Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0001430 (adenoma)
 21,222 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Liver cancer is one of the major human tumors in the world. Basic and epidemiological studies have proposed that the major risk factors for liver cancer include alcohol and diet as well as infection with hepatitis B and C viruses. However, the mechanistic clues for the development of this type of cancer is largely unknown. Poly(ADP-ribose) polymerase (PARP-1) and a component of nonhomologous end-joining (NHEJ) machinery, Ku80, are two major DNA end-binding molecules that play a multifunctional role in DNA damage signaling and repair, recombination as well as the maintenance of genomic stability. Here we show that the interaction of PARP-1 and Ku80 is essential for development because PARP-1/Ku80 double null mice died at embryonic day (E) 9.5. Interestingly, haplo-insufficiency of Ku80 in PARP-1-/- mice promotes the development of hepatocellular adenoma and hepatocellular carcinoma (HCC). These tumors exhibited a multistage tumor progression associated with the loss of E-cadherin expression and the mutation of beta-catenin. Cytogenetic analysis revealed that Ku80 heterozygosity elevated chromosomal instability in PARP-1-/- cells and that these liver tumors harbored a high degree of chromosomal aberrations including fragmentations, end-to-end fusions, and recurrent nonreciprocal translocations (NRT). These features are reminiscent of human HCC. Taken together, these data implicate a synergistic function of Ku80 and PARP-1 in minimized chromosome aberrations and cancer development and suggest that defects in DNA end-processing molecules may be etiological factors in human HCC formation.
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PMID:Synergistic role of Ku80 and poly(ADP-ribose) polymerase in suppressing chromosomal aberrations and liver cancer formation. 1246 Sep 17

Although a number of studies have suggested that diets with low intake of folate, an important methyl donor, are associated with increased risks of colon cancer and its precursor the adenomatous polyp, the underlying mechanisms are poorly understood. Dysregulation and instability of DNA methylation and alterations in the levels of the predominant DNA methylating enzyme, DNA (cytosine-5)-methyltransferase 1 (Dnmt1), have also been linked to tumorigenesis. We have used a combination of genetic and dietary manipulation to assess the effects of reduced Dnmt1 expression with and without folate deficiency on tumor induction in the Apc(Min) mouse. Apc(Min) mice with a reduction in Dnmt1 expression (Apc(Min/+)/Dnmt1(C/+)) had significantly lower tumor numbers than Apc(Min) mice with normal Dnmt1 (Apc(Min/+)/Dnmt1(+/+)). Dietary folate deficiency from weaning to 13 weeks of age did not affect tumor number or size in Apc(Min/+)/Dnmt(+/+) mice. However, in Apc(Min/+)/Dnmt1(C/+) mice with high baseline tumor numbers (41 +/- 4), folate deficiency was associated with a decreased absolute number of tumors (27 +/- 3), but a higher proportion of larger tumors as compared with mice on the control diet. In the repeat experiment, Apc(Min/+)/Dnmt1(C/+) mice had low baseline tumor numbers (20 +/- 2) and folate deficiency did not affect tumor number (23 +/- 4) or size as compared with the same mice on the control diet. These results suggest that, in the presence of Dnmt1 deficiency, the effects of folate deficiency on tumor number and size may depend on the stage of adenoma development when folate deficiency is initiated. We also show that folate deficiency with or without reductions in Dnmt1 did not affect overall genomic DNA methylation or the methylation levels of two candidate genes, E-cadherin or p53, in normal or neoplastic intestinal tissue. In conclusion, genetic deficiency in Dnmt1 with or without folate deficiency decreases tumor number in the Apc(Min) mouse model, but this effect may not be mediated by changes in SAM or SAH levels, nor by alterations in global methylation in the pre-neoplastic intestinal tissue.
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PMID:Impact of Dnmt1 deficiency, with and without low folate diets, on tumor numbers and DNA methylation in Min mice. 1253 47

Our group has previously demonstrated an association between ret/PTC-1 activation and decreased E-cadherin mRNA levels in papillary thyroid carcinoma. We also observed similarities in the E-cadherin expression profiles of Hashimoto thyroiditis and ret/PTC-1-positive papillary thyroid carcinomas and have hypothesized that ret/PTC-1 activation might cause not only the structural and nuclear peculiarities of PTC but also an immune reaction to thyroid epithelium. The objective of this study was to examine the expression of E-cadherin's ligands, beta- and gamma-catenin, in various thyroid tissue types in the context of ret/PTC-1 positivity using laser capture microdissection and TaqMan (Applied Biosystems, Foster City, CA). One-Step RT-PCR. Beta-catenin mRNA levels were found to be consistently decreased in both papillary and anaplastic carcinomas when compared with a normal/follicular adenoma group. A significant difference in expression levels was observed between papillary and follicular thyroid carcinomas with the latter having elevated mRNA levels of beta-catenin. Gamma-catenin mRNA was decreased in anaplastic carcinomas compared with normal/follicular adenoma groups. A similar expression profile of gamma-catenin as beta-catenin was observed in papillary and follicular carcinomas with the latter once again having higher mRNA levels. These results therefore suggest that although beta- and gamma-catenin may play a role in the progression of thyroid cancer in general, they do not appear to be associated with ret/PTC-1-modulated pathways.
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PMID:Real-time analysis of beta- and gamma-catenin mRNA expression in ret/PTC-1 activated and nonactivated thyroid tissues. 1260 35

