UMLS:C0596263 - FACTA Search

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Query: UMLS:C0596263 (carcinogenesis)
64,820 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The instability of short repetitive sequences in tumor DNA can result from defective repair of replication errors due to mutations in any of several genes required for mismatch repair. Understanding this repair pathway and how defects lead to cancer is being facilitated by genetic and biochemical studies of tumor cell lines. In the present study, we describe the mismatch repair status of extracts of 22 tumor cell lines derived from several tissue types. Ten were found to be defective in strand-specific mismatch repair, including cell lines from tumors of the colon, ovary, endometrium, and prostate. The repair defects were independent of whether the signal for strand specificity, a nick, was 5' or 3' to the mismatch. All 10 defective cell lines exhibited microsatellite instability. Repair activity was restored to 9 of these 10 extracts by adding a second defective extract made from cell lines having known mutations in either the hMSH2 or hMLH1 genes. Subsequent analyses revealed mutations in hMSH2 (4 lines) and hMLH1 (5 lines) that could explain the observed microsatellite instability and repair defects. Overall, this study strengthens the correlation between microsatellite instability and defective mismatch repair and the suggestion that diminuition in mismatch repair activity is a step in carcinogenesis common to several types of cancer. It also provides an extensive panel of repair-proficient and repair-deficient cell lines for future studies of mismatch repair.
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PMID:Microsatellite instability, mismatch repair deficiency, and genetic defects in human cancer cell lines. 852 94

DNA instability, reflected in altered patterns of short tandem repeat sequences (microsatellites) in dividing cells, has been described in hereditary non-polyposis colon cancer (HNPCC) and in other tumor types. Ovarian cancer (OC), although most often a sporadic cancer, can recur, with HNPCC, as part of the Lynch cancer family syndrome. In an investigation of microsatellite instability (MIN) in 90 OC cases, we found MIN in 3/28 (11%) OC cases with, and 8/62 (13%) without, a family history of cancer. For 2/3 MIN+ OC cases with family cancer history consistent with the Lynch cancer family syndrome, we found additional bands in the microsatellite patterns in tumor versus normal tissue (HNPCC-type of MIN), but no germline mutations in two DNA mismatch repair genes, hMSH2 and hMLH1. In 7/8 MIN+ sporadic OC cases distinct MIN patterns not commonly reported in HNPCC were found. These are characterized by partial or total band shifting, leading to fewer bands and/or changes in the intensity of individual bands restricted to the tumor. In only one case was a germline change in hMSH2 or hMLH1 identified: this was subsequently found to be a polymorphism. An apparent hMLH1 somatic change confined to the tumor was found in another case. The fact that we found no germline pathologic mutations in hMSH2 and hMLH1 (predominant sites of mutation in HNPCC) in MIN+ OC cases, suggests that the genetic basis of MIN in OC can be different from that in HNPCC; our finding that distinct microsatellite banding patterns largely distinguish sporadic from familial OC, may reflect the involvement of different DNA repair genes in MIN in individual OC cases.
Carcinogenesis 1996 Sep
PMID:Microsatellite instability differences between familial and sporadic ovarian cancers. 882 98

Histological type, malignancy grade, and tumor stage are among the most important parameters predicting outcome in cancer patients. Making use of immunocytochemistry as well as polymerase chain reaction-based techniques the demonstration of micrometastatic tumor spread, for example, into bone marrow, lymph nodes, and peritoneal cavity, is a new staging parameter of prognostic significance. In contrast, the prognostic value of different proliferation markers such as Ki67 (Mib 1), PCNA, and AgNOR has not yet been unequivocally established. A series of genetic change has been described in the development of cancer. In general, these changes seem to be of predictive value within defined tumor stages and it might be helpful to determine several genetic lesions within one tumor. Very recently a new mechanism of carcinogenesis closely related to the hereditary nonpolyposis cancer syndrome (HNPCC) was detected. Due to mutations in mismatch repair genes (hMSH 2, hMLH1, hPMS1,2) instabilities in simple repetitive genomic sequences occur, which are the genetic hallmark of most HNPCC tumors. This opens a new field to cancer prevention.
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PMID:Prognostic significance of molecular biological and immunohistological parameters in gastrointestinal carcinomas. 889 36

