UMLS:C0038187 - FACTA Search

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Query: UMLS:C0038187 (starvation)
24,951 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In several pathophysiologic states, i.e., cirrhosis of liver, protein calorie malnutrition, starvation, carbohydrate deprivation, etc., thyroid hormone metabolism is reported to be altered with a decrease in serum T3 and a reciprocal increase in TR3. Uncontrolled diabetes mellitus is a similar state in which glucose does not enter the cells causing cellular starvation and hyperglycemia ensues. Therefore, serum T4, T3, RT3, T3-resin uptake, TSH, and glucose were determined after an overnight fast in 94 male diabetics (aged 28 to 85 years) during a routine follow-up visit to the outpatient clinic and 24 healthy male adults (aged 24 to 81 years). Glycosylated hemoglobin concentrations were measured as well in normal subjects and 16 newly discovered diabetics. In normal subjects, no significant relationships between fasting plasma glucose and T3 and RRT3 levels were observed. In diabetics there was a significant positive (r = 0.611; p less than 0.001) correlation between glucose and RT3. Similarly, a significant negative relationship was observed between glucose and T3 (r = 0.491; p less than 0.001). T4, free T4, T3-resin uptake, and TSH were normal in diabetics. In 16 newly discovered diabetics, with fasting plasma glucose greater than 200 mg/dl, serum T3 rose (96 +/- 5 to 128 +/- 5 ng/dl) and RT3 declined (26.3 +/- 10.4 +/- 1.4 ng/dl) on improvement of hyperglycemia (fasting plasma glucose less than 140 mg/dl) after intensive therapy for 6 to 8 weeks. Glycosylated hemoglobin levels declined as well (14.6 +/- 0.9% to 9.3 +/- 0.7%). These data indicate: (1) thyroid hormone metabolism may be altered in diabetes mellitus with a fall in serum T3 and a reciprocal rise in RT3; and (2) T3 and RT3 concentrations may serve as indicators of metabolic control in diabetes mellitus.
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PMID:Low serum 3, 5, 3'-triiodothyronine (T3) and raised 3, 3', 5'-triidothyronine (reverse T3 or RT3) in diabetes mellitus: normalization on improvement in hyperglycemia. 714 29

Thyroid hormone effects have been studied in both rats and human. In rats ketone body levels are increased by thyroid hormone excess at the initial phase of starvation. Glucose levels are also increased at the initial and late phase of starvation. Ketone bodies production of isolated liver cells from thyroidectomized fed rats (14 +/- 0,2 muMol/g/h) are decreased when compared with cells from thyroidectomized fed rats treated with triiodothyronine 63 +/- 3 muMol/g/h). These changes are related to a direct effect of T3. Ketone bodies levels are increased in Grave's diseases. The increase is significantly correlated to thyroid hormone levels.
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PMID:[Effect of thyroid function on ketogenesis (author's transl)]. 724 39

Short term changes in serum 3,3',5-triiodothyronine (T3) and 3,3'5-triiodothyronine (reverse T3, rT3) were studied in four healthy nonobese male subjects under varying but isocaloric and weight maintaining conditions. The four 1500 kcal diets tested during 72 hr, consisted of: I, 100% fat; II, 50% fat, 50% protein; III, 50% fat, 50% carbohydrate (CHO), and IV, a mixed control diet. The decrease of T3 (50%) and increase of rT3 (123%) in the all-fat diet equalled changes noted in total starvation. In diet III (750 kcal fat, 750 kcal CHO) serum T3 decreased 24% (NS) and serum rT3 rose significantly 34% (p < 0.01). This change occurred in spite of the 750 kcal CHO. This amount of CHO by itself does not introduce changes in thyroid hormone levels and completely restores in refeeding models the alterations of T3 and rT3 after total starvation. The conclusion is drawn that under isocaloric conditions in man fat in high concentration itself may play an active role in inducing changes in peripheral thyroid hormone metabolism.
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PMID:The role of dietary fat in peripheral thyroid hormone metabolism. 742 83

