UMLS:C0033036 - FACTA Search

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Query: UMLS:C0033036 (APC)
10,214 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Lung cancers exhibit multiple genetic lesions including mutations activating the dominant cellular proto-oncogenes as well as those inactivating the recessive or "tumor suppressor" genes. Candidate tumor suppressor genes include those on chromosomes 1p, 1q, 3p14, 3p21.3, 3p25 (VHL gene), 5q21 (APC/MCC gene cluster), 9p21-22 (interferon gene cluster), 11p, 13q (rb gene), 16p24, and 17p (p53 gene). Mutations in p53 inactivate its transcriptional activity, while replacement of a wild-type p53 in lung cancer cells inhibits growth and tumorigenicity suggesting that p53 acts as a master growth regulatory switch. Lung cancer cells exhibit several positive autocrine growth factor loops and express nicotine receptors which could function as tumor promoting systems. In addition, they express a negative autocrine loop involving opioids and their receptors which is reversed by nicotine acting through nicotinic acetylcholine receptors. The presence of nicotine receptors suggests nicotine or its metabolites may play a direct role in lung cancer pathogenesis.
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PMID:The molecular biology of lung cancer pathogenesis. 846 39

Identification of inherited cancer-predisposing genes offers opportunities for cancer prevention. Inherited susceptibility genes have been identified, primarily through studies of unusual cancer cases and families but also through general population studies. Examples include the RB1 gene for retinoblastoma; the WT1 gene for Wilms' tumor; germline p53 mutations in families with the Li-Fraumeni syndrome; the NF1 and NF2 genes for neuroblastomatosis, types 1 and 2; the VHL gene for renal cancer and other tumors associated with Von Hippel-Lindau disease; the APC gene for adenomatous polyposis coli; the BRCA1 gene for hereditary breast and ovarian cancer; and the mismatch repair genes for colon and other common cancers. For some cancers, identification of gene carriers might be beneficial for targeting screening and chemopreventive interventions. On the other hand, predisposition testing for cancer has the potential for harm from loss of insurability and employability, psychological distress, social stigmatization and other adverse effects. Research is needed to identify predisposition testing procedures that maximize benefits while minimizing harm to subjects. Chemoprevention trials in genetically susceptible populations offer the prospect of finding effective methods of reducing future cancer risk.
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PMID:Identification and management of inherited cancer susceptibility. 874 2

To investigate the molecular mechanisms of tuberous sclerosis (TSC) histopathologic lesions, we have tested for loss of heterozygosity the two TSC loci (TSC1 and TSC2) and seven tumor suppressor gene-containing regions (TP53, NF1, NF2, BRCA1, APC, VHL, and MLM) in 20 hamartomas from 18 TSC patients. Overall, eight angiomyolipomas, eight giant cell astrocytomas, one cortical tuber, and three rhabdomyomas were analyzed. Loss of heterozygosity at either TSC locus was found in a large fraction of the informative patients, both sporadic (7/14) and familial (1/4). Interestingly, a statistically significant preponderance of loss of heterozygosity at TSC2 was observed in the sporadic group (P < 0.01). Among the possible explanations considered, the bias in the selection for TSC patients with the most severe organ impairment seems particularly appealing. According to this view, a TSC2 defect might confer a greater risk for early kidney failure or, possibly, a more rapid growth of a giant cell astrocytoma. None of the seven antioncogenes tested showed loss of heterozygosity, indicating that the loss of either TSC gene product may be sufficient to promote hamartomatous cell growth. Finally, the observation of loss of heterozygosity at different markers in an astrocytoma and in an angiomyolipoma from the same patient might suggest the multifocal origin of the second-hit mutation.
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PMID:Apparent preferential loss of heterozygosity at TSC2 over TSC1 chromosomal region in tuberous sclerosis hamartomas. 882 21

Recent knowledge about biological role of tumor suppressor genes and their products: RB1, p53, WT1, DCC, APC/FAP, NF1, NF2, VHL, MCC and MTS1 is presented. The main approaches of these agents as physiological regulators of cell growth and proliferation are discussed. Views on the tumor suppressor genes involvement in the development of inherited and sporadic forms of cancer have been reviewed.
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PMID:[Antioncogenes--tumor suppression genes]. 933 80

