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Target Concepts:
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Query: EC:2.3.1.21 (
CPT
)
4,580
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The main hormones involved in ketone-body metabolism are the anabolic hormone insulin and the primarily catabolic hormones, glucagon, cortisol, catecholamines and growth hormone. These hormones may regulate ketone-body metabolism at three sites: adipose tissue, by regulating fatty acid supply to the liver; the liver itself, by determining the relative activities of the re-esterification and fatty acid oxidation pathways; and the periphery, by influencing the rate of extrahepatic utilization of ketone bodies. The first two are quantitatively the most important. Insulin acts on all three regulatory sites. In adipose tissue lipolysis is inhibited and re-esterification enhanced with consequent decrease of fatty acid release. Both these processes are extremely insulin-sensitive. In the liver insulin increases fatty acid synthesis and esterification. At the same time malonyl-CoA formation is increased, which inhibits the
acylcarnitine transferase
system and thus decreases the transport of fatty acids into mitochondria and hence fatty acid oxidation and ketogenesis. Insulin also has a small stimulatory effect on extrahepatic ketone-body utilization. The effects of glucagon depend on whether insulin is present. In normal man glucagon stimulates insulin secretion and the predominant effect is that of insulin, i.e. decreased ketogenesis. In insulin deficiency glucagon has a mild stimulatory effect on lipolysis, increasing fatty acid supply to the liver. The main effects of glucagon are, however, on the liver. It activates the carnitine acyltransferase system through inhibition of malonyl-CoA synthesis. Fatty acid oxidation is increased and ketogenesis enhanced. The overall effect on the liver depends on the relative amounts of insulin and glucagon present. Studies with somatostatin show that glucagon can increase ketogenesis acutely when insulin secretion is inhibited in normal man, but the effects are short-lived.
Cortisol
has similar effects to glucagon. In the presence of insulin there is a small increase in fatty acid mobilization from adipose tissue, secondary to impaired glucose entry, and perhaps a small effect on lipolysis itself. This fatty acid is, however, directed to triacylglycerol in the liver. In insulin deficiency, again demonstrated by somatostatin infusion, the incoming fatty acidstone-body formation. The mechanism remains obscure. Catecholamines, in contrast, have their most potent effects on adipose tissue, stimulating lipolysis and fatty acid release even in the presence of insulin. They thus act mainly by enhancing precursor supply and have only minor effects on liver and no effect on peripheral utilization. Growth hormone, like glucagon, has little effect in the presence of insulin, but can enhance ketogenesis in insulin deficiency, although again the mechanism is unknown. Thus in normally fed man the effects of insulin will be overriding and little ketogenesis occurs because of limited fatty acid availability in the liver...
...
PMID:Hormonal regulation of ketone-body metabolism in man. 74 14
Carbohydrate metabolism in pregnancy reflects the balance between counterregulatory hormones, which induce insulin resistance, and lactogenic hormones, which stimulate beta-cell proliferation and insulin production. Here we explored the interactions of prolactin (PRL) and glucocorticoids in the regulation of beta-cell gene expression, fatty acid oxidation, and glucose-stimulated insulin secretion (GSIS). In rat insulinoma cells, rat PRL caused 30-50% (P < 0.001) reductions in Forkhead box O (FoxO)-1, peroxisome proliferator activator receptor (PPAR)-gamma coactivator-1alpha (PGC-1alpha), PPARalpha, and carnitine palmitoyltransferase 1 (CPT-1) mRNAs and increased Glut-2 mRNA and GSIS; conversely, dexamethasone (DEX) up-regulated FoxO1, PGC1alpha, PPARalpha,
CPT
-1, and uncoupling protein 2 (UCP-2) mRNAs in insulinoma cells and inhibited GSIS.
Hydrocortisone
had similar effects. The effects of DEX were attenuated by coincubation of cells with PRL. In primary rat islets, PRL reduced FoxO1, PPARalpha, and
CPT
-1 mRNAs, whereas DEX increased FoxO1, PGC1alpha, and UCP-2 mRNAs. The effects of PRL on gene expression were mimicked by constitutive overexpression of signal transducer and activator of transcription-5b. PRL induced signal transducer and activator of transcription-5 binding to a consensus sequence in the rat FoxO1 promoter, reduced nuclear FoxO1 protein levels, and induced its phosphorylation and cytoplasmic redistribution. DEX increased beta-cell fatty acid oxidation and reduced fatty acid esterification; these effects were attenuated by PRL. Thus, lactogens and glucocorticoids have opposing effects on a number of beta-cell genes including FoxO1, PGC1alpha, PPARalpha,
CPT
-1, and UCP-2 and differentially regulate beta-cell Glut-2 expression, fatty acid oxidation, and GSIS. These observations suggest new mechanisms by which lactogens may preserve beta-cell mass and function and maternal glucose tolerance despite the doubling of maternal cortisol concentrations in late gestation.
...
PMID:The interplay of prolactin and the glucocorticoids in the regulation of beta-cell gene expression, fatty acid oxidation, and glucose-stimulated insulin secretion: implications for carbohydrate metabolism in pregnancy. 1859 50
Higher testosterone levels in males have previously been linked to decreased stress reactivity, but in other cases, testosterone has been reported to increase the stress response. We addressed these inconsistencies in a placebo-controlled single-dose testosterone administration study, in which 120 male participants were randomly assigned to undergo a cold-pressor test (
CPT
, a non-social somatic stressor), a socially evaluated cold-pressor test (SECPT, a social-somatic stressor), or a lukewarm water test (LWT, a non-stressful control condition). Throughout the experiment, blood pressure and interbeat intervals were measured continuously, and saliva samples for hormonal analyses were taken repeatedly at predefined time points. When comparing the groups treated with placebo, the SECPT elicited a larger increase in the systolic blood pressure than
CPT
, in agreement with previous studies. However, testosterone administration altered this pattern. Compared to placebo, testosterone increased systolic blood pressure during the
CPT
, whereas the opposite effect was found during the SECPT.
Cortisol
reactivity was not affected by testosterone administration. The CAG repeat polymorphism of the androgen receptor gene was unrelated to the effects of testosterone on the stress response, but it was correlated with blood pressure across the whole sample. Our findings demonstrate that testosterone's effects on the stress response are dependent on the social context. Testosterone's ability to flexibly influence the response to stressors may be an important mechanism through which the hormone promotes adaptive behavior. Our results are also in line with research showing that testosterone decreases social anxiety and suggest it may help to modulate the effects of stress in socially challenging situations.
...
PMID:The effects of testosterone on the physiological response to social and somatic stressors. 3241 73
