Mutations in two short noncoding mononucleotide repeats in most microsatellite-unstable colorectal cancers

DNA mismatch repair (MMR)-deficient cells typically accumulate mutations in short repetitive DNA tracts. This microsatellite instability (MSI) facilitates malignant transformation when affecting genes with growth-related and caretaker functions. To date, several putative MSI target genes have been proposed mainly based on high mutation frequency within their coding regions. However, some intronic repeat mutations have also been suggested to associate with MSI tumorigenesis, indicating the need for additional analyses on noncoding repeats. Here we have analyzed an intronic T9 repeat of semenogelin I (SEMG1) and report mutation frequencies of 51% (75 of 146) and 62% (8 of 13) in MMR-deficient primary colorectal cancers and cell lines, respectively. The putative effect of the SEMG1 mutations was assessed by RNA and protein level analyses, but no differences were detected between colorectal cancer cell lines with different SEMG1 status. Subsequently, the general background mutation frequency of MSI colorectal cancers was assessed by screening for intergenic T9 repeat alterations. One of 10 examined repeats was mutated in 70% (102 of 145) of the colorectal cancers evaluated. The frequencies observed here are notably higher than previously published in noncoding repeats shorter than 10 bp in MMR-deficient primary tumors. Our results indicate that high mutation frequencies, similar or higher than those observed in proposed and approved target genes, can be detected in repeat tracts of MSI tumors without any apparent selection pressure. These data call for urgent and thorough large-scale evaluation of mutation frequencies in neutral short repetitive sequences in MMR-deficient tumors.     

Candidate driver genes in microsatellite-unstable colorectal cancer

Defects in the mismatch repair system lead to microsatellite instability (MSI), a feature observed in ～ 15% of all colorectal cancers (CRCs). Microsatellite mutations that drive tumourigenesis, typically inactivation of tumour suppressors, are selected for and are frequently detected in MSI cancers. Here, we evaluated somatic mutations in microsatellite repeats of 790 genes chosen based on reduced expression in MSI CRC and existence of a coding mononucleotide repeat of 6-10 bp in length. All the repeats were initially sequenced in 30 primary MSI CRC samples and whenever frameshift mutations were identified in >20%, additional 70 samples were sequenced. To distinguish driver mutations from passengers, we similarly analyzed the occurrence of frameshift mutations in 121 intronic control repeats and utilized a statistical regression model to determine cut-off mutation frequencies for repeats of all types (A/T and C/G, 6-10 bp). Along with several know target genes, including TGFBR2, ACVR2, and MSH3, six novel candidate driver genes emerged that harbored significantly more mutations than identical control repeats. The mutation frequencies in 100 MSI CRC samples were 51% in G8 of GLYR1, 47% in T9 of ABCC5, 43% in G8 of WDTC1, 33% in A8 of ROCK1, 30% in T8 of OR51E2, and 28% in A8 of TCEB3. Immunohistochemical staining of GLYR1 revealed defective protein expression in tumors carrying biallelic mutations, supporting a loss of function hypothesis. This is a large scale, unbiased effort to identify genes that when mutated are likely to contribute to MSI CRC development.     

Systematic identification of genes with coding microsatellites mutated in DNA mismatch repair-deficient cancer cells

Microsatellite instability (MSI) caused by deficient DNA mismatch-repair functions is a hallmark of cancers associated with the hereditary nonpolyposis colorectal cancer (HNPCC) syndrome but is also found in about 15% of all sporadic tumors. Most affected microsatellites reside in untranslated intergenic or intronic sequences. However, recently few genes with coding microsatellites were also shown to be mutational targets in MSI-positive cancers and might represent important mutation targets in their pathogenesis. The systematic identification of such genes and the analysis of their mutation frequency in MSI-positive cancers might thus reveal major clues to their functional role in MSI-associated carcinogenesis. We therefore initiated a systematic database search in 33,595 distinctly annotated human genes and identified 17,654 potentially coding mononucleotide repeats (cMNRs) and 2,028 coding dinucleotide repeats (cDNRs), which consist of n > or = 6 and n > or = 4 repeat units, respectively. Expression pattern and mutation frequency of 19 of these genes with the longest repeats were compared between DNA mismatch repair-deficient (MSI(+)) and proficient (MSS) cancer cells. Instability frequencies in these coding microsatellite genes ranged from 10% to 100% in MSI-H tumor cells, whereas MSS cancer cells did not show mutations. RT-PCR analysis further showed that most of the affected genes (10/15) were highly expressed in tumor cells. The approach outlined here identified a new set of genes frequently affected by mutations in MSI-positive tumor cells. It will lead to novel and highly specific diagnostic and therapeutic targets for microsatellite unstable cancers.     

