Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UNIPROT:P43146 (tumour suppressor)
 5,935 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The transformation of the normal fully differentiated thyroid follicular cell to the rapidly growing undifferentiated anaplastic thyroid carcinoma cell involves a number of stages which have been defined morphologically and are now being related to various growth pathways and to molecular biological defects. The two main factors involved in this transformation are growth stimulation and mutagenesis. Growth stimulation alone, through elevated TSH, can lead to the development of thyroid tumours, usually benign, and retaining TSH dependency in some cases. Mutagens alone, if growth is suppressed, do not produce tumours, the combination of mutagens and increased growth is a potent carcinogenic regime. Non-genotoxic carcinogenesis in the thyroid involves growth, without mutagenesis the agent often causes this through affecting one component of thyroid hormone synthesis or metabolism, leading to a fall in thyroid hormone levels and a rise in TSH. Growth stimulation increases the rate of cell division, and therefore increases the chance of a mutation. Continued growth increases the change of subsequent events, in particular loss of heterozygosity in a tumour suppressor gene. The main oncogenes involved in human thyroid carcinogens are ras in the follicular tumour pathway, and ret in the papillary carcinoma pathway. p53 is involved in the progression of either papillary or follicular adenoma to an undifferentiated carcinoma. In experimental thyroid carcinogenesis, ras is again involved, with a link between the mutagenic agent used and the type of ras gene showing mutation. Analysis of the involvement of different growth factors and oncogenes in thyroid carcinogenesis suggests that genes related to the two receptors concerned with normal TSH stimulated growth, TSH receptor and the IGF1 receptor may be involved in the progression of thyroid tumours of follicular pathology. Several tyrosine kinase receptors with unknown ligands or of uncertain physiological function are linked to papillary carcinoma. The recent large increase in papillary carcinoma of the thyroid in children exposed to fallout from the Chernobyl nuclear accident underlines the importance of understanding the pathobiology of thyroid neoplasia.
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PMID:Mechanisms and pathogenesis of thyroid cancer in animals and man. 853 19

There have been many recent advances in our understanding of thyroid disease, including thyroid physiology, the molecular biology of thyroid neoplasms, guidelines for the management of surgical thyroid disease and the operative approach to thyroidectomy. The control of thyroid growth and function is better understood now that the thyroid stimulating hormone (TSH) receptor has been characterized as a G-protein coupled transmembrane receptor. The peripheral action of thyroid hormones is also better understood in terms of their interaction with nuclear thyroid hormone receptors. An adenoma-carcinoma sequence for the development of thyroid neoplasms has been proposed based on the characterization of a number of proto-oncogenes and tumour suppressor genes, and different pathways for the development of papillary and follicular thyroid carcinoma have been demonstrated. Fine needle biopsy has become, over the past few years, the principal diagnostic technique for evaluation of thyroid nodules, and has resulted in a significant reduction in the need for surgery for benign thyroid nodules. The approach to the management of thyroid carcinoma can now be based on comprehensive scoring systems for assigning patients to a particular risk group, the most recent of which is the MACIS system based on distant metastases (M), age (A), completeness of resection (C), invasion (I) and size (S). The capsular technique of thyroidectomy as described has now been shown to be the best method to preserve parathyroid blood supply, protect the recurrent laryngeal nerve and minimize the complications of thyroid surgery.
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PMID:The aetiology, investigation and management of surgical disorders of the thyroid gland. 867 80

Selenium is an essential trace element for humans, playing an important role in various major metabolic pathways. Selenium helps to protect the body from the poisonous effects of heavy metals and other harmful substances. Medical studies have provided evidence of selenium supplementation in preventing certain cancers. Low and too high selenium (Se) status correlates with increased risk of e.g. lung, larynx, colorectal and prostate cancers. A higher level of selenium and supplementation with selenium has been shown to be associated with substantially reduced cancer mortality. Selenium exerts its biological roles through selenoproteins, which are involved in oxidoreductions, redox signalling, antioxidant defence, thyroid hormone metabolism and immune responses. Checkpoint kinase 2 (CHEK2) is an important signal transducer of cellular responses to DNA damage and acts as a tumour suppressor gene. Mutations in the CHEK2 gene have been shown to be associated with increased risks of several cancers. Four common mutations in CHEK2 gene (1100delC, IVS2+1G>A, del5395 and I157T) have been identified in the Polish population. Studies have provided evidence that CHEK2-truncating and/or missense mutations are associated with increased risk of breast, prostate, thyroid, colon and kidney cancers. The variability in penetrance and cancer expression in CHEK2 mutation carriers can probably be explained by the influence of other genetic or environmental factors. One of the possible candidates is Se, which together with genetic variations in selenoprotein genes may influence susceptibility to cancer risk.
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PMID:Can selenium be a modifier of cancer risk in CHEK2 mutation carriers? 2410 7