The clinical and genetic studies have been very few on a familial predisposition to gastric cancers. We defined the criteria as familial gastric cancer (FGC) in which at least three relatives in two generations have gastric cancers, with one of the relatives having been diagnosed at less than 50 years of age. Other hereditary tumors, such as cancer family syndrome of hereditary nonpolyposis colorectal cancer(HNPCC), should be excluded. To clarify the carcinogenesis in FGC, we examined genetic alterations in six cancers from four FGC kindreds. Four (67%) cancers showed replication error, indicating that microsatellite instability is highly associated with not only HNPCC but also FGC. However, no germline mutation was found in the whole coding sequences of hMSH2 and hMTH1, or in the conservative regions of hMLH1 in any patients. Only few alterations were found at the small repeated sequences in the transforming growth factor-beta type II receptor gene in FGC tumor DNA. These results indicate that the carcinogenetic process of FGC may be different from that of HNPCC.
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PMID:[Analyses of mutator gene mutations in familial gastric cancers]. 892 Jun 67

Spontaneous mutation rates at the hypoxanthine-guanine phosphoribosyl transferase (hprt) locus were measured in human cancer cell lines defective in the mismatch repair (MMR) genes hMLH1, hPMS2, or GTBP, as well as in a cell line carrying mutations in both hMLH1 and hPMS2. The mutation rate was determined by quantitating mutant frequency increases within a single culture as a function of cell division. These MMR-deficient cell lines exhibited a 50- to 750-fold increase in mutation rate relative to a MMR-proficient cancer cell line. From lowest to highest, the spontaneous mutation rates relative to the MMR-gene defects studied here are as follows: hMLH1- < GTBP- < hPMS2- < hMLH1- / hPMS2-. In addition, a cell line in which MMR was restored by chromosome transfer exhibited a mutation rate 12-fold below the MMR-deficient parental cell line. These data support the notion that MMR plays an important role in controlling the rate of spontaneous mutation and suggest that different MMR-gene defects may vary in their ability to repair different types of DNA mismatches, thus leading to measurable quantitative differences in spontaneous mutagenesis. Furthermore, a difference in mutation rates was observed between a hPMS2-defective cell line (3.1 x 10(-5) mutations/cell/generation) and two hMLH1-defective cell lines (4.0 x 10(-6) and 7.3 x 10(-6) mutations/cell/generation). Assuming the hPMS2- and hMLH1-gene products only function in the proposed hMutL alpha heterodimer, then defects in either gene should yield comparable mutation rates. These data suggest that hPMS2 plays a critical role in MMR, while additional hMLH1 homologues or hPMS2 alone may function to partially complement defects in hMLH1.
Carcinogenesis 1997 Jan
PMID:Mutation rate at the hprt locus in human cancer cell lines with specific mismatch repair-gene defects. 905 82

A genome-wide instability has been found in almost all analyzed malignant tumors from patients with hereditary non-polyposis colorectal cancer (HNPCC), and in a subgroup of sporadic (non-inherited) cancers of the same type. This mutator phenotype was initially seen as novel alleles at microsatellite loci (a family of repetitive DNA sequences) and was shown to be caused by mutations in the highly conserved mismatch repair genes. Mutations have been found in each of four of these human genes: hMSH2, hMLH1, hPMS1 and hPMS2, in the germline of HNPCC patients and in their tumors, as well as in sporadic tumors. These recent discoveries provide new molecular diagnostic tools for the detection of patients at high risk of developing carcinomas of the large bowel and other HNPCC-related tumors. Ongoing international research is progressively solving many of the unanswered questions at the genotypic and phenotypic levels of this newly identified mechanism in carcinogenesis.
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PMID:Microsatellite instability in human solid tumors. 906 3