Slip slidin' away: a duodecennial review of targeted genes in mismatch repair deficient colorectal cancer

Roughly 15% of colorectal tumors are characterized by microsatellite instability (MSI), a deficiency caused by defective DNA mismatch repair, which leads to profuse insertions and deletions in microsatellites. Downstream target genes of this defective repair are those prone to exhibit these insertion/deletion mutations in their coding regions and potentially having functional consequences in, and providing a growth advantage for, the cancer cell. This review presents the last 12 years of research on these MSI target genes, systematizing the mutation details of the more than 160 genes identified to date, and includes their mutation frequencies in colorectal and other MSI (e.g., gastric and endometrial) tumors. Functional aspects of certain targets and the target gene concept itself are also discussed, as is the comparative wealth of potential target genes assessed by scanning the coding sequences of the human genome for mononucleotide repeats--yet to be investigated.     

Frequent alteration of DNA damage signalling and repair pathways in human colorectal cancers with microsatellite instability

Accumulation of frameshift mutations at genes containing coding mononucleotide repeats is thought to be the major molecular mechanism by which mismatch repair-deficient cells accumulate functional alterations. These mutations resulting from microsatellite instability (MSI) can affect genes involved in pathways with a putative oncogenic role, but may also arise in genes without any expected role in MSI carcinogenesis because of the high mutation background of these tumours. We here screened 39 MSI colorectal tumours for the presence of mutations in 25 genes involved in DNA damage signalling and repair pathways. Using a maximum likelihood statistical method, these genes were divided into two different groups that differed significantly in their mutation frequencies, and likely represent mutations that do or do not provide selective pressure during MSI tumour progression. Interestingly, the so-called real-target mutational events were found to be distributed among genes involved in different functional pathways of the DNA metabolism, for example, DNA damage signalling (DNA-PKcs, ATR), double-strand break (DSB) repair (DNA-PKcs, RAD50), mismatch repair (MSH3, MSH6, MBD4) and replication (POLD3). In particular, mutations in MRE11 and/or RAD50 were observed in the vast majority of the tumours and resulted in the concomitant loss of immunohistochemical expression of both proteins. These data might explain why MSI colorectal cancers (CRC) behave differently in response to a wide variety of chemotherapeutic agents, notably those targeting DNA. More generally, they give further insights into how MSI leads to functional changes with synergistic effects in oncogenic pathways.     

Oncogenic pathway of sporadic colorectal cancer with novel germline missense mutations in the hMSH2 gene

The deficiency of the DNA mismatch repair (MMR) system is involved in tumorigenesis of either familial or sporadic colorectal cancers showing microsatellite instability (MSI). To investigate the involvement of the mutated hMSH2 gene in carcinogenesis, we searched for alteration of the gene in 15 MSI tumors of Japanese patients with sporadic colorectal cancer by a polymerase chain reaction (PCR)-single strand conformation polymorphism (SSCP) and DNA sequencing analyses. We found 20 alterations including 7 novel mutations, 6 germline and one somatic. To assume an oncogenic pathway of tumor of two patients carrying germline missense mutations, G40S located in an evolutionarily conserved amino-terminal motif and Y619C in a domain interacting with either hMSH3 or hMSH6, somatic mutations in 9 target genes of the MMR defect and in the p53 and K-ras genes and loss of heterozygosity (LOH) at the hMLH1 and p53 gene loci were then studied. In the tumor carrying G40S, other somatic hMSH2 mutations, G203R and 687delA in the (A)(7) repeat, and 5 one-bp deletions in the target genes were found, while no mutation in the p53 and K-ras genes. These results indicate that G40S may affect the hMSH2 function and the tumor may be developed by a typical MSI pathway. In another tumor with Y619C, LOH at the hMLH1 gene locus, no mutation in MMR target genes, and two-hit inactivation of the p53 gene were detected. This MSI tumor seems to be developed by another than MSI pathway. These results indicate that there are different oncogenic pathways in the MSI sporadic colorectal cancers with germline missense mutations in the hMSH2 gene. We conclude that familial colorectal cancer-suspected cases exist in a small population of sporadic colorectal cancers.     

