Human MutY homolog, a DNA glycosylase involved in base excision repair, physically and functionally interacts with mismatch repair proteins human MutS homolog 2/human MutS homolog 6.

Adenines mismatched with guanines or 7,8-dihydro-8-oxo-deoxyguanines that arise through DNA replication errors can be repaired by either base excision repair or mismatch repair. The human MutY homolog (hMYH), a DNA glycosylase, removes adenines from these mismatches. Human MutS homologs, hMSH2/hMSH6 (hMutSalpha), bind to the mismatches and initiate the repair on the daughter DNA strands. Human MYH is physically associated with hMSH2/hMSH6 via the hMSH6 subunit. The interaction of hMutSalpha and hMYH is not observed in several mismatch repair-defective cell lines. The hMutSalpha binding site is mapped to amino acid residues 232-254 of hMYH, a region conserved in the MutY family. Moreover, the binding and glycosylase activities of hMYH with an A/7,8-dihydro-8-oxo-deoxyguanine mismatch are enhanced by hMutSalpha. These results suggest that protein-protein interactions may be a means by which hMYH repair and mismatch repair cooperate in reducing replicative errors caused by oxidized bases.     

Identification of the protein components of mismatch binding complexes in human cells using a gel-shift assay.

In eukaryotes, mismatch recognition is thought to be mediated by two heterodimers, hMutSalpha (hMSH2+hMSH6), which preferentially binds to base-base mismatches and hMutSbeta (hMSH2+hMSH3), which binds to insertion/deletion loops. We studied these mismatch binding activities in several human cell lines with a gel-shift assay using various mismatch oligonucleotides as substrates. Both hMutSalpha and hMutSbeta activities could be detected in various human cell lines. In cells with amplified copies of the hMSH3 gene, a large increase in hMutSbeta and a reduction in hMutSalpha were observed. To identify the composition of each mismatch binding complex, the protein-DNA complexes were transferred from gel-shift polyacrylamide gel to a polyvinylidene difluoride membrane and were subjected to immunoblot analysis with an enhanced chemiluminescence protein detection system. The results clearly demonstrated that hMutSalpha detected by the gel-shift assay was composed of hMSH2 and hMSH6, while hMutSbeta was composed of hMSH2 and hMSH3. Our data, therefore, support a model whereby formation of hMutSalpha and hMutSbeta is mutually regulated. Combination of a gel-shift assay with immunoblotting (shift-Western assay) proved to be a highly sensitive technique and should be useful for studying the interactions between DNA and binding proteins, including DNA mismatch recognition.     

hMutS alpha is protected from ubiquitin-proteasome-dependent degradation by atypical protein kinase C zeta phosphorylation

The hMutS alpha (hMSH2-hMSH6) protein heterodimer plays a critical role in the detection of DNA mispairs in the mismatch repair (MMR) process. We recently reported that hMutS alpha proteins were degraded by the ubiquitin-proteasome pathway in a cell-type-dependent manner, indicating that one or several regulator(s) may interfere with hMutS alpha protein ubiquitination and degradation. On the other hand, we and others have shown that protein kinase C (PKC) is involved as a positive regulator of MMR activity. Here, we provide evidence that the atypical PKC zeta regulates ubiquitination, degradation, and levels of hMutS alpha proteins. Using both PKC zeta-transfected U937 and PKC zeta siRNA-transfected MRC-5 cell lines, we found that PKC zeta protein expression was correlated with that of hMutS alpha as well as with MMR activity, but was inversely correlated with hMutS alpha protein ubiquitination and degradation. Interestingly, PKC zeta interacts with hMSH2 and hMSH6 proteins and phosphorylates both. Moreover, in an in vitro assay PKCzeta mediates phosphorylation events decreasing hMutS alpha protein degradation via the ubiquitin-proteasome pathway. Altogether, our results indicate that PKC zeta modulates hMutS alpha stability and protein levels, and suggest a role for PKC zeta in genome stability by regulating MMR activity.     

Functional analysis of human MutSalpha and MutSbeta complexes in yeast.

