Minna Nyström

Mechanisms of pathogenicity in human MSH2 missense mutants.

The human mismatch repair (MMR) gene MSH2 is the second most frequently mutated hereditary nonpolyposis colorectal cancer (HNPCC) susceptibility locus. Given that missense mutations account for 17% of all identified alterations in this gene, the study of their pathogenicity is of increasing importance. Previously, we showed that pathogenic MSH2 missense mutations typically impaired the repair activity of the protein. In this study, we took advantage of its crystal structure and attempted to correlate the mismatch binding and ATP‐catalyzed mismatch release activities with the location of 18 nontruncating MSH2 mutations. We observed that the MMR‐deficient mutations situated in the amino‐terminal connector and lever domains of MSH2 (V161D, G162R, G164R, L173P, L187P, C333Y, and D603N) affected protein stability, whereas mutations in the ATPase domain (A636P, G674A, C697F, I745_I746del, and E749 K) mainly caused defects in mismatch binding or release. Of the MMR‐proficient variants, four (T33P, A272 V, G322D, and V923E) showed slightly reduced mismatch binding and/or release efficiencies compared to wild‐type (WT) protein, while two variants (N127S and A834 T) showed no defects in the assays. Similar to our biochemical data, the mutations that affected protein stability were associated with an absence of the protein in tumors in immunohistochemical (IHC) analyses. In contrast, the protein with the mutation E749 K, which abrogates MMR but not protein stability, is well expressed in tumors. In conclusion, pathogenic missense mutations in MSH2 may interfere with different mechanisms that tend to cluster in separate protein domains with varying effects on protein stability, which could be taken into account when interpreting IHC data. Hum Mutat 29(11), 1355–1363, 2008.

Germline MLH1 and MSH2 mutations in Italian pancreatic cancer patients with suspected Lynch syndrome

Lynch syndrome is an inherited cancer syndrome caused by germline mutations in mismatch repair (MMR) genes MLH1, MSH2, MSH6 and PMS2. LS predisposes to high risk of early-onset colorectal, endometrial and other tumors. Patients with Lynch syndrome have also been shown to have an elevated risk for pancreatic cancer (PC). In this study, we aimed to estimate the frequency of suspected Lynch syndrome among a series of 135 PC patients. Further, we wanted to determine the frequency of MMR gene mutations in the suspected Lynch syndrome cases. We also aimed to verify the pathogenicity of any novel non-truncating variants we might detect with a functional assay. Based on personal and/or familial cancer history, 19 patients were classified as suspected Lynch syndrome cases. DNA material for mutation analysis was available for eleven of them. Four patients were found to carry a total of five MLH1 or MSH2 variants. Of these, MSH2-Q402X, MSH2-G322D, and MLH1-K618A had been previously reported, while the MSH2-E205Q and MSH2-V367I variants were novel. MSH2-Q402X is a known stop mutation and reported here for the first time here in association with PC. MLH1-K618A was found in the unaffected branch of a kindred, suggesting that it may be a polymorphism or a low penetrance variant. MSH2-G322D likely does not cause a MMR defect, although this variant has also been associated with breast cancer as indeed seen in our patient. The novel variants MSH2-E205Q and MSH2-V367I were found in the same patient. Both novel variants were however functional in the applied MMR assay. Our findings suggest that only a small subset of pancreatic cancer patients carry pathogenic MMR mutations.

Agenesis of the corpus callosum and gray matter heterotopia in three patients with constitutional mismatch repair deficiency syndrome

Constitutional mismatch repair deficiency (CMMR-D) syndrome is a rare inherited childhood cancer predisposition caused by biallelic germline mutations in one of the four mismatch repair (MMR)-genes, MLH1, MSH2, MSH6 or PMS2. Owing to a wide tumor spectrum, the lack of specific clinical features and the overlap with other cancer predisposing syndromes, diagnosis of CMMR-D is often delayed in pediatric cancer patients. Here, we report of three new CMMR-D patients all of whom developed more than one malignancy. The common finding in these three patients is agenesis of the corpus callosum (ACC). Gray matter heterotopia is present in two patients. One of the 57 previously reported CMMR-D patients with brain tumors (therefore all likely had cerebral imaging) also had ACC. With the present report the prevalence of cerebral malformations is at least 4/60 (6.6%). This number is well above the population birth prevalence of 0.09–0.36 live births with these cerebral malformations, suggesting that ACC and heterotopia are features of CMMR-D. Therefore, the presence of cerebral malformations in pediatric cancer patients should alert to the possible diagnosis of CMMR-D. ACC and gray matter heterotopia are the first congenital malformations described to occur at higher frequency in CMMR-D patients than in the general population. Further systematic evaluations of CMMR-D patients are needed to identify possible other malformations associated with this syndrome.

