Cyclic nucleotide phosphodiesterases, insulin and thyroid hormones

Sensitivity of adipocyte lipolysis to stimulatory and inhibitory agonists in hypothyroidism and starvation

The responsiveness of lipolysis to the stimulatory agonists noradrenaline, corticotropin and glucagon and to the inhibitory agonists N6-phenylisopropyladenosine, prostaglandin E1 and nicotinic acid was investigated with rat white adipocytes incubated with a high concentration of adenosine deaminase (1 unit/ml). The cells were obtained from fed or 48 h-starved euthyroid animals or from fed or starved animals rendered hypothyroid by 4 weeks of treatment with low-iodine diet and propylthiouracil. Hypothyroidism increased sensitivity to and efficacy of all three inhibitory agonists in their opposition of noradrenaline-stimulated lipolysis. Starvation decreased sensitivity to all three inhibitory agonists when opposing basal lipolysis. Hypothyroidism decreased sensitivity to noradrenaline, glucagon and corticotropin by 37-, 4- and 4-fold respectively and decreased the maximum response to these agonists by approx. 50%, 50% and 75% respectively. Starvation reversed decreases in maximum response to these agonists in hypothyroidism. Starvation in the euthyroid state increased sensitivity to glucagon and noradrenaline, but did not alter sensitivity to corticotropin. Cells from hypothyroid rats were relatively insensitive to Bordetella pertussis toxin, which substantially increased basal lipolysis in the euthyroid state.

Pertussis toxin effects on adenylate cyclase activity, cyclic AMP accumulation and lipolysis in adipocytes from hypothyroid, euthyroid and hyperthyroid rats

Adipocytes from hypothyroid rats have a decreased responsiveness to agents that activate adenylate cyclase, whereas cells from hyperthyroid rats have an increased responsiveness as compared to the controls. This is reflected in cyclic AMP accumulation as well as lipolysis. Administration of pertussis toxin to rats or its in vitro addition to adipocytes increased basal lipolysis and cyclic AMP accumulation as well as the response to norepinephrine or forskolin. The effects of thyroid status was not abolished by toxin treatment. Pertussis toxin-catalyzed ADP ribosylation of Ni was increased in adipocyte membranes from hypothyroid rats as compared to those from euthyroid rats. However, no change in sensitivity to N6-(phenylisopropyl)adenosine was observed. The data suggest that the amount of Ni might not be rate-limiting for the inhibitory action of adenosine. A consistent decrease in maximal lipolysis was observed in freshly isolated adipocytes from hypothyroid animals as compared to those from the controls. Such defective maximal lipolysis was not corrected by adenosine deaminase or in vivo administration of pertussis toxin. The relationship between cyclic AMP levels and lipolysis suggests that in fat cells from hypothyroid rats either the cyclic AMP-dependent protein kinase or the lipase activity itself may limit maximal lipolysis. There appears to be multiple effects of thyroid status on lipolysis involving factors other than those affecting adenylate cyclase activation.

Thyroid hormones and fat cell phosphorylation

The phosphorylation of cytosolic and plasma membrane proteins was studied in isolated fat cells from euthyroid and thyroidectomized rats. The analysis, by sodium dodecyl sulphate-polyacrylamide gel electrophoresis, of subcellular fractions of 32P-labelled fat cells revealed the presence of 10-12 phosphoprotein bands in the cytosol. The washed plasma membrane fraction contained 4 major phosphoproteins with estimated molecular weights of 70-67, 60, 42-40 and 26-22 kDa. Two-dimensional analysis of the 32P-labelled phosphoproteins showed that their isoelectric points were between 6.3 and 4.1. The profiles and the isoelectric points were similar in fat cells from euthyroid and thyroidectomized rats. The state of hypothyroidism did not affect the basal phosphorylation of fat cell proteins of the cytosolic or plasma membrane fractions. The incubation of fat cells from euthyroid rats in the presence of isoproterenol or dibutyryl adenosine cyclic monophosphate led to (a) an increase in the 32P labelling of cytosolic proteins which may be subunits of acetyl CoA carboxylase, ATP citrate lyase, hormone-sensitive lipase and other proteins, with apparent molecular weights between 50 and 42 kDa, and (b) an increase in the 32P labelling of plasma membrane proteins of 26-22 kDa. In the case of fat cells from hypothyroid rats, the dibutyryl adenosine cyclic monophosphate increased the 32P labelling of plasma membrane proteins, whereas in the presence of isoproterenol these reactions did not occur. These results show that thyroid hormones control the 32P labelling of proteins of the cytosol and plasma membrane fractions of rat fat cells and therefore, at least in some cases, the lipolytic and lipogenic pathways.