Spectra of spontaneous mutations at the hypoxanthine-guanine phosphoribosyltransferase (hprt) locus in colon carcinoma cell lines HCT116 and HCT-15 deficient in mismatch repair and displaying mutator phenotypes were determined. HCT116 and HCT-15 cells, respectively, harbour a mutation in the mismatch repair gene hMLH1 and GTBP. The mutation frequency at the hprt locus in both cell lines was elevated by about two orders, but the microsatellite instability in HCT116 cells was one order higher than in HCT-15 cells. Except for one mutant of HCT-15, all the mutations (114/115) were point mutations; base substitutions of various types and frameshifts (deletions/insertions of less than a few bases, predominantly of +/-1 bp). Base substitutions (57%) and frameshifts (43%) occurred at a comparable rate in HCT116, whereas base substitutions (92%) were the major mutational events in HCT-15. Most frameshifts in HCT116 occurred at sites of monotonous or short tandem repeating sequences, and two of these sites, where there was a run of six Gs and four As, were hot spots. Three hot spot sites of base substitutions were found in HCT-15; two of them at splice acceptor sites, the other at the CpG site shared with HCT116. The distinct mutation spectra of the HCT116 and HCT-15 cell lines may reflect functional differences in the hMLH1 and GTBP gene products in mismatch repair. The gene product GTBP may be involved in the preferential repair of base mismatches, and MLH1 in the repair of both base mismatches and deletions/insertions of less than a few bases. These results suggest that mismatch repair deficiency affects the microsatellite stability as widely reported in colorectal tumour cells, but that it may not severely affect chromosome integrity as the karyotypes of these tumour cells are, unlike other tumour cells, relatively stable.
Carcinogenesis 1997 Jun
PMID:Spectra of spontaneous mutations at the hprt locus in colorectal carcinoma cell lines defective in mismatch repair. 921 93

Alterations of the length of simple repetitive genomic sequences (microsatellite instability, MSI) characterize a distinct mechanism of colorectal carcinogenesis. Such MSI has been found to be associated with hereditary nonpolyposis colorectal cancer (HNPCC) that involves mutation of the human mismatch repair genes hMSH2 and hMLH1 as well as many sporadic cancers of most tissue types. Although the study of MSI status is a useful tool for HNPCC screening and for the determination of tumor prognosis in sporadic cases of colorectal cancer, the reliability of MSI diagnosis is still a subject of debate. Here we have examined 58 primary colorectal tumors (selected from a cohort of 200) using 31 microsatellite markers that comprised the most frequent simple repeat types. The expression of the hMSH2 and hMLH1 mismatch repair proteins was studied by immunohistochemistry, and most patients were surveyed for at least 2 years. Reproducibility of gel interpretation, as well as diagnostic sensitivity and specificity of the MSI status, were determined. We found that unambiguous determination of band shifts as well as MSI diagnosis were closely related to the type of the marker repeat and that MSI could be subdivided into "high" MSI (>20% unstable loci), "low" MSI (<10% unstable loci), and microsatellite stable (0% unstable loci). One-half of the patients with high MSI tumors (n = 8) fulfilled either the Amsterdam criteria (n = 4), had at least one relative with HNPCC-related carcinoma (n = 2), or were diagnosed with colorectal cancer at an age below 45 years (n = 2). Fourteen of the 15 high MSI tumors had lost either hMSH2 (n = 8) or hMLH1 (n = 6) protein expression. In contrast, all of the low MSI tumors and the MSI-negative tumors displayed normal expression of hMSH2 and hMLH1. These studies provide a clear recommendation for the uniform use of a panel of 10 microsatellites and a definition of at least 40% instability (using these defined marker loci) in the diagnostic analysis of MSI.
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PMID:Diagnostic microsatellite instability: definition and correlation with mismatch repair protein expression. 935 36