Sixteen-week-old control and obese rats survive longer than 8-wk-old control rats. In addition, unlike the 8-wk-old group, they conserve tissue RNA and protein. To evaluate the basis for this, the effects of starvation on circulating fuels and hormones and the urinary excretion of nitrogen and 3-methylhistidine (3MH) were compared in the three groups. Urinary nitrogen and 3MH diminished during prolonged starvation in 16-wk-old obese and control rats, suggesting that both groups are able to conserve protein and curtail muscle proteolysis. In contrast, urine nitrogen and 3MH did not decrease in 8-wk-old control rats. Protein conservation in the older rats was associated with diminished blood levels of alanine and increased levels of lipid fuels, ketone bodies, and free fatty acids. Although ketone bodies and free fatty acids were also increased during the first few days of starvation in 8-wk-old rats, there was no evidence of protein sparing. In all groups, as fat stores became exhausted terminally, blood lipid levels decreased and protein catabolism increased. Starvation caused insulin to decrease to comparable levels in all rats; however, minimal levels were reached later in the older groups. Thyroxine and triiodothyronine (T3) decreased during the fast in both control groups; however, T3 did not decrease in the obese rats. These findings support the contention that the conservation of protein during prolonged starvation requires the continued availability of lipid fuels. The role of insulin and thyroid hormone in modulating these adaptations is unclear.
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PMID:Starvation in the rat. II. Effect of age and obesity on protein sparing and fuel metabolism. 742 20

A decreased serum triiodothyronine (T3) level is one of the main characteristics of the sick euthyroid syndrome, caused mainly by a decreased 5'-deiodination of thyroxine (T4) in the liver. Cytokines have been implicated in the pathogenesis of the changes in thyroid hormone metabolism during illness. We therefore investigated the role of cytokines produced by the liver macrophages (Kupffer cells) in the development of the sick euthyroid syndrome, which was induced in mice by a single injection of bacterial endotoxin (lipopolysaccharide) or by 24-h starvation. Experiments were carried out with or without previous selective depletion of liver macrophages by intravenous administration of liposome-encapsulated dichloromethylene diphosphonate. Relative to saline-injected pair-fed controls, the administration of lipopolysaccharide caused a decrease of serum T3 and T4 and liver 5'-deiodinase mRNA. Selective depletion of liver macrophages, did not affect these changes. Starvation for 24h decreased serum T3 and T4, associated with a slight decrease of liver 5'-deiodinase mRNA. There were no differences between macrophage-depleted and non-depleted animals in this respect. In summary, selective depletion of liver macrophages did not affect the decrease in serum T3, T4 or liver 5'-deiodinase mRNA induced by lipopolysaccharide or 24-h starvation in mice. We conclude that cytokines produced by Kupffer cells are not involved in the pathogenesis of the sick euthyroid syndrome in this experimental model.
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PMID:Selective macrophage depletion in the liver does not prevent the development of the sick euthyroid syndrome in the mouse. 864 Mar 6

