Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
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Target Concepts:
Gene/Protein
Disease
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Drug
Enzyme
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Query: EC:3.6.1.3 (
ATPase
)
65,361
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The heart is a major target organ for thyroid hormone action, and marked changes occur in cardiac function in patients with hypothyroidism or hyperthyroidism. Triiodothyronine (T3)-induced changes in cardiac function can result from direct or indirect T3 effects. Direct T3 effects result from T3 action in the heart itself and are mediated by nuclear or extranuclear mechanisms. Extranuclear T3 effects, which occur independently of nuclear T3 receptor binding and increases in protein synthesis, influence primarily the transport of amino acids, sugars, and calcium across the cell membrane. Nuclear T3 effects are mediated by the binding of T3 to specific nuclear receptor proteins, which results in increased transcription of T3-responsive cardiac genes. The T3 receptor is a member of the ligand-activated transcription factor family and is encoded by cellular erythroblastosis A (c-erb A) genes. T3 increases the heart transcription of the myosin heavy chain (MHC) alpha gene and decreases the transcription of the MHC beta gene, leading to an increase of myosin V1 and a decrease in myosin V3 isoenzymes. Myosin V1, which is composed of two MHC alpha, has a higher myosin ATPase activity than myosin V3, which contains two MHC beta. The globular head of myosin V1, with its higher
ATPase
activity, leads to a more rapid movement of the globular head of myosin along the thin filament, resulting in an increased velocity of contraction. T3 also leads to an increase in the speed of diastolic relaxation, which is caused by the more efficient pumping of the calcium ATPase of the sarcoplasmic reticulum (SR). This T3 effect results from T3-induced increases in the level of the mRNA coding for the SR calcium ATPase protein, leading to an increased number of calcium ATPase pump units in the SR. Overall, T3 leads to an increase in ATP consumption in the heart. In addition, less chemical energy of ATP is used for contractile purposes and more of it goes toward heat production, which causes a decreased efficiency of the contractile process in the hyperthyroid heart. The pathophysiologic basis for
myxedema
is the opposite of that discussed for the hyperthyroid heart. In addition to decreased direct effects of thyroid hormone in cardiac myocytes, indirect effects occur through decreases in peripheral oxygen consumption and changes in hemodynamic parameters. Myofibrillar swelling with loss of striation and interstitial fibrosis occurs on histologic examination of hypothyroid hearts. In addition, accumulation of mucopolysaccharide substances (Glycosaminoglycans) can be demonstrated. On electron microscopic examination, mitochondria show disruption and lipid inclusion. Cardiac papillary muscle obtained from animals with hypothyroidism shows a depression of the force velocity curve and reduced rate of tension development, indicating significant contractile abnormalities. In patients with hypothyroidism, a true enhanced incidence of hypertension (increased peripheral vascular resistance) has been found. In addition, hypercholesterolemia and impairment of fatty acid mobilization are associated with
myxedema
and present additional risk factors for the development of atherosclerotic cardiovascular disease.
...
PMID:[Cardiovascular effects of thyroid hormones]. 906 69
This review will discuss generalized
myxedema
as it develops in hypothyroidism. First, the precipitating conditions (thyroprivic trophoprivic + goitrous forms) and the clinical manifestations of thyroid hormone deficiency are presented. Pathobiochemical and pathophysiological factors that lead to the main manifestations include retention of fluid, retention of sodium and hyponatremia. In particular are primary and direct consequences of reduced thyroid hormone levels, and secondary or indirect consequences, such as cardiovascular and renal derangements. In hypothyroidism many biochemical disturbances result. Most important is the interstitial deposition of hydrophilic mucopolysaccharides, which in turn lead to fluid and Na retention and impairment of blood circulation and lymphatic drainage.
Myxedema
, therefore, is to a large extent a lymphatic edema. Hyponatremia is an indirect consequence of the lack of T3 and is directly caused by impaired renal Na reabsorption. Renal Na,K-
ATPase
is reduced in specific segments. The often discussed role of inappropriate elevation of circulating ADH does not seem to be a key factor in
myxedema
. Impaired capacity of renal water excretion is caused by reduced GFR. We discuss the time dependent development of the derangement of different organ systems, and include recently published biochemical results, according to which the lack of T3 interferes not only with the metabolism of numerous compounds of the interstitial matrix, but also with cell surface proteins and intracellular proteins of microfilaments. Finally, we refer briefly to pretibial
myxedema
in states of hyperthyroidism, that is, infiltrative dermopathy in Graves' disease, which is caused by poorly understood autoimmune processes.
...
PMID:Myxedema. 918 11