Microsatellite instability of selective target genes in HNPCC-associated colon adenomas

Microsatellite instability (MSI) occurs in most hereditary nonpolyposis colorectal cancers (HNPCC) and less frequently in sporadic tumors as the result of DNA mismatch repair (MMR) deficiency. Instability at coding microsatellites (cMS) in specific target genes causes frameshift mutations and functional inactivation of affected proteins, thereby providing a selective growth advantage to MMR deficient cells. At present, little is known about Selective Target Gene frameshift mutations in preneoplastic lesions. In this study, we examined 30 HNPCC-associated MSI-H colorectal adenomas of different grades of dysplasia for frameshift mutations in 26 cMS-bearing genes, which, according to our previous model, represent Selective Target genes of MSI. About 30% (8/26) of these genes showed a high mutation frequency (> or =50%) in colorectal adenomas, similar to the frequencies reported for colorectal carcinomas. Mutations in one gene (PTHL3) occurred significantly less frequently in MSI adenomas compared to published mutation rates in MSI carcinomas (36.0 vs 85.7%, P=0.023). Biallelic inactivation was observed in nine genes, thus emphasizing the functional impact of cMS instability on MSI tumorigenesis. Some genes showed a high frequency of frameshift mutations already at early stages of MSI colorectal tumorigenesis that increased with grade of dysplasia and transition to carcinoma. These include known Target Genes like BAX and TGFBR2, as well as three novel candidates, MACS, NDUFC2, and TAF1B. Overall, we have identified genes of potential relevance for the initiation and progression of MSI tumorigenesis, thus representing promising candidates for novel diagnostic and therapeutic approaches directed towards MMR-deficient tumors.     

Microsatellite instability is a predictive factor of the tumor response to irinotecan in patients with advanced colorectal cancer

The aim of our study was to assess the relationship between colorectal tumor responsiveness to irinotecan and microsatellite instability (MSI), a feature of colorectal tumors with DNA mismatch repair defect. Seventy-two patients with metastatic colorectal cancer were included in our retrospective study. A complete response to irinotecan was observed in 1 patient and a partial response in 10 patients, whereas 61 patients did not respond to this treatment. We analyzed the protein expression of hMLH1, hMSH2, and BAX by immunohistochemistry, determined the MSI phenotype, and looked for mutations in the coding repeats located in the transforming growth factor beta-RII, BAX, hMSH3, and hMSH6 genes. All 44 tumors analyzed expressed detectable levels of hMLH1; 1 tumor lacked hMSH2 staining, whereas 4 tumors showed a marked decrease in BAX expression. A better response to irinotecan was observed in the patients whose tumors have lost BAX expression (P < 0.001). Among the 7 tumors that displayed a MSI-H phenotype, 4 responded to irinotecan, whereas only 7 of the 65 MSI-L/ microsatellite stable tumors did (P = 0.009). Seven of the 72 tumors had inactivating mutations in the coding repeats of the target genes. Three tumors displayed a mutation in the poly-A10 tract of the transforming growth factor beta-RII gene, associated with a 1-bp deletion in the poly-A8 tract of hMSH3 in one tumor and with a 1-bp deletion in the poly-G8 tract of BAX in another. Four tumors displayed mutations in the poly-G8 repeat of BAX, whereas 2 mutations in hMSH6 and hMSH3 were characterized. Among the 7 tumors with mutations in these target genes, 5 responded to irinotecan, whereas only 6 of the other 65 tumors did (P < 0.001), indicating that MSI-driven inactivation of target genes modifies tumor chemosensitivity. Our observations allowed us to define the first useful predictive criteria for irinotecan response in patients with colorectal cancer.     

