UMLS:C0025202 - FACTA Search

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Query: UMLS:C0025202 (melanoma)
69,561 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have cloned, sequenced, and characterized the RNA expression properties of a fish CDKN2 gene from Xiphophorus helleri and X. maculatus. This gene, termed CDKN2X, shows a high degree of amino acid sequence similarity to members of the mammalian CDKN2 gene family, which includes the tumor suppressor loci CDKN2A (P16) and CDKN2B (P15). Comparative sequence analysis suggests that fish CDKN2X is similarly related to all four mammalian gene family members, and may represent a descendant of an ancestral prototypic CDKN2 gene. CDKN2X was mapped to a region on autosomal Xiphophorus linkage group V (LG V) known to contain the DIFF gene that acts as a tumor suppressor of melanoma formation in X. helleri/X. maculatus backcross hybrids. Thus, CDKN2X may be a candidate for the tumor suppressor DIFF gene. Here we have sequenced CDKN2X in both Xiphophorus species and have characterized its expression in normal and melanotic tissues within control and backcross hybrid fish. A simultaneous expressional analysis of the Xmrk-2 tyrosine kinase receptor gene, which is strongly implicated in melanomagenesis in this system, was also performed. RT - PCR analyses revealed that both genes were highly expressed in melanomas. For CDKN2X, this result contrasts numerous findings in human tumors including human melanoma in which either CDKN2A (P16) deactivation or LOH was observed.
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PMID:Comparative structure and characterization of a CDKN2 gene in a Xiphophorus fish melanoma model. 1049 Aug 45

Inherited mutations in the CDKN2A/INK4a/MTS1 tumour suppressor gene on chromosome 9p21 are associated with familial predisposition to melanoma and other tumour types. Nonsense and missense mutations are also found in a variety of sporadic cancers, and over 140 sequence variants have already been recorded in the literature. In assessing the relevance of these variants and for counselling members of affected families, it is important to distinguish inactivating mutations from harmless polymorphisms. Existing functional assays have frequently reached conflicting conclusions and no single test appears adequate. Here we evaluate a number of alternatives including a novel assay based on retroviral delivery of p16INK4a cDNAs into human diploid fibroblasts. Among the 17 sequence variants analysed, three distinct categories can be distinguished: those that abrogate the binding of p16INK4a to CDK4 and CDK6, those that alter the properties of the protein without preventing it from interacting with CDKs, and those that have no discernible effect on protein function. These distinctions can be rationalized by considering the impact of the amino acid changes on the three-dimensional structure of the protein.
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PMID:Functional evaluation of tumour-specific variants of p16INK4a/CDKN2A: correlation with protein structure information. 1049 96

Germline mutations impairing the p16(INK4)-function have previously been demonstrated to be responsible for genetic predisposition in at least one half of melanoma-prone kindreds of North European origin. Familial melanoma kindreds have also been found to present an increased risk of pancreatic cancer and other cancers, but results relative to more common neoplasias incidence, in particular, are heterogeneous. We report here a clinical-epidemiological study, including the presence of additional neoplasias, in 14 apparently unrelated kindreds coming from a small geographic region of Northern Italy (Liguria), having therefore lived for generations in similar environmental conditions. We identified the common p16 missense mutation (Gly101Trp) reported in several previously studied kindreds, in 7 of 14 families, whereas the remaining 7 families had no detectable mutations in the coding region of p16 gene. Median age at diagnosis and other melanoma features were studied. When compared with the expected figures, based on regional incidence rates, a significant excess of pancreatic cancer, with 4 cases diagnosed, and of breast cancer, with 7 cases, was observed. The 7 families without apparent CDKN2A involvement were also negative for hot-spot exon 2 mutation of CDK4. Environmental factors do not appear to play a role in the excess of non-melanoma neoplasia in our families, as somewhat substantiated by the control group, composed of spouses and members of non-affected branches; they do not reveal any increased cancer incidence compared with the general population. Furthermore, given the proven significance of interaction between the melanoma susceptibility gene and the propensity to sunburns and other environmental risk factors, our results, obtained from a small but homogeneous sample, may have important implications for further risk assessment studies.
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PMID:Characterization of ligurian melanoma families and risk of occurrence of other neoplasia. 1050 77

The most common hereditary melanoma susceptibility disorder is the familial atypical multiple mole-melanoma (FAMMM) syndrome. FAMMM is regarded as an ideal natural model to study the very complex pathologic mechanism of melanoma. In 1994, cloning of the melanoma susceptibility gene CDKN2A was thought to give answers to many questions on genotype-phenotype correlations in familial melanoma. Today, 4 y later, germline mutations cosegregate with melanoma in only 40%-50% of the families predisposed to this disease. The hunt for genes and modifying genes is on again. Through the years the very well-characterized Dutch FAMMM families have proven to be valuable study subjects in melanoma research. This paper describes over 10 y of melanoma research illustrated by research performed in the Dutch FAMMM families.
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PMID:Familial melanoma; CDKN2A and beyond. 1053 8