Skeletal muscle is one of the major target organs for thyroid hormone. The muscles most commonly affected are those used during prolonged effort (slow-twitch muscles). One of the major clinical features is the shortening of the Achilles-tendon reflex time in hyperthyroidism and its prolongation in hypothyroidism. Most of the peripheral effects of the thyroid hormones can be ascribed to the action of triiodothyronine (T2), which is produced by de-iodination of thyroxine (T4) in liver and kidney. From the plasma, T3 is actively transported into skeletal muscle. The Ca2+ ATPase in skeletal muscle is responsible for removal of Ca2+ ions from the cytosol into the sarcoplasmic reticulum (SR) during relaxation, and the Na+, K+ ATPase in the plasma membrane is responsible for restoration of the membrane potential after excitation. The concentrations of Ca2+ ATPase and Na+, K+ ATPase in rat skeletal muscle have been shown to increase four- and 10-fold, respectively, in the transition from the hypothyroid to the hyperthyroid state. In humans, a linear correlation between the Na+, K+ ATPase concentration of skeletal muscle and the free T4 index was established. Significant effects of T3 on Ca2+ ATPase and Na+, K+ ATPase can be detected 24 h after a single injection. These effects are mediated by increased production of mRNA for the respective proteins, initiated by binding of T3 to nuclear receptors. Passive fluxes of Ca2+, Na+ and K+ also show a significant rise after T3 treatment. The increase in passive fluxes of Na+ and K+ can be detected before the rise in the concentration of Na+, K+ ATPase, suggesting that T3. In addition to its nuclear effects, may have a direct effect on the plasma membrane. Apart from their significance for muscle function in thyroid disease, the changes in Ca2+ ATPase and Na+, K+ ATPase will be important in other conditions where T3 and T4 levels show dramatic changes, i.e. during postnatal development, starvation and undernutrition, as well as in non-thyroidal illness (low-T3 syndrome).
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PMID:Effects of thyroid hormones on contractility and cation transport in skeletal muscle. 872 93

Effects of starvation on thyroid hormone homeostasis were usually determined after 2 or more days of fasting, however, both in man and in rodents, natural feeding cycles comprise far shorter fasting periods. Therefore serum levels of T4, FT4, T3, FT3 and rT3 were measured in rats refed chow diet for 1, 4, 8 or 24 hours after 14 or 48 hours of starvation. Both short-term (14 h) and long-term fasting (48 h) decreased body weight and serum glucose level. Short-term fast decreased serum FT3 and did not change serum levels of T4, FT4, T3 and rT3. Total T3 and reverse T3 increased after one and 4 hours, free T3 after 4 hours and total T4 after 4 and 8 hours of refeeding. Percent of FT3 did not change after short-term fast, declined after 1 and 4 hours of refeeding, and normalised thereafter. Prolonged starvation (48 h) decreased serum T4, T3, FT3 and % FT3 with no changes in FT4 and rT3. After 24 hours of refeeding only FT3 and % FT3 returned to control levels while total T4 and total T3 were still diminished, and reverse T3 levels did not change. The results suggest that the length of preceding fasting period may strongly influence thyroid hormone homeostasis during fasted-to-fed transition.
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PMID:Thyroid hormones homeostasis in rats refed after short-term and prolonged fasting. 879 39

The effects of short-term food deprivation and photoperiod on plasma thyroid hormone levels of sea bass and sea bream were studied. Animals were acclimated under constant photoperiod regime (15L/9D) and feeding times (2 hr after light onset and 2 hr before light offset). Time-course studies involved monitoring plasma hormone levels every 4 hr throughout 1.5 24-hr cycles. Plasma 3,5, 3'-Triiodo-L-thyronine (T3) and L-thyroxine (T4) were assayed using a newly developed competitive enzyme immunoassay, utilizing acetylcholinesterase as a label of enzymatic tracers. Enzyme immunoassays had sensitivities of 1.25-0.02 and 62.5-0.2 ng/ml for T3 and T4, respectively, and reproducibilities of 3.7 and 5.6% intraassay variation for T3 and T4, respectively; interassay variations for T3 and T4 assays respectively were 1.6%, 11% and 6.6%, 8% for sea bass and sea bream plasma similar to RIA. In sea bass, 3 days of food deprivation resulted in depressed plasma T3 and T4, overriding significant diel variations seen during the second day of starvation. Sea bream displayed a slight decrease of T4 plasma levels while T3 levels remained constant for the whole sampling period. Both thyroidal systems responded to photoperiod with a significant increase in plasma T4 level at the time of light onset. In addition, sea bass also displayed increased T3 levels and decreases in both hormone levels coinciding with "lightoff." Data show different responses of the sea bass and sea bream thyroidal systems to both nutritional state and photoperiod in that the latter state is influenced by the former. Data suggest plasma thyroid levels can be used as a rapid indicator of nutritional status.
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PMID:Development of enzyme immunoassays for 3,5,3'-triiodo-L-thyronine and L-thyroxine: time-course studies on the effect of food deprivation on plasma thyroid hormones in two marine teleosts, sea bass (Dicentrarchus labrax L.) and sea bream (Sparus aurata L.). 881 99