Frameshift peptide-derived T-cell epitopes: a source of novel tumor-specific antigens

Microsatellite instability (MSI) caused by defective DNA mismatch repair (MMR) is a hallmark of hereditary nonpolyposis colorectal cancers (HNPCC) but also occurs in about 15% of sporadic tumors. If instability affects microsatellites in coding regions, translational frameshifts lead to truncated proteins often marked by unique frameshift peptide sequences at their C-terminus. Since MSI tumors show enhanced lymphocytic infiltration and our previous analysis identified numerous coding mono- and dinucleotide repeat-bearing candidate genes as targets of genetic instability, we examined the role of frameshift peptides in triggering cellular immune responses. Using peptide pulsed autologous CD40-activated B cells, we have generated cytotoxic T lymphocytes (CTL) that specifically recognize HLA-A2.1-restricted peptides derived from frameshift sequences. Among 16 frameshift peptides predicted from mutations in 8 different genes, 3 peptides conferred specific lysis of target cells exogenously loaded with cognate peptide. One peptide derived from a (-1) frameshift mutation in the TGFbetaIIR gene gave rise to a CTL bulk culture capable of lysing the MSI colorectal cancer cell line HCT116 carrying this frameshift mutation. Given the huge number of human coding microsatellites and assuming only a fraction being mutated and encoding immunologically relevant peptides in MSI tumors, frameshift protein sequences represent a novel subclass of tumor-specific antigens. It is tempting to speculate that a frameshift peptide-directed vaccination approach not only could offer new treatment modalities for existing MSI tumors but also might benefit asymptomatic at-risk individuals in HNPCC families by a prophylactic vaccination strategy.     

Microsatellite instability and mutation analysis of candidate genes in urothelial cell carcinomas of upper urinary tract

A subset of upper urinary tract urothelial cell carcinomas (UUC), arising sporadically or as a manifestation of hereditary non-polyposis colorectal cancer, displays microsatellite instability (MSI). MSI tumours are characterized by defective mismatch repair and accumulation of frameshift mutations in numerous genes harbouring repeats in their coding sequences. We have evaluated the incidence of MSI in UUC and the intratumoral distribution of mutations in 13 candidate target genes. A total of 58 unselected UUC were screened for MSI using the panel of five mononucleotide markers recently recommended by the National Cancer Institute for a precise MSI assessment. Four tumours displayed MSI (7%), among which at least three had alterations in the genes MSH3, BAX, MRE11, RAD50. Mutations in genes involved in key cellular pathways (ATR, DNA-PKcs, MBD4, TCF-4, MSH6, and BLM) were further detected. BAX and MRE11 mutations tend to present homogeneously within the three MSI UUC. Immunohistochemistry (MLH1, MSH2, MSH6) showed that loss of mismatch repair protein expression occurred in all MSI UUC defining the gene defect and that MRE11 and RAD50 mutations were associated with their concomitant loss expression. In conclusion, MSI UUC represent a small proportion of UUC in which BAX and MRE11 mutations are frequent and may play a role early in UUC tumorigenesis.     

Clinicopathologic characteristics related to the high variability of coding mononucleotide repeat sequences in tumors with high-microsatellite instability

Frameshift mutation at coding mononucleotide repeat sequences are common in tumors with microsatellite instability (MSI-H), but the incidences are different among the target genes. We analyzed the mutational profiles of 12 known target genes containing polydeoxyadenosine repeats in their coding sequences in 39 MSI-H colorectal carcinomas and 40 MSI-H gastric carcinomas by using polymerase chain reaction and sequencing, and compared the results with the clinicopathologic characteristics. Frameshift mutations of target genes in the MSI-H colorectal and gastric carcinomas are increased according to the length of the polydeoxyadenosine repeats in the target genes. The mean mutational rates of MSI-H colorectal carcinomas and MSI-H gastric carcinomas were 2.03 and 1.95 in the 4 genes containing (A)10 repeats, 1.23 and 0.73 in the 4 genes with (A)9 repeats and 0.61 and 0.48 in the 4 genes containing (A)8 repeats, respectively (p<0.001). Among the evaluated clinicopathologic findings, intestinal type gastric carcinomas had more frameshift mutations than the diffuse type carcinomas (3.5 vs. 1.9, p=0.01). These findings suggest that mutational rates of the target genes in MSI-H tumors are diverse, and higher mutational rates are related to the length of mononucleotide repeat sequences of the target genes and histologic type of tumors.     

