overactivates the c-Abl tyrosine kinase activity. Furthermore, it seems that the tyrosine phosphorylation of hMSH5 promotes the dissociation of hMSH4-hMSH5 heterocomplex. Together, the revealed physical and functional interaction of hMSH5 with c-Abl implies that the interplay between hMSH5 and c-Abl could manipulate cellular responses to ionizing radiation-induced DNA damages.

Formation of hMSH4-hMSH5 heterocomplex is a prerequisite for subsequent GPS2 recruitment.

Increasing evidence suggests that components of the DNA mismatch repair (MMR) pathway play multifunctional roles beyond the scope of mismatch correction, including the modulation of cellular responses to DNA damage and homologous recombination. The heterocomplex consisting of MutS homologous proteins, hMSH4 and hMSH5, is believed to play essential roles in meiotic DNA repair particularly during the process of meiotic homologous recombination (HR). In order to gain a better understanding of the mechanistic basis underlying the roles of these two human MutS proteins, we have identified G-protein pathway suppressor 2 (GPS2) (i.e., an integral component of a deacetylase complex) as an interacting protein partner specifically for the hMSH4-hMSH5 heterocomplex. The interaction with GPS2 is entirely dependent on the physical association between hMSH4 and hMSH5, as disruption of the interaction between hMSH4 and hMSH5 completely abolishes GPS2 recruitment. Our analysis further indicates that the association with GPS2 is mediated through the interface of hMSH4-hMSH5 complex and the N-terminal region of GPS2. Moreover, these three proteins interact in human cells, and analysis of microarray data suggested a coordinated expression pattern of these genes during the onset of meiosis. Together, the results of our present study suggest that the GPS2-associated deacetylase complex might function in concert with hMSH4-hMSH5 during the process of homologous recombination.

Two variants of MutS homolog hMSH5: prevalence in humans and effects on protein interaction.

MSH5 is known to play functional roles in an array of cellular processes such as DNA damage response and meiotic homologous recombination. Here, we report the characterization of an hMSH5 splicing variant (hMSH5sv) that resulted from the retention of the last 51 bp of hMSH5 intron 6, in which the encoded 17-amino acid insertion between codons 179 and 180 does not compromise its capability to interact with hMSH4. We have also identified an hMSH5 polymorphism (C85T) [corrected] that altered codon 29 of the hMSH5 gene resulting in a proline-to-serine change (P29S). The interaction domains of hMSH4 and hMSH5 have also been resolved. The P29S alteration is located within the interacting domain and leads to a weakened protein interaction with hMSH4. Together, our present study revealed the existence of two forms of hMSH5 variants in human cells. The different properties associated with these two hMSH5 variants underscore the potential functional diversity of the human hMSH5 gene.

hMRE11 deficiency leads to microsatellite instability and defective DNA mismatch repair.

DNA mismatch repair (MMR) is essential in the surveillance of accurate transmission of genetic information, and defects in this pathway lead to microsatellite instability and hereditary nonpolyposis colorectal cancer (HNPCC). Our previous study raised the possibility that hMRE11 might be involved in MMR through physical interaction with hMLH1. Here, we show that hMRE11 deficiency leads to significant increase in MSI for both mono- and dinucleotide sequences. Furthermore, RNA-interference-mediated hMRE11-knockdown in HeLa cells results in MMR deficiency. Analysis of seven HNPCC-associated hMLH1 missense mutations located within the hMRE11-interacting domain shows that four mutations (L574P, K618T, R659P and A681T) cause near-complete disruption of the interaction between hMRE11 and hMLH1, and two mutations (Q542L and L582V) cause a 30% reduction of protein interaction. These findings indicate that hMRE11 represents a functional component of the MMR pathway and the disruption of hMLH1-hMRE11 interaction could be an alternative molecular explanation for hMLH1 mutations in a subset of HNPCC tumours.