Colorectal cancer is a significant cause of morbidity and mortality in Western populations. This cancer develops as a result of the pathologic transformation of normal colonic epithelium to an adenomatous polyp and ultimately an invasive cancer. The multistep progression requires years and possibly decades and is accompanied by a number of recently characterized genetic alterations. Mutations in two classes of genes, tumor-suppressor genes and proto-oncogenes, are thought to impart a proliferative advantage to cells and contribute to development of the malignant phenotype. Inactivating mutations of both copies (alleles) of the adenomatous polyposis coli (APC) gene--a tumor-suppressor gene on chromosome 5q--mark one of the earliest events in colorectal carcinogenesis. Germline mutation of the APC gene and subsequent somatic mutation of the second APC allele cause the inherited familial adenomatous polyposis syndrome. This syndrome is characterized by the presence of hundreds to thousands of colonic adenomatous polyps. If these polyps are left untreated, colorectal cancer develops. Mutation leading to dysregulation of the K-ras protooncogene is also thought to be an early event in colon cancer formation. Conversely, loss of heterozygosity on the long arm of chromosome 18 (18q) occurs later in the sequence of development from adenoma to carcinoma, and this mutation may predict poor prognosis. Loss of the 18q region is thought to contribute to inactivation of the DCC tumor-suppressor gene. More recent evidence suggests that other tumor-suppressor genes--DPC4 and MADR2 of the transforming growth factor beta (TGF-beta) pathway--also may be inactivated by allelic loss on chromosome 18q. In addition, mutation of the tumor-suppressor gene p53 on chromosome 17p appears to be a late phenomenon in colorectal carcinogenesis. This mutation may allow the growing tumor with multiple genetic alterations to evade cell cycle arrest and apoptosis. Neoplastic progression is probably accompanied by additional, undiscovered genetic events, which are indicated by allelic loss on chromosomes 1q, 4p, 6p, 8p, 9q, and 22q in 25% to 50% of colorectal cancers. Recently, a third class of genes, DNA repair genes, has been implicated in tumorigenesis of colorectal cancer. Study findings suggest that DNA mismatch repair deficiency, due to germline mutation of the hMSH2, hMLH1, hPMS1, or hPMS2 genes, contributes to development of hereditary nonpolyposis colorectal cancer. The majority of tumors in patients with this disease and 10% to 15% of sporadic colon cancers display microsatellite instability, also know as the replication error positive (RER+) phenotype. This molecular marker of DNA mismatch repair deficiency may predict improved patient survival. Mismatch repair deficiency is thought to lead to mutation and inactivation of the genes for type II TGF-beta receptor and insulin-like growth-factor II receptor. Individuals from families at high risk for colorectal cancer (hereditary nonpolyposis colorectal cancer or familial adenomatous polyposis) should be offered genetic counseling, predictive molecular testing, and when indicated, endoscopic surveillance at appropriate intervals. Recent studies have examined colorectal carcinogenesis in the light of other genetic processes. Telomerase activity is present in almost all cancers, including colorectal cancer, but rarely in benign lesions such as adenomatous polyps or normal tissues. Furthermore, genetic alterations that allow transformed colorectal epithelial cells to escape cell cycle arrest or apoptosis also have been recognized. In addition, hypomethylation or hypermethylation of DNA sequences may alter gene expression without nucleic acid mutation.
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PMID:Molecular biology of colorectal cancer. 943 4

Hereditary nonpolyposis colorectal cancer (HNPCC), also termed Lynch syndrome, was originally called cancer family syndrome. Historically, in 1913 Aldred Warthin, a pathologist, published a family, now known as Family G, which had features of HNPCC. It was first delineated as a hereditary cancer syndrome in the mid-1960s by Lynch. There was an apparent autosomal dominant mode of inheritance of colorectal cancer and certain integral cancers, the most prominent of which was endometrial carcinoma. Prior to the discovery in 1993 and 1994 of genes (hMSH2, hMLH1, hPMS1, hPMS2) known as mis-match repair genes or mutator genes, the diagnosis of HNPCC rested exclusively upon evaluation of clinical findings in concert with a well-documented and extended pedigree. Thus, this disorder has evolved from a medical curiosity into a clinical syndrome wherein molecular biologists provided proof of its hereditary status. These discoveries should aid in elucidating its pathogenesis and carcinogenesis and in the next decade we likely will learn more about chemoprevention and surgical prophylaxis of HNPCC.
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PMID:Molecular genetics and clinical-pathology features of hereditary nonpolyposis colorectal carcinoma (Lynch syndrome): historical journey from pedigree anecdote to molecular genetic confirmation. 949 83

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