Verification of the three‐step model in assessing the pathogenicity of mismatch repair gene variants

In order to assess whether variations affecting DNA mismatch repair (MMR) genes are pathogenic and hence predisposing to Lynch syndrome (LS), a three‐step assessment model has been proposed. Where LS is suspected based on family history, STEP1 is dedicated to the identification of the causative MMR gene and the variation within it. Thereafter, in STEP2 of the assessment model, the effect of the variation on the function of the protein is assessed in an in vitro MMR and in silico assays. Where LS cannot be confirmed or ruled out in STEP2, the more specific biochemical laboratory assays such as analyzing the effect of the variation on expression, localization, and interaction of the protein are required in STEP3. Here, we verified the proposed three‐step assessment model and its ability to distinguish pathogenic MMR variations from variants of uncertain significance (VUS) by utilizing the clinical as well as the laboratory and in silico data of 37 MLH1, 26 MSH2, and 11 MSH6 variations. The proposed model was shown to be appropriate and proceed logically in assessing the pathogenicity of MMR variations. In fact, for MMR deficient MSH2 and MLH1 variations the first two steps seem to be sufficient as STEP3 provides no imperative information concerning the variant pathogenicity. However, the importance of STEP3 is seen in the assessment of MMR proficient variations showing discrepant in silico results as their pathogenicity cannot be confirmed or ruled out after STEP2. MSH6 variations may be applicable to the model if appropriate selection in terms of ruling out MLH1 and MSH2 variations and MLH1 promoter hypermethylation is ensured prior to the completion of STEP2. In conclusion, taking into consideration the susceptibility gene the three‐step model can be utilized in an appropriate and efficient manner to determine the pathogenicity of MMR gene variations. Hum Mutat 32:107–115, 2011.

APC and β-catenin protein expression patterns in HNPCC-related endometrial and colorectal cancers

Objective: The adenomatous polyposis coli (APC) and β-catenin (CTNNB1) genes are the two major components of the Wnt signaling pathway that has been shown to play an important role in the formation of certain cancers. The overactivation of the pathway, which results in abnormal accumulation of β-catenin protein in nuclei, contributes to most colorectal cancers (CRCs), both sporadic and hereditary, as well as sporadic endometrial cancers (ECs). Here, we studied the involvement of APC and β-catenin in hereditary nonpolyposis colorectal cancer (HNPCC)-related ECs, and compared the expression patterns to those in HNPCC-related CRCs. Materials and methods: Nineteen ECs and 31 CRCs derived from HNPCC patients were immunohistochemically stained with anti-APC- and anti-β-catenin –antibodies. Results: Tumor-specific loss of APC was observed in 16 of endometrial cancers (3 of 19) and in 39 of colorectal cancers (12 of 31). Consistently, the loss of APC expression was associated with nuclear β-catenin staining. Altogether, aberrant β-catenin localization was observed in 53 of ECs (10 of 19) as compared to 84 of CRCs (26 of 31) (P=0.02).Conclusion: Our results suggest a frequent overactivation of the Wnt signaling pathway in hereditary endometrial cancer. In accordance with studies on sporadic cancers, abnormal accumulation of β-catenin protein in nuclei occurred much less frequently in HNPCC-related ECs than CRCs, which may reflect organ-specific differences in their pathogenesis.

The first functional study of MLH3 mutations found in cancer patients.

The MLH3 gene is one of the five mismatch repair (MMR) genes associated with hereditary nonpolyposis colorectal cancer (HNPCC). Eighteen different inherited MLH3 mutations have been reported as pathogenic in an international mutation database. In several cases, a mutation was found in a patient without a family history suggestive of inherited cancer susceptibility. In some cases, a similar mutation was also found in sporadic patients and/or healthy controls. Four patients carried an MLH3 mutation together with another inherited MMR gene variation. No functional analyses have been performed to assess the pathogenicity of these 18 mutations. MLH3 has been assumed to be less important in MMR than the other HNPCC susceptibility genes MSH2, MSH6, MLH1, and PMS2, and accordingly a low‐risk gene for colorectal cancer (CRC). To assess the significance of the inherited sequence variations in MLH3, we functionally characterized seven missense mutations (Q24E, R647C, S817G, G933C, W1276R, A1394T, E1451K) scattered throughout the MLH3 polypeptide. The mutations were found in CRC or endometrial cancer patients and reported as pathogenic. Our study showed that the seven mutated MLH3 proteins, in complex with their counterpart MLH1 (MutLγ), repaired mismatches as the wild type MutLγ but worse than a heterodimer of MLH1 and PMS2 (MutLα). The results confirm that MutLγ is a less efficient MMR complex than MutLα and show that the MLH3 mutations alone do not interfere with MMR. Further studies are needed to evaluate the pathogenicity of MLH3 mutations in compound with other MMR mutations.

Mismatch repair analysis of inherited MSH2 and/or MSH6 variation pairs found in cancer patients.