Carcinoma in ulcerative colitis (UC) develops from dysplastic precursor lesions, which include flat dysplasia (FD) and polypoid dysplasias (PD). PD may present as single or multiple polypoid structures or as plaque-like lesions that, independent of histological grade, are an indication for colectomy. PDs are histologically similar to adenomas and may not be readily distinguished by light microscopy. It is not known whether FD and PD are different entities, or whether they represent etiologically similar lesions with different morphological expression. We microdissected 25 cases of UC with PD and 19 samples of FD with surrounding chronic colitis (CC) in UC. Loss of heterozygosity (LOH) at the von Hippel Lindau (vHL) gene locus and the putative tumor suppressor genes APC, INK4A (9p16), and p53 was studied. LOH of the vHL gene, INK4A (9p16), and APC was also studied in 11 sporadic adenomas of the colon. LOH at the vHL locus was present in 50% of the samples of PD and in 12% of the samples of FD. LOH was seen in CC close to PD and FD in 26% and 12% of cases, respectively. No adenoma showed LOH of the vHL gene markers studied. LOH in p53 was seen in PD in 16% cases and in FD in 42% cases and in CC close to PD and FD in 0% and 14% cases, respectively. LOH patterns between PD and FD of the markers for APC and 9p16 were not different. LOH in APC was seen in two of five cases of adenoma. We conclude that PD and FD share genetic alterations in APC and 9p16 genes. More frequent involvement of the VHL gene in PD and surrounding CC and involvement of p53 in HGD and CC in FD may represent genetic differences between the development of PD and FD and may be the cause of the different morphology. The infrequency of LOH at the vHL locus in adenomas versus PD may serve as a discriminator between adenomas and PD in diagnostically problematic cases.
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PMID:Loss of heterozygosity of the von Hippel Lindau gene locus in polypoid dysplasia but not flat dysplasia in ulcerative colitis or sporadic adenomas. 974 12

Deletions of tumour-suppressor genes can be detected by loss of heterozygosity (LOH) studies, which were performed on 23 cases of adenocarcinoma of the oesophagus, using 120 microsatellite primers covering all non-acrocentric autosomal chromosome arms. The chromosomal arms most frequently demonstrating LOH were 3p (64% of tumours), 5q (45%), 9p (52%), 11p (61%), 13q (50%), 17p (96%), 17q (55%) and 18q (70%). LOH on 3p, 9p, 13q, 17p and 18q occurred mainly within the loci of the VHL, CDKN2, Rb, TP53 and DCC tumour-suppressor genes respectively. LOH on 5q occurred at the sites of the MSH3 mismatch repair gene and the APC tumour-suppressor gene. 11p15.5 and 17q25-qter represented areas of greatest LOH on chromosomes 11p and 17q, and are putative sites of novel tumour-suppressor genes. LOH on 9p was significantly associated with LOH on 5q, and tumours demonstrating LOH at both the CDKN2 (9p21) and MSH3 (5q11-q12) genes had a significantly higher fractional allele loss than those retaining heterozygosity at these sites. Six of nine carcinomas displaying microsatellite alterations also demonstrated LOH at CDKN2, which may be associated with widespread genomic instability. Overall, there are nine sites of LOH associated with oesophageal adenocarcinoma.
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PMID:Allelotype analysis of oesophageal adenocarcinoma: loss of heterozygosity occurs at multiple sites. 976 89

