Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0596263 (carcinogenesis)
 64,820 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Somatic changes in the genome of breast cancer cells include amplifications, deletions and gene mutations. Several chromosome regions harboring known oncogenes are found amplified in breast tumors. Despite the high number of chromosome regions deleted in breast tumors the functional relationship to known genes at these locations and cancer growth is mainly undiscovered. Mutations in two tumor suppressor genes (TSG) have been described in a subset of breast carcinomas. These TSG are the TP53, encoding the p53 transcription factor, and the CDH1, encoding the cadherin cell adhesion molecule. Breast tumors of patients with a germ-line mutation in the BRCA1 or BRCA2 gene have an increase of additional genetic defects compared with sporadic breast tumors. This higher frequency of genetic aberrations could pinpoint genes that selectively promote tumor progression in individuals predisposed to breast cancer due to BRCA1 or BRCA2 germ-line mutations. Accumulation of somatic genetic changes during tumor progression may follow a specific and more aggressive pathway of chromosome damage in these individuals. Although the sequence of molecular events in the progression of breast tumor is poorly understood the detected genetic alterations fit the model of multistep carcinogenesis in both sporadic and hereditary breast cancer. This review will focus on the genetic lesions within the breast cancer cell.
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PMID:Molecular genetics of breast cancer progression. 1044 15

The worldwide incidence of hepatocellular carcinoma (HCC) is approximately one million cases a year. This makes HCC one of the most frequent human malignancies, especially in Asia and Africa, although the incidence is increasing also in the western world. HCC is a complication of chronic liver disease, with cirrhosis as the most important risk factor. Viral co-pathogenesis makes cirrhosis due to hepatitis B (HBV) and hepatitis C virus (HCV) infection a very important factor in the development of HCC. As curative therapy is often ruled out due to the late detection of HCC, it would be attractive to find parameters which predict malignant transformation in HBV- and HCV-infected livers. This study has used comparative genomic hybridization (CGH) to analyse 26 HCCs (11 non-viral, nine HBV, six HCV) and 12 concurrent dysplasias (five non-viral, five HBV, two HCV). Frequent gain (> or =25% of all tumours) was detected, in decreasing order of frequency, on 8q (69%), 1q (46%), 17q (46%), 12q (42%), 20q (31%), 5p (27%), 6q (27%), and Xq (27%). Frequent loss (> or =25% of all tumours) was found, in decreasing order of frequency, on 8p (58%), 16q (54%), 4q (42%), 13q (39%), 1p (35%), 4p (35%), 16p (35%), 18q (35%), 14q (31%), 17p (31%), 9p (27%), and 9q (27%). Minimal overlapping regions could be determined at multiple locations (candidate genes in parentheses). Minimal regions of overlap for deletions were assigned to 4p14-15 (PCDH7), 8p21-22 (FEZ1), 9p12-13, 13q14-31 (RB1), 14q31 (TSHR), 16p12-13.1 (GSPT1), 16q21-23 (CDH1), 17p12-13 (TP53), and 18q21-22 (DPC4, DCC). Minimal overlapping amplified sites could be seen at 8q24 (MYC), 12q15-21 (MDM2), 17q22-25 (SSTR2, GH1), and 20q12-13.2 (MYBL2, PTPN1). A single high level amplification was seen on 5q21 in an HBV-related tumour. Aberrations appeared more frequent in HBV-related HCCs than in HCV-associated tumours (p=0.008). This was most prominent with respect to losses (p=0.004), specifically loss on 4p (p=0.007), 16q (p=0.04), 17p (p=0.04), and 18q (p=0.03). In addition, loss on 17p was significantly lower in non-viral cancers than in HBV-related HCC (p<0.001). Furthermore, loss on 13q was more prevalent in HCCs in non-cirrhotic livers (p=0.02), thus suggesting a different, potentially more aggressive, pathway in neoplastic progression. A tendency (p=0.07) was observed for loss on 9q in high-stage tumours; no specific changes were found in relation to tumour grade. A subset of the HCC-associated genetic changes was disclosed in the preneoplastic stage, i.e. liver cell dysplasia. This group of dysplasias showed frequent gain on 17q (25%) and frequent loss on 16q (33%), 4q (25%), and 17p (25%). The majority of the dysplasias with alterations revealed genetic changes that were also present in the primary tumour. In conclusion, firstly, this study has provided a detailed map of genomic changes occurring in HCC of viral and non-viral origin, and has suggested candidate genes. Loss on 17p, including the TP53 region, appeared significantly more prevalent in HBV-associated liver cancers, whereas loss on 13q, with possible involvement of RB1, was distinguished as a possible genetic biomarker. Secondly, CGH analysis of liver cell dysplasia, both viral and non-viral, has revealed HCC-specific early genetic changes, thereby confirming its preneoplastic nature. Finally, genes residing in these early altered regions, such as CDH1 or TP53, might be associated with hepatocellular carcinogenesis.
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PMID:Molecular cytogenetic evaluation of virus-associated and non-viral hepatocellular carcinoma: analysis of 26 carcinomas and 12 concurrent dysplasias. 1100 97