Patients with a family history of melanoma are at increased risk of this tumor. Those family members who also have the atypical mole syndrome are commonly targeted for screening in the belief that they are more likely to be mutant gene carriers. We have correlated the atypical mole syndrome phenotype and gene carrier status in five families with germline CDKN2A mutations and shown that family members with the atypical mole syndrome were three times more likely to be mutant gene carriers than their relatives who did not have the atypical mole syndrome (odds ratio 3.4; confidence interval 1.0-11. 1), supporting the view that CDKN2A is nevogenic. Individual characteristics which best predicted mutant gene carrier status were: nevi on the buttocks (odds ratio 4.4; confidence interval 1. 6-12.4), nevi on the feet (odds ratio 4.2; confidence interval 1. 4-12.5), total nevus number being at least 100 (nevi > or = 2 mm in diameter) (odds ratio 3.4; confidence interval 1.0-11.1) and two or more clinically atypical nevi (odds ratio 3.1; confidence interval 1. 1-9.0). Gene carriers were also significantly more likely to have noticeable freckling and possibly also Fitzpatrick skin types 1-3. The overlap between gene carriers and nongene carriers was, however, marked: the atypical mole syndrome did not clearly differentiate mutant gene carriers from those with a normal gene. This study is of significance to clinicians as the clinical practice of using the atypical mole syndrome to identify particular family members for surveillance is shown to be inappropriate. Until formal gene testing is available, all members of families with an excessive number of melanoma cases should be treated as potential mutation carriers at increased risk of melanoma.
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PMID:Genotype/phenotype and penetrance studies in melanoma families with germline CDKN2A mutations. 1062 Jan 11

Although the first English-language report of melanoma in 1820 contained a description of a melanoma-prone family, it was 1983 before formal genetic analysis suggested an autosomal dominant mode of inheritance for both melanoma and the then newly described melanoma precursor, dysplastic nevi (DN). Subsequent genetic studies have assumed this model to be correct, although when viewed in aggregate, the data are inconsistent. The first proposed melanoma gene (CMM1) was mapped to chromosome 1p36. This gene assignment has not been confirmed. A second melanoma gene, designated CMM2, has been mapped to chromosome 9p21. This gene assignment has been confirmed, and the cell cycle regulator CDKN2A has been proposed as the candidate gene. Germline mutations in this gene have been identified in about 20% of melanoma-prone families that have been studied to date. Pancreatic cancer occurs excessively in melanoma families with germline mutations in CDKN2A. Germline mutations in the cyclin-dependent kinase gene CDK4 (chromosome 12q14) have been described in three melanoma families. This finding represents a third melanoma gene but one that accounts for only a tiny fraction of all hereditary melanoma. Recently, a familial melanoma-astrocytoma syndrome has been reported. Large germline deletions of 9p21 occur in these families, with the p19 gene implicated in its pathogenesis. At present, clinical predictive genetic testing for mutations in the CDKN2A gene is available commercially, but its use has been limited by uncertainty as to how test results would affect the management of melanoma-prone family members. Currently, management recommendations include monthly skin self-examination, clinical skin examination once or twice yearly, a low threshold for simple excision of changing pigmented lesions, moderation of sun exposure, and appropriate use of sunscreens. A heritable determinant for total nevus number has been suggested by twin studies. Other data suggest the presence of a major gene responsible for "total nevus density" in melanoma-prone families. Approximately 55% of the mole phenotype in multiplex melanoma families was explained by this proposed gene. An autosomal dominant mode of inheritance has been proposed for DN, and data exist to suggest that DN may be a pleiotropic manifestation of the 1p36 familial melanoma gene. However, there clearly are melanoma-prone families that do not express the dysplastic nevus trait, and some of the families linked to CDKN2A also present with dysplastic nevi. Several studies have shown a surprisingly high prevalence of DN on the skin of family members of probands with DN. In light of the extensive evidence documenting that persons with DN (both sporadic and familial) have an increased prospective risk of melanoma, these family studies suggest that relatives of persons with DN should be examined for both DN and melanoma. Genetic determinants play a major role in the pathogenesis of normal nevi, DN, and melanoma. Identifying the molecular basis of these genetic events promises to enhance melanoma risk-reduction strategies and, ultimately, reduce melanoma-associated mortality.
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PMID:The genetics of hereditary melanoma and nevi. 1998 update. 1063 Jan 72