Mismatch repair (MMR) is initiated when a heterodimer of hMSH2*hMSH6 or hMSH2*hMSH3 binds to mismatches. Here we perform functional analyses of these human protein complexes in yeast. We use a sensitive genetic system wherein the rate of single-base deletions in a homopolymeric run in the LYS2 gene is 10 000-fold higher in an msh2 mutant than in a wild-type strain. Expression of the human proteins alone or in combination does not reduce the mutation rate of the msh2 strain, and expression of the individual human proteins does not increase the low mutation rate of a wild-type strain. However, co-expression of hMSH2 and hMSH6 in wild-type yeast increases the mutation rate 4000-fold, while co-expression of hMSH2 and hMSH3 elevates the rate 5-fold. Analysis of cell extracts indicates that the proteins are expressed and bind to mismatched DNA. The results suggest that hMutSalpha and hMutSbeta complexes form, bind to and prevent correction of replication slippage errors in yeast. Expression of hMSH6 with hMSH2 containing a proline substituted for a conserved Arg524 eliminates the mutator effect and reduces mismatch binding. The analogous mutation in humans is associated with microsatellite instability, defective MMR and cancer, illustrating the utility of the yeast system for studying human disease alleles.     

Mutation in the magnesium binding site of hMSH6 disables the hMutSalpha sliding clamp from translocating along DNA

In human cells, binding of base/base mismatches and small insertion/deletion loops is mediated by hMutSalpha, a heterodimer of hMSH2 and hMSH6. In the presence of ATP and magnesium, hMutSalpha dissociates from the mismatch by following the DNA contour in the form of a sliding clamp. This process is enabled by a conformational change of the heterodimer, which is driven by the binding of ATP and magnesium in the Walker type A and B motifs of the polypeptides, respectively. We show that a purified recombinant hMutSalpha variant, hMutSalpha 6DV, which contains an aspartate to valine substitution in the Walker type B motif of the hMSH6 subunit, fails to undergo the conformational change compatible with translocation. Instead, its direct dissociation from the mismatch-containing DNA substrate in the presence of ATP and magnesium precludes the assembly of a functional mismatch repair complex. The "translocation-prone" conformation of wild type hMutSalpha could be observed solely under conditions that favor hydrolysis of the nucleotide and mismatch repair in vitro. Thus, whereas magnesium could be substituted with manganese, ATP could not be replaced with its slowly or nonhydrolyzable homologues ATP-gammaS or AMPPNP, respectively. The finding that ATP induces different conformational changes in hMutSalpha in the presence and in the absence of magnesium helps explain the functional differences between hMutSalpha variants incapable of binding ATP as compared with those unable to bind the metal ion.     

Implication of protein kinase C in the regulation of DNA mismatch repair protein expression and function

The DNA mismatch repair (MMR) proteins are essential for the maintenance of genomic stability of human cells. Compared with hereditary or even sporadic carcinomas, MMR gene mutations are very uncommon in leukemia. However, genetic instability, attested by either loss of heterozygosity or microsatellite instability, has been extensively documented in chronic or acute malignant myeloid disorders. This observation suggests that in leukemia some internal or external signals may interfere with MMR protein expression and/or function. We investigated the effects of protein kinase C (PKC) stimulation by 12-O-tetradecanoylphorbol-13-acetate (TPA) on MMR protein expression and activity in human myeloid leukemia cell lines. First, we show here that unstimulated U937 cells displayed low level of PKC activity as well as MMR protein expression and activity compared with a panel of myeloid cell lines. Second, treatment of U937 cells with TPA significantly increased (3-5-fold) hMSH2 expression and, to a lesser extent, hMSH6 and hPMS2 expression, correlated to a restoration of MMR function. In addition, diacylglycerol, a physiological PKC agonist, induced a significant increase in hMSH2 expression, whereas chelerythrine or calphostin C, two PKC inhibitors, significantly decreased TPA-induced hMSH2 expression. Reciprocally, treatment of HEL and KG1a cells that exhibited a high level of PKC expression, with chelerythrine significantly decreased hMSH2 and hMSH6 expression. Moreover, the alteration of MMR protein expression paralleled the difference in microsatellite instability and cell sensitivity to 6-thioguanine. Our results suggest that PKC could play a role in regulating MMR protein expression and function in some myeloid leukemia cells.     

Identification of mismatch repair protein complexes in HeLa nuclear extracts and their interaction with heteroduplex DNA

Deficiencies in DNA mismatch repair (MMR) have been found in hereditary colon cancers (hereditary non-polyposis colon cancer, HNPCC) as well as in sporadic cancers, illustrating the importance of MMR in maintaining genomic integrity. We have examined the interactions of specific mismatch repair proteins in human nuclear extracts. Western blot and co-immunoprecipitation studies indicate two complexes as follows: one consisting of hMSH2, hMSH6, hMLH1, and hPMS2 and the other consisting of hMSH2, hMSH6, hMLH1, and hPMS1. These interactions occur without the addition of ATP. Furthermore, the protein complexes specifically bind to mismatched DNA and not to a similar homoduplex oligonucleotide. The protein complex-DNA interactions occur primarily through hMSH6, although hMSH2 can also become cross-linked to the mismatched substrate when not participating in the MMR protein complex. In the presence of ATP the binding of hMSH6 to mismatched DNA is decreased. In addition, hMLH1, hPMS2, and hPMS1 no longer interact with each other or with the hMutSalpha complex (hMSH2 and hMSH6). However, the ability of hMLH1 to co-immunoprecipitate mismatched DNA increases in the presence of ATP. This interaction is dependent on the presence of the mismatch and does not appear to involve a direct binding of hMLH1 to the DNA.     