Inactivating mutations have been found in the cell-cell adhesion molecule E-cadherin (CDH1), which acts as a tumor suppressor gene in different kinds of cancers, e.g. primarily diffuse gastric cancer and lobular breast cancer. In this study, we screened for germline alterations in familial gastric and colon cancer cases. In total, 20 gastric and 18 colon cancer patients with both familial gastric and colon cancer were tested for germline E-cadherin alterations by using PCR/SSCP, specific restriction digestion test and sequencing. No pathogenic mutations were identified in the gastric cancer patients. In two colon cancer patients, a missense mutation in exon 12, codon 592 (Ala592Thr) was found. This alteration segregated with diffuse gastric cancer and colon cancer in one of the families. The prevalence of this alteration in the general population and colon cancer cases was almost the same. However, the fact that this alteration (Ala592Thr) segregated with colon cancer and diffuse gastric cancer in one big family, suggests that this E-cadherin missense alteration, beside predisposing to diffuse gastric cancer, also may play a role in colorectal carcinogenesis.
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PMID:A germline E-cadherin mutation in a family with gastric and colon cancer. 1156 85

Gastric cancers are commonly subdivided into intestinal and diffuse subtypes on a morphologic basis, supported by corollary evidence of differences at the pathogenetic and molecular levels. Chronic atrophic gastritis with intestinal metaplasia is a common precursor lesion for the intestinal type of carcinoma. To identify early molecular changes, in this study we have examined 13 surgical specimens both for the expression of E-cadherin, p53 and beta-catenin by immunohistochemistry and for methylation of the CDH1 promoter (E-cadherin) by bisulfite genomic sequencing of laser capture microdissected samples. Each specimen examined contained areas of normal (nonmetaplastic) gastric mucosa, as well as areas of intestinal metaplasia and/or carcinoma. Reduced or absent E-cadherin and partial to complete methylation of one to multiple CpG sites examined in the CDH1 promoter were observed in all of the metaplasia samples. Thus, the methylation status of the CDH1 promoter and expression of E-cadherin together provide strong evidence that loss of E-cadherin is an early event in intestinal type gastric carcinogenesis. In contrast, expression of p53, assumed to be mutant p53, was generally not detected (except for isolated cells) until the carcinoma stage in tissues from these patients. These results suggest that mutation of p53 is a late event in intestinal type gastric cancer. The level of beta-catenin expression did not appear to change between normal, metaplastic and carcinoma cells of intestinal type, and no nuclear staining was visible in any of the tissues. These results suggest that the Wnt signaling pathway is not upregulated in this type of cancer.
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PMID:Loss of E-cadherin expression in gastric intestinal metaplasia and later stage p53 altered expression in gastric carcinogenesis. 1166 47