Mismatch repair (MMR) malfunction causes the accumulation of mismatches in the genome leading to genomic instability and cancer. The inactivation of an MMR gene (MSH2, MSH6, MLH1, or PMS2) with an inherited mutation causes Lynch syndrome (LS), a dominant susceptibility to cancer. MMR gene variants of uncertain significance (VUS) may be pathogenic mutations, which cause LS, may result in moderately increased cancer risks, or may be harmless polymorphisms. Our study suggests that an inherited MMR VUS individually assessed as proficient may, however, in a pair with another MMR VUS found in the same colorectal cancer (CRC) patient have a concomitant contribution to the MMR deficiency. Here, eight pairs of MMR gene variants found in cancer patients were functionally analyzed in an in vitro MMR assay. Although the other pairs do not suggest a compound deficiency, the MSH2 VUS pair c.380A>G/c.982G>C (p.Asn127Ser/p.Ala328Pro), which nearly halves the repair capability of the wild‐type MSH2 protein, is presumed to increase the cancer risk considerably. Moreover, two MSH6 variants, c.1304T>C (p.Leu435Pro) and c.1754T>C (p.Leu585Pro), were shown to be MMR deficient. The role of one of the most frequently reported MMR gene VUS, MSH2 c.380A>G (p.Asn127Ser), is especially interesting because its concomitant defect with another variant could finally explain its recurrent occurrence in CRC patients. Hum Mutat 33:1294–1301, 2012.

Functional characterization of MLH1 missense variants identified in lynch syndrome patients

Germline mutations in the human DNA mismatch repair (MMR) genes MSH2 and MLH1 are associated with the inherited cancer disorder Lynch syndrome (LS), also known as hereditary nonpolyposis colorectal cancer or HNPCC. A proportion of MSH2 and MLH1 mutations found in suspected LS patients give rise to single amino acid substitutions. The functional consequences in regard to pathogenicity of many of these variants are unclear. We have examined the functionality of a panel of MLH1 missense mutations found in LS families, by testing the variant proteins in functional assays, addressing subcellular localization, and protein–protein interaction with the dimer partner PMS2 and the MMR‐associated exonuclease 1. We show that a significant proportion of examined variant proteins have functional defects in either subcellular localization or protein–protein interactions, which is suspected to lead to the cancer phenotype observed in patients. Moreover, the obtained results correlate well with reported MMR activity and with in silico analysis for a majority of the variants. Hum Mutat 33:1647–1655, 2012.

Functional characterization of rare missense mutations in MLH1 and MSH2 identified in Danish colorectal cancer patients

Recently, we have performed a population based study to analyse the frequency of colorectal cancer related MLH1 and MSH2 missense mutations in the Danish population. Half of the analyzed mutations were rare and most likely only present in the families where they were identified originally. Some of the missense mutations were located in conserved regions in the MLH1 and MSH2 proteins indicating a relation to disease development. In the present study, we functionally characterized 10 rare missense mutations in MLH1 and MSH2 identified in 13 Danish CRC families. To elucidate the pathogenicity of the missense mutations, we carried out in vitro functional analyses. The missense mutations were analyzed for their effect on protein expression and repair efficiency. The results of the functional analysis were correlated with clinical data on the families carrying these mutations. Eight missense mutations resulted in proteins with expression and repair efficiency similar to the wild type. One missense mutation (MSH2 p.Met688Val) caused reduced protein expression and one (MSH2 p.Leu187Arg) caused both reduced protein expression and repair deficiency. The MSH2 p.Leu187Arg mutation was found in an Amsterdam II family presenting with high microsatellite instability and loss of MSH2 and MSH6 proteins in tumours. In conclusion, only 1/10 missense mutations displayed repair deficiency and could be classified as pathogenic. No final conclusion can be drawn on the MSH2 p.Met688Val mutation, which caused reduced protein expression. Although, no deficiencies have been identified in the proteins harbouring the other missense mutations, pathogenicity of these variants cannot be unambiguously excluded.

Uncertain pathogenicity of MSH2 variants N127S and G322D challenges their classification

Hereditary non‐polyposis colorectal cancer (HNPCC) is associated with germline mutations in mismatch repair (MMR) genes. Inherited missense mutations, however, complicate the diagnostics because they do not always cause unambiguous predisposition to cancer. This leads to variable and contradictory interpretations of their pathogenicity. Here, we establish evidence for the functionality of the 2 frequently reported variations, MSH2 N127S and G322D, which have been described both as pathogenic and non‐pathogenic in literature and databases. We report the results of 3 different functional analyses characterizing the biochemical properties of these protein variants in vitro. We applied an immunoprecipitation assay to assess the MSH2–MSH6 interaction, a bandshift assay to study mismatch recognition and binding, and a MMR assay for repair efficiency. None of the experiments provided evidence on reduced functionality of these proteins as compared to wild‐type MSH2. Our data demonstrate that MSH2 N127S and G322D per se are not sufficient to trigger MMR deficiency. This together with variable clinical phenotypes in the mutation carriers suggest no or only low cancer risk in vivo.