Role of thyroid hormones in the modification of diet-induced thermogenesis by propranolol

The effect of thyroid hormones on the reduction in resting metabolic rate by the beta-blocker propranolol has been investigated in young pigs. Oxygen consumption was measured 12 to 20 hr after the last meal in euthyroid and hypothyroid animals on a high or low level of energy intake. The increase in resting metabolic rate in animals on the high energy intake was reduced by propranolol in the euthyroid controls but not in those animals made hypothyroid by methimazole. Thus at least part of the action of propranolol to decrease diet-induced thermogenesis depends on its interaction with thyroid hormones.     

Effect of thyroid hormones on delayed type hypersensitivity reaction

The effect of long term administration of thyroid hormones and its deprivation on delayed type hypersensitivity (DTH) reaction to 2-4 dinitrochlorobenzene (DNCB) was studied. Animals were either pre-treated with thyroid hormones (T3 or T4) for 15 days and then subjected to DNCB skin test or the animals received thyroid hormones and simultaneously subjected to DNCB skin test. In both the cases DTH reaction was found to be increased significantly. When DNCB skin test was performed in the thyroidectomized animals, DNCB skin reaction was significantly decreased and the reaction was restored to normal following supplementation of thyroid hormones to the thyroidectomized animals. TLC and ALC were increased significantly following hormone treatment and thyroidectomized animals. TLC hand, induced significant depression in the count which was restored by hormone administration to the thyroidectomized animals.     

Effect of acidosis on skeletal muscle metabolism with and without propranolol

Does the stimulatory effect of circulating catecholamines counteract the inhibitory effect of acidosis on skeletal muscle metabolism? To investigate this possibility, we studied gastrocnemii in dogs breathing either air (n = 10) or 4% carbon dioxide in air (n = 10) at rest and during contractions. In five dogs from each group, we infused propranolol into the arterial supply of the right and left muscles for 40 min. After 30 min of infusion, the left muscle was stimulated at 3 Hz for 10 min. During the 10th min of contractions, we removed and froze both muscles in liquid nitrogen. Oxygen uptake and blood flow to the left muscle prior to or during stimulation was not affected by acidosis either with or without propranolol. Glycogen concentration in resting muscle was unaffected by acidosis with or without propranolol. There was an acidosis related decrease of approximately 50% in the glycolytic intermediates (glucose 6-phosphate, fructose 1,6-diphosphate, alpha-glycerol phosphate, and dihydroxyacetone phosphate) in unstimulated muscles without beta-blockade. At rest, acidosis decreased muscle lactate by 50% with and 64% without propranolol, but lactate release was decreased only with acidosis without propranolol (1.4-0.1 mumols/kg.s). Acidosis without propranolol had no effect on the changes in glycogen concentration or the change in the concentration of glycolytic intermediates resulting from contractions. In beta-blocked muscle, the difference between stimulated and unstimulated concentrations of glycogen and glycolytic intermediates including lactate was 20-50% smaller with acidosis. Thus, with beta-blockade, the acidotic effects at rest disappeared and an inhibition of the metabolic adjustment to contractions appeared, indicating that circulating catecholamines do modify some metabolic effects of acidosis.