The effect of altered thyroid status on lipid metabolism in Nubian goats

The effects of triiodothyronine (T3)-induced hyperthyroidism and of carbimazole (CZ)-produced hypothyroidism on lipid metabolism were studied in Nubian goats (Capra hircus). T3 treatment decreased the serum, liver and heart triglyceride, cholesterol and phospholipid concentrations. These changes were accompanied by an increase in the activity of lipoprotein lipase (LPL) in the heart and skeletal muscles. CZ treatment at a dose of 90 mg/goat significantly increased the serum triglyceride, liver cholesterol and heart phospholipid. CZ treatment significantly increased the liver and heart triglyceride concentration but the activity of LPL was not affected.

Simulations of the roles of multiple cyclic nucleotide phosphodiesterases

1. Simulations were performed using a model for cellular cyclic AMP metabolism involving a hormone-activated adenylate cyclase and two cyclic nucleotide phosphodiesterases with different Michaelis constants. 2. The response curves of cyclic AMP concentration as a function of hormone concentration were affected by regulating the phosphodiesterases. The maximum velocity of the high-affinity phosphodiesterase (V1) was important in determining the position of the response curve; when v1 was less than the maximal activity of adenylate cyclase (Vc), sigmoid response curves were readily produced. The maximum attainable concentration of cyclic AMP was determined primarily by V1 when Vc less than V1, and primarily by the activity of the low-affinity enzyme when Vc greater than V1 (V2 much greater than Vc in all cases). 3. The glucagon-stimulated adenylate cyclase and insulin-stimulated phosphodiesterase of the rat liver plasma membrane were simulated using experimentally determined values for the enzyme-kinetic parameters, and a considerable potential for regulation of the system by insulin was demonstrated. 4. Other possible functions for the regulation of phosphodiesterases are considered, in particular the value of increasing the speed of response to decreases in hormone concentration.

Thyroid hormone binding to plasma membrane preparations: studies in different thyroid states and tissues

Two orders of high-affinity saturable binding sites for L-T4 and L-T3 were evidenced in purified plasma membrane preparations from rat liver (apparent equilibrium dissociation constant KD for T4 congruent to 0.6 and 23 nM, for T3 congruent to 9 and 237 nM) and kidney (KD for T4 congruent to 4 and 127 nM; for T3 congruent to 15 and 270 nM). Differences of statistical significance were only found for the higher affinity T4 binding site. In contrast, no saturable T4 or T3 binding could be detected in spleen plasma membranes. Testis plasma membranes exhibited 2 sets of T4 binding sites but with a lower affinity than in liver and kidney (KD congruent to 28 and 286 nM), and only one set of T3 binding sites (KD congruent to 266 nM). A good correlation was found between the plasmalemma T4 and T3 binding properties of a tissue and its ability to respond to and/or metabolize thyroid hormones. T4 and T3 binding was also examined in liver plasma membranes of rats under various thyroid status; no difference could be detected in either KD or total capacity for both sets of T4 and T3 binding sites when comparing normal with hyper- or hypothyroid rats. The distribution of plasmalemma high-affinity specific T4 and T3 binding sites in different tissues suggests that these sites are involved in hormone action, or in the transport of these hormones within the cell.