Mononucleotide repeats BAT-26 and BAT-25 accurately detect MSI-H tumors and predict tumor content: implications for population screening

Tumors with a defective DNA mismatch repair system (MSI-H tumors) have distinct molecular and clinicopathologic profiles compared with mismatch repair-proficient tumors and are associated with a relatively favorable prognosis. There is evidence to suggest that colorectal cancer patients with MSI-H tumors respond differently to adjuvant chemotherapy. Determination of MSI status also has clinical application for assisting in the diagnosis of suspected hereditary nonpolyposis colorectal cancer cases. For these reasons, it is becoming increasingly apparent that testing for MSI should be conducted routinely in human cancer types that frequently present with such a phenotype. BAT-26 and BAT-25 are mononucleotide repeats that are widely used to establish the MSI status of human tumors. We show here that their allelic size profiles provide an estimate of the percentage of contaminating normal cells in MSI-H tumors. These markers are sensitive enough to detect instability when the tumor cell content of a sample is as low as 5-10%. MSI-H tumors contain mutations in coding repeats within genes known to be targets for instability. In cases with low tumor cell content, no mutations in any of 9 coding repeats were detected. However, when these samples were enriched for tumor cells, mutations were detected in the same target genes. Thus, BAT-26 and BAT-25 markers accurately identify MSI-H tumors without prior need for enrichment for tumor cells and indicate which samples require further purification before screening for mutations in target genes for instability. Our results have implications for large-scale screening of cancer patients to determine MSI-H status and prognosis.     

Genes involved in DNA repair are mutational targets in endometrial cancers with microsatellite instability

Microsatellite instability (MSI) is observed in a subset of endometrial cancers (ECs) and is attributed to defects in mismatch repair. Mismatch repair deficiency allows for accumulation of mutations in the coding repeats of key target genes, which may be involved in the initiation and progression of MSI+ EC. We examined genes implicated in DNA repair pathways in 38 MSI-high (MSI-H), 10 MSI-low, 25 microsatellite stable ECs, and a selected panel of associated premalignant hyperplasias. Genetic alterations were correlated to histopathological data, including tumor grade and stage. Somatic frameshift mutations were observed in hMLH3, hMSH3, hMSH6, CHK1, and BAX genes in MSI-H endometrial hyperplasias and cancers, whereas mutations in ATR and CDC25C were observed only in MSI-H ECs. Increased mutation frequency in DNA damage response pathway genes including ATR, CHK1, and BAX demonstrated a significant trend with advancing tumor grade (P < 0.05). Our observations of the same mutations at short coding mononucleotide repeats in both premalignant lesions and tumors and association of increased frequency of mutation accumulation with advancing tumor grade suggest that these alterations may play a role in the development and progression of MSI+ EC.     

Infrequent frameshift mutations in the simple repeat sequences of hMLH3 in hereditary nonpolyposis colorectal cancers

BACKGROUND: A recently identified mismatch repair gene, hMLH3, contains two simple repeat sequence regions, (A)9 and (A)8, in its coding region. To clarify the role of hMLH3 in hereditary nonpolyposis colorectal cancer (HNPCC), we searched for hMLH3 somatic and germline mutations, particularly in the repeat regions, in 41 HNPCC patient cells. METHODS: We analyzed the hMLH3 (A)9 and (A)8 repeats in 27 colorectal cancers with microsatellite instability (MSI) as well as in normal cells from 41 HNPCC patients by means of polymerase chain reaction-single-strand conformation polymorphism. hMSH3 (A)8 and hMSH6 (C)8 repeats were also examined in these cancers. RESULTS: Frameshift mutations in the hMLH3 (A)9 repeat were observed in 4/27 (14.8%) cancers with MSI, all of which showed the severe MSI phenotype. No mutations in the (A)8 repeat were found in any case. The mutation frequency of the hMLH3 (A)9 repeat was similar to that of the hMSH6 (C)8 repeat (5/26, 19.2%), but was significantly lower than that of the hMSH3 (A)8 repeat (16/27, 59.3%) (P < 0.001). All four cancers with hMLH3 mutations exhibited germline hMSH2 and/or somatic hMSH3 mutations. No germline mutation in the hMLH3 (A)9 or (A)8 repeat was detected in normal cells from the 41 HNPCC patients. CONCLUSION: hMLH3 mutations were infrequently observed in HNPCC cancers with MSI and they may be secondary to other mismatch repair gene mutations. Hence hMLH3 may only play a small role in HNPCC tumorigenesis.     

