Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
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Gene/Protein
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Target Concepts:
Gene/Protein
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Query: UMLS:C0001430 (
adenoma
)
21,222
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Chromosome abnormalities found in pediatric solid tumors include deletions, translocations, homogeneously staining regions (hsr)/double minutes (dms), and ploidy abnormalities. The discovery of a 13q14 deletion found in lymphocytes of patients with retinoblastoma and developmental delay has led to the cloning of the retinoblastoma gene. Likewise the discovery of an 11p13 deletion in lymphocytes of patients with Wilms' tumor and aniridia has led to the cloning of the
Wilms' tumor gene
. Chromosome deletions found in tumor cells are considered to play a role on the homologous deletion of cancer suppressor genes. Recently, various translocations have been found mostly in soft tissue sarcomas; i.e. t(11;22) in Ewing's sarcoma, t(2;13) in alveolar rhabdomyosarcoma, t(3;8) in pleomorphic
adenoma
, t(3;12) in lipoma, t(12;16) in liposarcoma, t(12;14) in leiomyosarcoma, and t(X;18) in synovial sarcoma. These translocations provide important information on the difficult diagnosis of soft tissue sarcomas, and on the selection of chemotherapy protocol. Tumor cells in advanced stage neuroblastomas often show hsr/dms, in which N-myc amplification occurs. While near triploidy was regularly found in early-stage neuroblastomas, near-diploidy or near-tetraploidy was usually found in advanced stage tumors. Among various prognostic factors, N-myc copy numbers and tumor cell ploidies had the largest influence on the prognosis of neuroblastoma patients. Cytogenetic and molecular genetic analyses on tumor cells are becoming increasingly important for the diagnosis of pediatric solid tumors, and the prediction of the patients' prognosis.
...
PMID:[Cytogenetics in pediatric solid tumors]. 217 98
Twelve metanephric adenomas (MA) were studied for allelic imbalance at chromosomal regions known to be involved in the genetics of papillary renal cell tumors (RCT) and Wilms' tumors as well as for loci on chromosome 2p13-21. DNA was isolated from paraffin slides, and allelic status was established by fluorescently-labeled microsatellite markers. No allelic changes were seen in the
Wilms' tumor gene
region at chromosome 11p13 and in the papillary RCT gene region at chromosome 17q21.32. We delineated a tumor suppressor gene region of approximately 8-centimorgan genetic distance between loci D2S2153 and D2S380 on chromosome 2p13. Allelic changes at this region occurred in 56% of informative cases. Our results provide molecular evidence that MA is a genetic entity, and it can be differentiated from both Wilms' tumor and papillary renal cell
adenoma
.
...
PMID:Mapping a tumor suppressor gene to chromosome 2p13 in metanephric adenoma by microsatellite allelotyping. 1117 2
The expression levels of the
Wilms' tumor gene
WT1 were examined in 34 primary thyroid cancers (24 papillary, 5 follicular, 1 anaplastic, and 4 medullary carcinomas), 17 thyroid follicular adenomas, and 6 normal-appearing thyroid tissues using quantitative real-time reverse transcriptase-polymerase chain reaction (RT-PCR). In 33 of 34 thyroid cancers, the WT1 mRNA was expressed at levels ranging from 5.0 x 10 (-5) to 8.3 x 10 (-2) levels (WT1 expression level in K562 leukemic cells was defined as 1.0). The WT1 mRNA expression levels were significantly higher than those in either thyroid follicular adenomas (P < 0.001) or normal-appearing thyroid tissues (P < 0.01). Immunohistochemical analysis confirmed the expression of WT1 protein in 20 of 21 thyroid cancers with WT1 mRNA expression. WT1 protein was also detected in 6 of 7 follicular adenomas with WT1 mRNA expression. However, the intensity of staining of WT1 protein in
adenoma
cells was weaker than that in cancer cells and its expression was restricted to approximately 30-80% of
adenoma
cells in the tumors examined. The direct sequencing analysis of the WT1 genomic DNA showed no mutations in any of the 10 exons of the WT1 gene in all of the 9 different thyroid cancers. These findings indicate an important role of the wild-type WT1 gene in the tumorigenesis of primary thyroid cancer.
...
PMID:Overexpression of the Wilms' tumor gene WT1 in primary thyroid cancer. 1284 69
The overexpression of
Wilms' tumor gene
product WT1, which acts as a tumor suppressor or oncogene, has been reported in various malignancies. Recent studies have shown that the interaction partner Wnt-4 is upregulated in pituitary adenomas dependent on the Pit-1 lineage (somatotrophs, lactotrophs, and thyrotrophs). However, no data on WT1 expression in nontumorous pituitary tissue or pituitary adenomas is available to date. We investigated WT1 expression in 90 paraffin-embedded pituitary adenomas, including eight atypical adenomas, and in 28 nontumorous pituitary glands by immunohistochemistry. WT1 is absent in epithelial cells of all nontumorous pituitary glands and in 87 out of 90 pituitary adenomas. Only two GHomas (including one atypical
adenoma
) and one gonadotropin-producing
adenoma
expressed WT1 in the cytoplasm of single tumor cells without nuclear staining. There is no evidence that WT1 does regulate the Wnt-4/beta-catenin-independent pathway which is activated in the Pit-1-expressing subset of pituitary adenomas.
...
PMID:No evidence for WT1 involvement in a beta-catenin-independent activation of the Wnt signaling pathway in pituitary adenomas. 1943 43