Germline mutations of the CDKN2A (p16(INK4A)) tumor suppressor gene predispose patients to melanoma and pancreatic carcinoma. In contrast, mutations of the murine CDKN2A gene predispose BALB/c mice to pristane-induced plasmacytoma. We describe here a family in which a germline mutation of CDKN2A is present in 4 individuals who developed melanoma as well as in a fifth family member who is suffering from multiple myeloma. To determine whether the CDKN2A mutation predisposed the myeloma patient to her disease, we carried out loss of heterozygosity studies on sorted bone marrow from this individual and observed loss of the wild type CDKN2A allele in the malignant plasma cells. We suggest that germline mutations of CDKN2A may predispose individuals to a wider variety of malignancy than has been hitherto reported, but that the expression of these cancers may depend heavily on the genetic background of the patient. (Blood. 2000;95:1869-1871)
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PMID:Germline CDKN2A mutation implicated in predisposition to multiple myeloma. 1068 50

Recent data suggest that additional factors, other than UV radiation, are involved in the etiology of non-melanoma skin cancer. These include alterations in the tumor suppressor genes, p53, p16$L*I*U$LINK4a$L*I$L/CDKN2A, p21$L*I*U$LWAF1/CIP1$L*I$L and the PTCH gene, as well as cytokines. Papillomavirus infections have been implicated in the etiology of non-melanoma skin cancer. The interaction of tumor suppressor genes and cytokines with the oncoproteins of high-risk mucosal HPV types have been studied in detail, but very little is known about the cutaneous HPV types. We have studied the effect of UV radiation on the URRs of HPV 1, 2, 3, 5, 7, 20, 23, 27, 38, 41, and 77. Neither the CAT-expression and promoter activity of these HPV types, nor presence or absence of wild-type or mutated p53 in the cell lines used, could be related to the DNA sequence homology between the different HPV types or their biological behavior.
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PMID:Human papillomaviruses in non-melanoma skin cancer. 1071 88

Germline mutations of the CDKN2A tumor suppressor gene have been identified in melanoma kindreds linked to 9p21, and pancreatic adenocarcinoma is the second most common malignancy in some of these families. We hypothesized that unselected patients with both primary cancers, i.e., pancreatic cancer and malignant melanoma, have a genetic predisposition to tumor development, and that this susceptibility may be due to germline CDKN2A mutations. Fourteen patients, with both pathologically verified pancreatic adenocarcinoma and melanoma, were assessed for germline CDKN2A mutations by polymerase chain reaction amplification and sequencing of six overlapping fragments encompassing exons 1alpha and 2. A yeast two-hybrid assay was used to assess the functional consequences of CDKN2A variants. Germline CDKN2A mutations were identified in 2/14 patients: I49S, a novel substitution in exon 1alpha, and M53I, a previously reported missense mutation in exon 2. Both variants lead to compromised CDKN2A function. We conclude that the occurrence of both pancreatic cancer and melanoma, in the same patient, signals an inherited susceptibility to cancer, and that this predisposition is, in some cases, due to germline CDKN2A mutations. This finding has important implications not only for the proband, but also for other family members.
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PMID:Patients with both pancreatic adenocarcinoma and melanoma may harbor germline CDKN2A mutations. 1071 65

In familial cutaneous malignant melanoma (CMM), disruption of the retinoblastoma (pRB) pathway frequently occurs through inactivating mutations in the p16 (p16INK4A/CDKN2A/MTS1) gene or activating mutations in the G1-specific cyclin dependent kinase 4 gene (CDK4). Uveal malignant melanoma (UMM) also occurs in a familial setting, or sometimes in association with familial or sporadic CMM. Molecular studies of sporadic UMM have revealed somatic deletions covering the INK4A-ARF locus (encoding P16INK4A and P14ARF) in a large proportion of tumours. We hypothesized that germline mutations in the p16INK4A, p14ARF or CDK4 genes might contribute to some cases of familial UMM, or to some cases of UMM associated with another melanoma. Out of 155 patients treated at the Institut Curie for UMM between 1994 and 1997, and interviewed about their personal and familial history of melanoma, we identified seven patients with a relative affected with UMM (n = 6) or CMM (n = 1), and two patients who have had, in addition to UMM, a personal history of second melanoma, UMM (n = 1), or CMM (n = 1). We screened by polymerase chain reaction single-strand conformation polymorphism the entire coding sequence of the INK4A-ARF locus (exon 1alpha from p16INK4A, exon 1beta from p14ARF, and exons 2 and 3, common to both genes), as well as the exons 2, 5 and 8 of the CDK4 gene, coding for the functional domains involved in p16 and/or cyclin D1 binding. A previously reported polymorphism in exon 3 of the INK4A-ARF locus was found in one patient affected with bilateral UMM, but no germline mutations were detected, either in the p16INK4A, p14ARF or CDK4 genes. Our data support the involvement of other genes in predisposition to uveal melanoma.
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PMID:Individuals with presumably hereditary uveal melanoma do not harbour germline mutations in the coding regions of either the P16INK4A, P14ARF or cdk4 genes. 1073 52

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