Mutations of an intronic repeat induce impaired MRE11 expression in primary human cancer with microsatellite instability

Frequent mutations of coding nucleotide repeats are thought to contribute significantly to carcinogenesis associated with microsatellite instability (MSI). We have shown that shortening of the poly(T)11 within the polypyrimidine stretch/accessory splicing signal of human MRE11 leads to the reduced expression and functional impairment of the MRE11/NBS1/RAD50 complex. This mutation was selectively found in mismatch repair (MMR) defective cell lines and potentially identifies MRE11 as a novel target for MSI. Here, we examined 70 microsatellite unstable primary human cancers and we report that MRE11 mutations occur in 83.7 and 50% of the colorectal and endometrial cancers, respectively. In the colorectal cancer series, mutated MRE11 is more frequently associated with advanced age at diagnosis and A/B stages. Biallelic mutations were present in 38.8% of the cases and more frequently associated with lower (G1/G2) grade tumors. Impaired MRE11 expression was prevalent in primary colorectal tumors with larger and biallelic shortening of the poly(T)11. Immunohistochemistry confirmed the impaired MRE11 expression and revealed NBS1-defective expression in MRE11 mutated cancers. Together with the observation that perturbation of the MRE11/NBS1/RAD50 complex predisposes to cancer, our work highlights MRE11 as a new common target in the MMR deficient tumorigenesis and suggests its role in colorectal carcinogenesis.     

Frameshift mutations at coding mononucleotide repeats of the hRAD50 gene in gastrointestinal carcinomas with microsatellite instability

Microsatellite instability (MSI) and frameshift mutations in genes containing nucleotide repeats have been reported in a subset of colorectal and gastric carcinomas. This study describes the analysis of MSI-positive colorectal (39 cases) and gastric carcinomas (36 cases) for the presence of frameshift mutations of the six genes known to be involved in DNA repair and containing mononucleotide repeats in their coding region. Our mutational study of the 75 MSI-positive tumors revealed frequent mutations in hRAD50 (23 cases, 31%), BLM (16 cases, 21%), and hMSH6 (16 cases, 21%); rare mutations in BRCA1 (1 case, 1%) and ATM (3 cases, 4%); and no mutation in NBS1. In contrast, no frameshift mutation was found in 60 MSI-negative colorectal and gastric carcinomas. The mutation of hRAD50, a gene that is involved in the response to cellular DNA damage and forms a complex with hMRE11 and NBS1, has not been reported previously. Our results suggest that frameshift mutations of hRAD50, BLM, and hMSH6 are selected and play a role in the tumorigenesis of colorectal and gastric carcinomas with MSI. The MSI targeting of the hRAD50 and BLM genes represents an additional link between MSI and DNA repair because alteration of these genes could accelerate defective DNA repair.     

PTEN gene mutations in colorectal cancers displaying microsatellite instability.

To determine the relationship between the mutation of the PTEN gene and genomic instability in human colorectal cancer, we screened the PTEN gene in 32 colorectal cancers (eight cell lines and 24 tissues) displaying microsatellite instability (MSI) and 32 colorectal cancers (six cell lines and 26 tissues) displaying microsatellite stability (MSS). Of 64 samples, six frameshift mutations were identified in six MSI colorectal cancers (two cell lines and four tumor tissues) but not in MSS colorectal cancers. Of the six MSI colorectal cancers containing PTEN mutation, two case (one cell line and one tumor tissue) showed biallelic mutation of PTEN. Furthermore, to compare the frequency of PTEN mutation with that of other MSI target genes, the mononucleotide repeat sequences of TGF-betaRII, BAX, IGFIIR, hMSH6 and hMSH3 were analyzed. The frequencies of frameshift mutation were revealed 78% in TGF-betaRII, 56% in BAX, 46.9% in hMSH3, 37.5% in hMSH6, 21.9% in IGFIIR, and 18.8% in PTEN. These results suggest that the PTEN gene is a target of genomic instability in MSI colorectal tumorigenesis.