Human SNAIL1 (SNAI1) protein encoded by SNAI1/SNA gene represses transcription of E-cadherin/CDH1 gene. Human SNAIL2 (SNAI2) protein encoded by SNAI2/SLUG gene induces the first phase of epithelial-mesenchymal transition (EMT), including desmosome dissociation, cell spreading, and initiation of cell separation. Here, we have identified human SNAIL3 (SNAI3) gene using bioinformatics. Human SNAI3 gene, consisting of at least three exons, spans around the nucleotide position 320214-328221 of human reference genomic contig NT_010404.8 in the reverse orientation. SNAI3 gene, was located between KIAA0233 gene and CBFA2T3 gene in human chromosome 16q24.3, a region affected in breast cancer, gastric cancer, hepatocellular carcinoma, ovarian cancer, and therapy-related myeloid leukemia with t(16;21)(q24;q22) translocation. Human SNAI3 gene was found to encode 292-amino-acid polypeptide with the N-terminal SNAG domain and five zinc finger domains. N-terminal SNAG domain was identified in zinc finger proteins SNAI1, SNAI2, SNAI3, SCRATCH (SCRT1), GFI1, and GFI1B. ATP/GTP binding site was identified in SCRT1, GFI1 and GFI1B, but not in SNAI1, SNAI2 and SNAI3. Phylogenetic analysis of human zinc finger proteins with SNAG domain revealed that SNAI1, SNAI2 and SNAI3 were more closely related. These results clearly indicate that SNAI1, SNAI2 and SNAI3 constitute a subfamily among SNAG zinc-finger proteins. Human SNAI3 mRNA was expressed in skin melanotic melanoma, lung epidermoid carcinoma, and germ cell tumor. Because SNAG zinc-finger proteins are transcriptional repressors implicated in carcinogenesis and embryogenesis, SNAI3 gene might be a potent target of pharmacogenomics in the field of oncology and regenerative medicine.
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PMID:Identification and characterization of human SNAIL3 (SNAI3) gene in silico. 1257 45

Differential gene methylation is observed in a variety of human malignancies. The study of the pattern of methylated genes helps to understand carcinogenesis and to identify potential marker tumor genes for clinical use. The differential methylated genes in undifferentiated nasopharyngeal carcinoma (NPC) of Chinese were studied by methylation-specific polymerase chain reaction (MSP). Methylation status of 11 tumor-associated genes (ARF, caspase-8, CDH1, CDKN2A, CDKN2B, MGMT, MLH1, RASSF1A, THBS1, TP73 and VHL) was studied in 30 primary undifferentiated NPC and paired peripheral blood of 12 patients. The methylation profile of NPC in order of frequency was CDH1 (50%), CDKN2B (50%), THBS1 (50%), RASSF1A (46%), MLH1 (40%), MGMT (28%), CDKN2A (23%), TP73 (20%), caspase-8 (7%), ARF (3%) and VHL (0%). Methylation of at least 1 gene was observed in 93% of primary NPC. Of the 12 patients with at least 1 methylated gene in the primary tumor, all 12 (100%) patients had at least 1 of the methylated gene promoter detectable in their peripheral blood. The results show high frequency of methylation in NPC and the potential of using methylation as peripheral blood tumor marker in screening NPC.
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PMID:Differential gene methylation in undifferentiated nasopharyngeal carcinoma. 1263 81

Down-regulation of tumor suppressor genes by hypermethylation of 5'-CpGs is one of the important mechanisms involved in tumor development. DNA (5-cytosine)-methyltransferases (DNMTs) are enzymes that methylate the cytosine residue of CpGs, and four types have been identified (DNMT1, 2, 3a and 3b). To examine the involvement of DNMTs in hepatocellular carcinogenesis, we measured DNMT mRNAs in hepatocellular carcinomas (HCCs). mRNAs of DNMT1, 2, 3a and 3b were detected by reverse transcription-PCR analysis and quantified by a real-time PCR method in surgically resected HCCs and adjacent non-tumorous liver tissue. DNMT1 was expressed in all tissues and at a significantly higher level in HCCs than in non-tumorous liver tissue (P=0.01). DNMT2 was expressed at a low level in all tissues. DNMT3a and DNMT3b mRNA were undetectable in normal liver. DNMT3a was expressed in all HCCs and was expressed at similar levels in 60% of the non-tumorous liver tissues. DNMT3b mRNA was detected at a significantly higher level (P=0.002) in HCCs than in non-tumorous liver tissues. The amount of DNMT1, 3a and 3b mRNA was not different between HCCs with or without hypermethylation of the CDH1 promoter. These data suggest that overexpression of DNMT1 and DNMT3b contributes to hepatocellular carcinogenesis.
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PMID:Expression of DNA (5-cytosin)-methyltransferases (DNMTs) in hepatocellular carcinomas. 1285 Jun 90