The stomach is one of the organs whose epithelial cells frequently undergo aberrant methylation of CpG islands. To date, several reports on the methylation of various genes in gastric cancer (GC) have been published. However, most of these studies have focused on cancer tissues or a single gene only and gave no information about the methylation status of specific genes in the premalignant stages or the concurrent methylation of other genes in specific lesions. We attempted to investigate methylation of multiple genes in a large sample collection of GC (n = 80), gastric adenoma (GA) (n = 79), intestinal metaplasia (IM) (n = 57), and chronic gastritis (CG) (n = 74). We determined the methylation frequency of 12 genes, including APC, COX-2, DAP-kinase, E-cadherin, GSTP1, hMLH1, MGMT, p16, p14, RASSF1A, THBS1, and TIMP3, by methylation-specific PCR. Five different classes of methylation behaviors were found: (a). genes methylated in GC only (GSTP1 and RASSF1A), (b). genes showing low methylation frequency (<12%) in CG, IM, and gastric adenoma (GA) but significantly higher methylation frequency in GC (COX-2, hMLH1, p16), (c). a gene with low and similar methylation frequency (8.8-21.3%) in four-step lesions (MGMT), (d). genes with high and similar methylation frequency (53-85%) in four-step lesions (APC and E-cadherin), and (e). genes showing an increasing tendency with or without fluctuation of the methylation frequency along the progression (DAP-kinase, p14, THBS1, and TIMP-3). The average number of methylated genes was 2.7, 3.6, 3.4, and 5.2 per 12 tested genes in CG, IM, GA, and GC, respectively. Aberrant methylation at multiple loci in the same lesions suggests an overall deregulation of the methylation control, which occurs early in multistep gastric carcinogenesis. Our results suggest that tumor-suppressor genes show a gene-type specific methylation profile along the multistep carcinogenesis and that aberrant CpG island methylation tend to accumulate along the multistep carcinogenesis.
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PMID:Profile of aberrant CpG island methylation along multistep gastric carcinogenesis. 1269 55

To date, several reports on methylation of various genes in gastric cancer (GC) have been published. However, most of these studies focused on cancer tissues or a single gene only and gave no information about the methylation status of specific genes in the premalignant stages or about the concurrent methylation of other genes in specific lesions. We attempted to investigate methylation of multiple genes in a large sample collection of GC (n = 80), gastric adenoma (GA) (n = 79), intestinal metaplasia (IM) (n = 57), and chronic gastritis (CG) (n = 74). We determined the methylation frequency of 12 genes, including APC, COX-2, DAP-kinase, E-cadherin, GSTP1, hMLH1, MGMT, p16, p14, RASSF1A, THBS1, and TIMP3 by methylation-specific PCR. Five different classes of methylation behaviors were found: (1) genes methylated in GC only (GSTP1 and RASSF1A); (2) genes showing low methylation frequency (<12%) in CG, IM, and GA, but significantly higher methylation frequency in GC (COX-2, hMLH1, and p16); (3) a gene with low and similar methylation frequency (8.8-21.3%) in four-step lesions (MGMT); (4) genes with high and similar methylation frequency (53-85%) in four-step lesions (APC and E-cadherin); and (5) genes showing an increasing tendency with or without fluctuation of the methylation frequency along the progression (DAP-kinase, p14, THBS1, and TIMP3). The average number of methylated genes was 2.7, 3.6, 3.4, and 5.2 per 12 tested genes in CG, IM, GA, and GC, respectively. Our results suggest that tumor suppressor genes show a gene type-specific methylation profile and that aberrant CpG island methylation tends to accumulate along the pathway of multistep carcinogenesis.
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PMID:Profile of aberrant CpG island methylation along the multistep pathway of gastric carcinogenesis. 1274 73