Prolonged fasting is associated with a number of changes in the thyroid axis manifested by low serum T3 and T4 levels and, paradoxically, low or normal TSH. This response is, at least partly, caused by suppression of proTRH gene expression in neurons of the hypothalamic paraventricular nucleus (PVN) and reduced hypothalamic TRH release. Because the fall in thyroid hormone levels can be blunted in mice by the systemic administration of leptin, we raised the possibility that leptin may have an important role in the neuroendocrine regulation of the thyroid axis, through effects on hypophysiotropic neurons producing proTRH. Adult male, Sprague-Dawley rats were either fed normally, fasted for 3 days, or fasted and administered leptin at a dose of 0.5 microg/gm BW i.p. every 6 h. Fasted animals showed significant reduction in plasma total and free T4 and T3 levels compared with controls, that were restored toward normal by the administration of leptin. Percent free T4, but not percent free T3, increased during fasting, further suggesting a reduction in plasma transthyretin levels that did not return to fed levels after leptin administration. By semiquantitative analysis of in situ hybridization autoradiograms, proTRH messenger RNA in medial parvocellular PVN neurons was markedly suppressed in the fasting animals but was restored to normal by leptin administration [fed vs. fast vs. fast/leptin (density units x 10(8)): 8.5 +/- 0.4, 3.2 +/- 0.2, 8.1 +/- 0.8]. In contrast, proTRH messenger RNA in adjacent neurons in the lateral hypothalamus that do not have a hypophysiotropic function remained unchanged by any of the experimental manipulations. These findings indicate that leptin has a selective, central action to modulate the hypothalamic-pituitary-thyroid axis by regulating proTRH gene expression in the PVN but does not have peripheral effects on thyroid-binding proteins. We propose that the fall in circulating leptin levels during fasting resets the set point for feedback inhibition by thyroid hormones on the biosynthesis of hypophysiotropic proTRH, thereby allowing adaptation to starvation.
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PMID:Leptin prevents fasting-induced suppression of prothyrotropin-releasing hormone messenger ribonucleic acid in neurons of the hypothalamic paraventricular nucleus. 916 50

Mitochondrial uncoupling proteins (UCPs) are transporters that are important for thermogenesis. The net result of their activity is the exothermic movement of protons through the inner mitochondrial membrane, uncoupled from ATP synthesis. We have cloned a third member of the UCP family, UCP3. UCP3 is expressed at high levels in muscle and rodent brown adipose tissue. Overexpression in yeast reduced the mitochondrial membrane potential, showing that UCP3 is a functional uncoupling protein. UCP3 RNA levels are regulated by hormonal and dietary manipulations. In contrast, levels of UCP2, a widely expressed UCP family member, showed little hormonal regulation. In particular, muscle UCP3 levels were decreased 3-fold in hypothyroid rats and increased 6-fold in hyperthyroid rats. Thus UCP3 is a strong candidate to explain the effects of thyroid hormone on thermogenesis. White adipose UCP3 levels were greatly increased by treatment with the beta3-adrenergic agonist, CL214613, suggesting another pathway for increasing thermogenesis. UCP3 mRNA levels were also regulated by dexamethasone, leptin, and starvation, albeit differently in muscle and brown adipose tissue. Starvation caused increased muscle and decreased BAT UCP3, suggesting that muscle assumes a larger role in thermoregulation during starvation. The UCP3 gene is located close to that encoding UCP2, in a chromosomal region implicated in previous linkage studies as contributing to obesity.
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PMID:Uncoupling protein-3 is a mediator of thermogenesis regulated by thyroid hormone, beta3-adrenergic agonists, and leptin. 930 58

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