Mismatch recognition and DNA-dependent stimulation of the ATPase activity of hMutSalpha is abolished by a single mutation in the hMSH6 subunit

The most abundant mismatch binding factor in human cells, hMutSalpha, is a heterodimer of hMSH2 and hMSH6, two homologues of the bacterial MutS protein. The C-terminal portions of all MutS homologues contain an ATP binding motif and are highly conserved throughout evolution. Although the N termini are generally divergent, they too contain short conserved sequence elements. A phenylalanine --> alanine substitution within one such motif, GXFY(X)(5)DA, has been shown to abolish the mismatch binding activity of the MutS protein of Thermus aquaticus (Malkov, V. A., Biswas, I., Camerini-Otero, R. D., and Hsieh, P. (1997) J. Biol. Chem. 272, 23811-23817). We introduced an identical mutation into one or both subunits of hMutSalpha. The Phe --> Ala substitution in hMSH2 had no effect on the biological activity of the heterodimer. In contrast, the in vitro mismatch binding and mismatch repair functions of hMutSalpha were severely attenuated when the hMSH6 subunit was mutated. Moreover, this variant heterodimer also displayed a general DNA binding defect. Correspondingly, its ATPase activity could not be stimulated by either heteroduplex or homoduplex DNA. Thus the N-terminal portion of hMSH6 appears to impart on hMutSalpha not only the specificity for recognition and binding of mismatched substrates but also the ability to bind to homoduplex DNA.     

hMSH2 and hMSH6 play distinct roles in mismatch binding and contribute differently to the ATPase activity of hMutSalpha.

In extracts of human cells, base-base mismatches and small insertion/deletion loops are bound primarily by hMutSalpha, a heterodimer of hMSH2 and hMSH6 (also known as GTBP or p160). Recombinant hMutSalpha bound a G/T mismatch-containing oligonucleotide with an apparent dissociation constant Kd = 2.6 nM, while its affinity for a homoduplex substrate was >20-fold lower. In the presence of ATP, hMutSalpha dissociated from mismatched oligonucleotide substrates, and this reaction was attenuated by mutating the conserved lysine in the ATP-binding domains of hMSH6, hMSH2 or both to arginine. Surprisingly, this reaction required only ATP binding, not hydrolysis. The ATPase activity of hMutSalpha variants carrying the Lys-->Arg mutation in hMSH2 or in hMSH6 was severely affected, but these mutants were still proficient in mismatch binding and were able to complement, albeit to different extents, mismatch repair-deficient cell extracts. The mismatch binding-proficient, ATPase-deficient double mutant was inactive in the complementation assay and its presence in repair-proficient extracts was inhibitory. We conclude that although the ATPase activity of hMutSalpha is dispensible for mismatch binding, it is required for mismatch correction.     

Ectopically expressed human tumor biomarker MutS homologue 2 is a novel endogenous ligand that is recognized by human γδ T cells to induce innate anti-tumor/virus immunity

Human (h) MutS homologue 2, a nuclear protein, is a critical element of the DNA mismatch repair system. Our previous studies suggest that hMSH2 might be a protein ligand for TCRγδ. Here, we show that hMSH2 is ectopically expressed on a large panel of epithelial tumor cells. We found that hMSH2 interacts with both TCRγδ and NKG2D and contributes to Vδ2 T cell-mediated cytolysis of tumor cells. Moreover, recombinant human MSH2 protein stimulates the proliferation and IFN-γ secretion of Vδ2 T cells in vitro. Finally, hMSH2 expression is induced on the cell surface of Epstein-Barr virus-transformed lymphoblastoid cell lines, and the induction increases the sensitivity of these lymphoblastoid cell lines to γδ T cell-mediated cytolysis. Our data suggest that hMSH2 functions as a tumor-associated or virus infection-related antigen recognized by both Vδ2 TCR and NKG2D, and it plays a role in eliciting the immune responses of γδ T cells against tumor- and virus-infected cells. The recognition of ectopic surface-expressing endogenous antigen by TCRγδ and NKG2D may be an important mechanism of innate immune response to carcinogenesis and viral infection.     