beta-catenin plays an important role in the Wnt signaling pathway and the E-cadherin-catenin complex plays a critical role in the maintenance of normal tissue architecture. An alteration of any of the components of the E-cadherin-catenin complex is believed to result in the loss of cell-cell adhesion and to contribute to carcinogenesis. In order to evaluate such alterations in the gastric adenoma-carcinoma sequence, the abnormal expression of beta-catenin and E-cadherin and the mutations of beta-catenin exon 3 were studied. In the case of beta-catenin, nuclear immunoreactivity was noted in 17 (11.3%) out of 150 adenomas and 19 (17.1%) out of 111 carcinomas (p = 0.18). Among 51 gastric adenomas, no mutations were detected by direct sequencing analysis. The loss of membranous expression of both beta-catenin and E-cadherin linearly increased with tumor progression, however, beta-catenin loss was more frequent than E-cadherin. Our results show that the nuclear expression and membranous loss of beta-catenin without exon 3 mutation is relatively frequent in gastric adenomas. These suggest that alteration of other genes is primarily responsible for the nuclear translocation of beta-catenin in gastric adenomas.
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PMID:Expression of beta-catenin and E-cadherin in the adenoma-carcinoma sequence of the stomach. 1292 24

Protein 4.1 family proteins are thought to interact with membrane proteins and membrane skeletons. Immunohistochemical studies by light and electron microscopy were performed on mouse pancreas with a specific antibody against protein 4.1B. Specific protein 4.1B immunolabeling was observed on endocrine cells in the islets of Langerhans. Protein 4.1B localized along the plasma membranes facing adjacent cells. By immunoelectron microscopy, the immunolabeling of the cells was restricted to the cytoplasmic side just beneath their plasma membrane, including the membranes adjacent to neighboring cells, while the plasma membranes facing endothelial cells were not immunolabeled for protein 4.1B. The immunolocalization of E-cadherin was similar, if not identical, to that of protein 4.1B supporting the idea that protein 4.1B may be functionally interconnected with adhesion molecules. In a transgenic mouse model of pancreatic beta-cell carcinogenesis (Rip1Tag2), the loss of protein 4.1B expression coincided with the phenotypic transition from adenoma to carcinoma. Therefore, we propose a role of protein 4.1B as a connecting and/or signaling molecule between membrane architecture, cell adhesion, and tumor cell invasion in mouse pancreatic endocrine cells.
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PMID:Protein 4.1B in mouse islets of Langerhans and beta-cell tumorigenesis. 1457 82

Most colorectal carcinomas (CRCs) arise from adenomas through an archetypal pathogenic pathway, the adenoma-carcinoma-metastasis sequence. Aberrant expression of beta-catenin, p16, E-cadherin and c-myc appears to have played important roles in the development and/or progression of CRC, but their precise distribution pattern and associations in different pathologic loci along CRC's pathogenic pathway have not been thoroughly examined. In this study, a tissue microarray (TMA) containing 85 advanced CRCs in different Dukes stages was constructed. In each of 85 cases, tissue specimens from normal mucosa and primary carcinomas in different layers of the bowel wall were included in the TMA. Tissue specimens from matched adenoma, lymph node metastases and distant metastases were obtained from 22, 21 and 21 cases, respectively. Expression patterns of beta-catenin, p16, E-cadherin and c-myc were evaluated by immunohistochemistry. The results revealed that nuclear expression of beta-catenin, p16 and c-myc was quantitatively increased from normal mucosa to premalignant adenoma, primary carcinoma and lymph node metastatic carcinoma; the frequency of nuclear overexpression of beta-catenin and p16 in lymph node metastases was significantly higher than that in distant metastases (p < 0.05). These results suggest an association between nuclear overexpression of beta-catenin and/or p16 and CRC lymph node metastasis but not distant metastasis. The results also showed that correlative high nuclear expression of beta-catenin and c-myc was observed in primary carcinomas involving the serosa and lymph node metastases (p < 0.05) but not in other pathologic regions of CRCs, suggesting that the tumor microenvironment in different pathologic loci of colorectal tumorigenesis and progression may influence c-myc responsiveness to beta-catenin/Tcf activation.
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PMID:Heterogeneous expression and association of beta-catenin, p16 and c-myc in multistage colorectal tumorigenesis and progression detected by tissue microarray. 1460 Oct 48