The human genome is thought to contain about 80,000 genes and presently only 3,000 are known to be implicated in genetic diseases. In the near future, the entire sequence of the human genome will be available and the development of new methods for point mutation detection will lead to a huge increase in the identification of genes and their mutations associated with genetic diseases as well as cancers, which is growing in frequency in industrial states. The collection of these mutations will be critical for researchers and clinicians to establish genotype/phenotype correlations. Other fields such as molecular epidemiology will also be developed using these new data. Consequently, the future lies not in simple repositories of locus-specific mutations but in dynamic databases linked to various computerized tools for their analysis and that can be directly queried on-line. To meet this goal, we devised a generic software called UMD (Universal Mutation Database). It was developed as a generic software to create locus-specific databases (LSDBs) with the 4(th) Dimension(R) package from ACI. This software includes an optimized structure to assist and secure data entry and to allow the input of various clinical data. Thanks to the flexible structure of the UMD software, it has been successfully adapted to nine genes either involved in cancer (APC, P53, RB1, MEN1, SUR1, VHL, and WT1) or in genetic diseases (FBN1 and LDLR). Four new LSDBs are under construction (VLCAD, MCAD, KIR6, and COL4A5). Finally, the data can be transferred to core databases.
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PMID:UMD (Universal mutation database): a generic software to build and analyze locus-specific databases. 1061 27

Although tumor suppressor genes continue to be discovered, the most recent advances have been made in attributing new and exciting functions to existing ones - such as the apparent role of VHL as a regulator of proteolysis. Great insights have also come from piecing genes together into pathways and networks. For instance the discovery that cyclin D1 is regulated by beta-catenin/Tcf-4 allows us to tie the APC pathway to the RB pathway and cell cycle control. Similarly, tumor suppressor genes have been fitted together with oncogenes into the various pathways that regulate apoptosis such that tumor suppressor function is now attributed to some of the basic components of the apoptotic machinery, such as caspases and Apaf-1. The great pace at which mouse models of tumorigenesis continue to advance our knowledge of tumor suppressor gene function has led us to look anew at the role of genes such as TCF-1 and SMAD-3 in human cancer. Finally, the realisation that different growth regulatory pathways give rise to generic signals suggests that future work may lie in integrating the signals from different pathways and in understanding the importance of protein levels to cellular function.
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PMID:Tumor suppressor genes. 1067 86

Seventy malignant, premalignant and histologically normal biopsies from 7 oesophagogastrectomy specimens of adenocarcinomas of the lower oesophagus and gastroesophageal junction were analysed for loss of heterozygosity (LOH) at 9 known or putative gene loci. LOH was detected in 20 of 27 (74%) malignant biopsies, 4 of 7 (57%) biopsies of dysplasia, 2 of 12 (25%) biopsies of histologically normal oesophagus adjacent to adenocarcinoma, and in 2 of 14 (14%) biopsies of histologically normal stomach adjacent to adenocarcinoma. LOH at the VHL, APC, CDKN2 and DCC tumour suppressor and MSH3 mismatch repair gene loci can be detected in histologically normal tissue and in adjacent adenocarcinoma, and are potential markers of early neoplastic progression.
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PMID:Histological and molecular mapping of adenocarcinoma of the oesophagus and gastroesophageal junction: loss of heterozygosity occurs in histologically normal epithelium in the oesophagus and stomach. 1076 62

Cell growth is under the control of a variety of positive and negative signals. An imbalance of such signals results in deregulation of cell behavior. Recessive oncogenes or tumor suppressor genes, opposite to dominant oncogenes, encode important cellular proteins which could function as negative regulators of the cell cycle, i.e., cell cycle brakes. Inactivation of recessive oncogenes, by allelic deletion, loss of expression, mutation, or functional inactivation by interacting with oncogene products of DNA tumor viruses or with amplified cellular binding proteins, will lead to uncontrolled cell growth or tumor formation. Besides the classic suppressor genes such as the p53 and RB, a growing number of novel tumor suppressor genes have been identified in recent years. While some tumor suppressor genes have been found to be important for the development of a large number of human malignancies (e.g., the p53 gene), others are more tumor type-specific (e.g., the NF-1 gene). Many human cancer types showed abnormalities of multiple tumor suppressor genes, offering strong support to the concept that tumorigenesis and progression result from an accumulation of multiple genetic alterations. In this review, we will begin with an overview (gene, transcript, protein and mechanisms of action) of the tumor suppressor genes (the RB, p53, DCC, APC, MCC, WT1, VHL, MST1, and BRCA1 genes) identified to date and then discuss the specific involvement of tumor suppressor genes in human malignancies including prostate cancer. Various chromosomal regions which potentially may contain tumor suppressor genes also will be reviewed.
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PMID:Recessive oncogenes: current status. 1117 62

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