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.     

Mismatch repair processing of carcinogen-DNA adducts triggers apoptosis

The DNA mismatch repair pathway is well known for its role in correcting biosynthetic errors of DNA replication. We report here a novel role for mismatch repair in signaling programmed cell death in response to DNA damage induced by chemical carcinogens. Cells proficient in mismatch repair were highly sensitive to the cytotoxic effects of chemical carcinogens, while cells defective in either human MutS or MutL homologs were relatively insensitive. Since wild-type cells but not mutant cells underwent apoptosis upon treatment with chemical carcinogens, the apoptotic response is dependent on a functional mismatch repair system. By analyzing p53 expression in several pairs of cell lines, we found that the mismatch repair-dependent apoptotic response was mediated through both p53-dependent and p53-independent pathways. In vitro biochemical studies demonstrated that the human mismatch recognition proteins hMutSalpha and hMutSbeta efficiently recognized DNA damage induced by chemical carcinogens, suggesting a direct participation of mismatch repair proteins in mediating the apoptotic response. Taken together, these studies further elucidate the mechanism by which mismatch repair deficiency predisposes to cancer, i.e., the deficiency not only causes a failure to repair mismatches generated during DNA metabolism but also fails to direct damaged and mutation-prone cells to commit suicide.     

Microsatellite instability and suppressed DNA repair enzyme expression in rheumatoid arthritis

Reactive oxygen and nitrogen are produced by rheumatoid arthritis (RA) synovial tissue and can potentially induce mutations in key genes. Normally, this process is prevented by a DNA mismatch repair (MMR) system that maintains sequence fidelity during DNA replication. Key members of the MMR system include MutSalpha (hMSH2 and hMSH6) and MutSbeta (hMSH2 and hMSH3). To provide evidence of DNA damage in inflamed synovium, we analyzed synovial tissues for microsatellite instability (MSI). MSI was examined by PCR on genomic DNA of paired synovial tissue and peripheral blood cells of RA patients using specific primer sequences for five key microsatellites. Surprisingly, abundant MSI was observed in RA synovium compared with osteoarthritis tissue. Western blot analysis for the expression of MMR proteins demonstrated decreased hMSH6 and increased hMSH3 in RA synovium. To evaluate potential mechanisms of MMR regulation in arthritis, fibroblast-like synoviocytes (FLS) were isolated from synovial tissues and incubated with the NO donor S-nitroso-N-acetylpenicillamine. Western blot analysis demonstrated constitutive expression of hMSH2, 3, and 6 in RA and osteoarthritis FLS. When FLS were cultured with S-nitroso-N-acetylpenicillamine, the pattern of MMR expression in RA synovium was reproduced (high hMSH3, low hMSH6). Therefore, oxidative stress can relax the DNA MMR system in RA by suppressing hMSH6. Decreased hMSH6 can subsequently interfere with repair of single base mutations, which is the type observed in RA. We propose that oxidative stress not only creates DNA adducts that are potentially mutagenic, but also suppresses the mechanisms that limit the DNA damage.     

四种错配修复基因蛋白在结直肠癌中的表达及临床意义

目的:分析hMLH1、hMSH2、hMSH6和hPMS2四种错配修复基因蛋白在结直肠癌中的表达及其临床意义。方法:随机选取2013年1月至2015年12月广州医科大学附属第三医院结直肠癌患者标本177例,采用免疫组织化学法检测hMLH1、hMSH2、hMSH6和hPMS2蛋白的表达情况,并分析蛋白表达与临床参数间关系。结果:177例结直肠癌组织中,hMLH1蛋白的缺失率为6.2%(11/177),hMSH2蛋白的缺失率为4.0%(7/177),hMSH6蛋白的缺失率为1.7%(3/177),hPMS2蛋白的缺失率为8.0%(14/177),四者之和占所有结直肠癌病例的19.8%(35/177)。四种错配修复基因蛋白表达缺失均与肿瘤发生部位有关(P0.05),另外,hMLH1及hPMS2蛋白的表达缺失还与肿瘤分化程度相关(P0.05),hMSH6蛋白的表达缺失还与肿瘤浸润深度相关(P0.05);而缺失均与年龄、性别、淋巴结转移和远处转移无关(P0.05)。结论:错配修复蛋白的表达在部分结直肠癌组织中出现缺失现象,且与肿瘤部位及分化程度密切相关。hMLH1、hMSH2、hMSH6和hPMS2四种基因的突变,为临床判断预后及拟定治疗方案提供一个有参考价值的依据。