Multiple genetic and epigenetic alterations in oncogenes, tumour-suppressor genes, cell-cycle regulators, cell adhesion molecules, DNA repair genes and genetic instability as well as telomerase activation are implicated in the multistep process of human stomach carcinogenesis. However, particular combinations of these alterations differ in the two histological types of gastric cancer, indicating that well-differentiated or intestinal-type and poorly differentiated or diffuse-type carcinomas have distinct carcinogenetic pathways. In the multistep process of well-differentiated-type carcinogenesis, the genetic pathway can be divided into three subpathways: an intestinal metaplasia-->adenoma-->carcinoma sequence, an intestinal metaplasia-->carcinoma sequence and de novo. In the multistep process of well-differentiated-type or intestinal-type gastric carcinogenesis, infection with Helicobacter pylori may be a strong trigger for hyperplasia of hTERT-positive 'stem cells' in intestinal metaplasia. Genetic instability and hyperplasia of hTERT-positive stem cells precede replication error at the D1S191 locus, DNA hypermethylation at the D17S5 locus, pS2 loss, RARbeta loss, CD44 abnormal transcripts and p53 mutation, all of which accumulate in at least 30% of incomplete intestinal metaplasias. All of these epigenetic and genetic alterations are common events in intestinal-type gastric cancer. An adenoma-->carcinoma sequence is found in about 20% of gastric adenomas with APC mutations. In addition to these events, p53 mutation and loss of heterozygosity (LOH), reduced p27 expression, cyclin E expression and the presence of c-met 6.0-kb transcripts allow malignant transformation from the above precancerous lesions to intestinal-type gastric cancer. DCC loss, APC mutations, 1q LOH, p27 loss, reduced tumour growth factor (TGF)-beta type I receptor expression, reduced nm23 expression and c-erbB gene amplification are frequently associated with an advanced stage of intestinal-type gastric cancer. The de-novo pathway for carcinogenesis of well-differentiated gastric cancer involves LOH and abnormal expression of the p73 gene that is responsible for the development of foveolar-type gastric cancers with pS2 expression. On the other hand, LOH at chromosome 17p, mutation or LOH of p53 and mutation or loss of E-cadherin are preferentially involved in the development of poorly differentiated gastric cancers. In addition to these changes, gene amplification of K-sam, and c-met and p27 loss as well as reduced nm23 obviously confer progression, metastasis and diffusely productive fibrosis. Mixed gastric carcinomas composed of well-differentiated and poorly differentiated components exhibit some but not all of the molecular events described so far for each of the two types of gastric cancer. Besides these genetic and epigenetic events, well-differentiated and poorly differentiated gastric cancers also organize different patterns of interplay between cancer cells and stromal cells through the growth factor/cytokine receptor system, which plays an important role in cell growth, apoptosis, morphogenesis, angiogenesis, progression and metastasis. Meta-analysis of epidemiological studies and animal models show that both intestinal and diffuse types of gastric cancer are equally associated with H. pylori infection. However, H. pylori infection may play a role only in the initial steps of gastric carcinogenesis. Differences in H. pylori strain, patient age, exogenous or endogenous carcinogens and genetic factors such as DNA polymorphism and genetic instability may be implicated in two distinct major genetic pathways for gastric carcinogenesis.
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PMID:Genetic pathways of two types of gastric cancer. 1505 5

CpG island hypermethylation is a potential means of inactivating tumor suppressor genes, and many genes have been demonstrated to be hypermethylated and silenced in colorectal cancer. However, limited data is available upon the concurrent methylation of multiple genes in colorectal cancer and in its precursor lesion. To address changes in the methylation profiles of multiple genes during colorectal carcinogenesis, we investigated the methylation of 12 genes (APC, COX-2, DAP-kinase, E-cadherin, GSTP1, hMLH1, MGMT, p14, p16, RASSF1A, THBS1, and TIMP3) in normal colon (n=24), colon adenoma (n=95), and colorectal cancer (n=149), using methylation-specific PCR. The average number of these genes methylated per sample was 0.12, 1.8, and 3.0 in normal colon mucosa, adenoma, and carcinoma, respectively, showing a stepwise increase (P<0.001). All the genes were methylated in colorectal cancer at frequencies varying from 51 to 9.4% and colon adenoma displayed methylation for the 11 genes, except for GSTP1, at frequencies varying from 40 to 1.1%. In contrast, normal colon mucosa demonstrated methylation for APC only, at a frequency of 12.5%. The total number of methylated genes per tumor showed a continuous, nonbimodal distribution in colon adenoma or cancer. CpG island hypermethylation exhibited a proclivity toward proximal colon cancer or adenoma, and the average number of genes methylated was higher in proximal colon cancer or adenoma than in distal colon cancer or adenoma, respectively (3.5 vs 2.6, P=0.018 for cancer, and 2.5 vs 1.4, P=0.003 for adenoma). In conclusion, concurrent CpG island methylation is an early and frequent event during colorectal carcinogenesis. It appears that CpG island methylation plays a more important role in proximal colon cancer development than in distal colon cancer development.
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PMID:Aberrant CpG island hypermethylation of multiple genes in colorectal neoplasia. 1512 5


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