The E-cadherin (CDH1) gene has been associated with prostate carcinogenesis. The C/A polymorphism--160 base pairs relative to the transcription start site has been shown to decrease gene transcription. We analyzed the association between this polymorphism and the risk of sporadic, familial (2 close relatives) and hereditary (3 or more close relatives) prostate cancer. We combined data from 3 population-based epidemiologic studies in Sweden encompassing altogether 1,036 prostate cancer cases and 669 controls that were genotyped for the short nucleotide polymorphism. Odds ratios with 95% confidence intervals were estimated through unconditional logistic regression. We found no significant association between the A-allele and sporadic (OR = 1.0; 95% CI = 0.8-1.2) or familial (OR = 1.4; 95% CI = 0.9-2.2) prostate cancer. In contrast, risk of hereditary cancer was increased among heterozygote CA carriers (OR = 1.7; 95% CI = 1.0-2.7) and particularly among homozygote AA carriers (OR = 2.6; 95% CI = 1.4-4.9). Our data indicate that the -160 single nucleotide polymorphism in CDH1 is a low-penetrant prostate cancer susceptibility gene that might explain a proportion of familial and notably hereditary prostate cancer.
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PMID:-160C/A polymorphism in the E-cadherin gene promoter and risk of hereditary, familial and sporadic prostate cancer. 1496 71

Gastric cancer remains quite a common malignancy and counts among the most important causes of cancer-related death worldwide. Although the pathogenesis is multifactorial, familial aggregation in a significant proportion of cases suggests the importance of genetic predisposition. The association between the E-cadherin/CDH1 gene germline mutations and the development of diffuse gastric cancer was the first evidence for a molecular basis of gastric cancer in predisposed families and led many authorities in the world to produce guidelines regarding the management of such families members. The recent advances in genetics resulted in the discovery of numerous genetic events occurring during the course of gastric carcinogenesis (activation of oncogenes, silencing of tumor suppressor genes, mutations in DNA-repairing genes) and contributed to a better understanding in pathogenesis. Many genetic changes described have been found to affect tumor's biological behavior. In this article the authors attempt a review of all the molecular alterations in gastric cancer described in the literature and their impact on the management of patients with an inherited predisposition to gastric cancer. The promising role of gene therapy in the treatment of gastric cancer in the near future is also commented on.
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PMID:Genes and gastric cancer. 1501 94

Gastric cancer is thought to result from a combination of environmental factors and accumulation of specific genetic alterations, and consequently mainly affects older patients (>50 years of age). Fewer than 10% of patients present with the disease before 45 years of age and these young patients are thought to develop carcinomas with a different molecular genetic profile from that of sporadic carcinomas occurring at a later age. Forty early-onset gastric carcinoma resection specimens were characterized for microsatellite instability (MSI) and loss of heterozygosity status using 22 polymorphic microsatellite markers. Twenty-four biopsies were additionally evaluated for the presence of MSI. No MSI was observed in any of the cases analysed. Losses were infrequent, but were most common for the D1S234 (26.1%) and D1S1676 (17.4%) markers, flanking the RUNX3 gene; for the p53ALU (23.1%) and TP53 (15.4%) markers, near the TP53 gene; and for the D16S2624 (17.2%) marker, near the E-cadherin (CDH1) gene. All cases with loss of CDH1, as well as 6/7 cases with loss of TP53, displayed aberrant staining of the corresponding proteins, pointing to a functional role for these proteins in early-onset gastric carcinogenesis. No germline CDH1, TP53 or RUNX3 mutations were detected in any of the cases analysed. No correlation was observed between non-functional E-cadherin and the histological type of the tumours analysed. Finally, Epstein-Barr virus was not detected in any of the cases analysed. On the basis of these results, early-onset gastric carcinomas appear to have characteristics distinct from gastric carcinomas occurring at a later age.
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PMID:Early-onset gastric carcinomas display molecular characteristics distinct from gastric carcinomas occurring at a later age. 1530 40


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