Regulation of cyclic AMP metabolism in the rat erythrocyte during chronic beta-adrenergic stimulation. Evidence for calmodulin-mediated alteration of membrane-bound phosphodiesterase activity

The regulation of cyclic AMP metabolism in the rat erythrocyte has been investigated during chronic exposure to the beta agonist isoproterenol. A triphasic response is observed: 1) an acute increase in cyclic AMP to levels four- to fivefold greater than basal, maximal by 1 minute (Phase I); 2) a gradual decline in cAMP content to levels near basal during the next 15-20 minutes (Phase II) and a second sustained rise in cAMP, maximal by 60 minutes, to a concentration greater than that observed during the first minute (Phase III). Extensively washed Phase II and Phase III cells are refractory to a second challenge by isoproterenol. In phosphodiesterase-inhibited intact Phase II and III cells adenylate cyclase activity is maximally activated. Isoproterenol has no effect on soluble phosphodiesterase activity but increases membrane-bound phosphodiesterase activity 3- and 2.2-fold in Phase II and Phase III cells, respectively. The activation of this membrane-bound enzyme activity appears to be mediated by the calcium-dependent regulatory protein, calmodulin, because 1) the amount of exogenous calmodulin required to achieve half-maximal activation of membrane-bound phosphodiesterase is 3.7, 2.0, and 1.2 micrograms in control, Phase III and Phase II membranes, respectively; and 2) there is less calmodulin in membrane-free lysates prepared from Phase II cells than control cells. These data support the idea that the major mechanism regulating cAMP content in the rat erythrocyte during chronic isoproterenol stimulation is the membrane-bound phosphodiesterase and that there is a translocation of calmodulin from the cytoplasm to the membrane during hormone stimulation.

Effect of thyroid status on insulin action in rat adipocytes and skeletal muscle

Isolated adipocytes and soleus muscles prepared from mature rats, rendered hypothyroid by a low iodine diet and propylthiouracil, markedly resisted the ability of insulin to increase glucose utilization. In adipocytes, the sum of basal d-(1-(14)C)-glucose conversion to CO(2), glyceride-glycerol, and fatty acid was unaltered by hypothyroidism, although conversion to fatty acid was decreased. The response of each of these metabolic pathways to insulin at all concentrations tested was greatly diminished in hypothyroid rat adipocytes. 3-O-Methylglucose transport rates in the presence of insulin were not significantly different in adipocytes from hypothyroid as compared with euthyroid rats, although basal transport rates were significantly higher in the hypothyroid state. Lipolysis and cyclic AMP accumulation in adipocytes from hypothyroid rats in response to theophylline were markedly diminished compared with euthyroid controls, but insulin was about as effective in inhibiting lipolysis in these cells as in those derived from euthyroid animals. The binding of (125)I-insulin to adipocytes at several hormone concentrations was also shown to be unaffected by hypothyroidism. In soleus muscle, basal glucose conversion to H(2)O and glycogen was unaltered in the hypothyroid state, whereas insulin action on these pathways was markedly inhibited. The decrease in muscle insulin responsiveness was less marked than that observed in adipocytes. Uptake of either 2-deoxyglucose or l-arabinose in the presence or absence of insulin was similar in soleus muscles derived from euthryoid vs. hypothyroid rats. Similarly, insulin action on the conversion of soleus muscle glycogen synthase D to the I form in the absence of glucose was unaltered by hypothyroidism. We conclude that (a) hypothyroidism in mature rats leads to a marked decrease in the responsiveness of glucose metabolism in adipocytes and skeletal muscle to insulin; (b) no detectable impairment of the membrane insulin effector systems that mediate the regulation of adipocyte hexose transport and glycogen synthase is caused by hypothyroidism in this animal model; and (c) the cellular defect that leads to apparent insulin resistance of adipocyte and soleus muscle glucose utilization resides at the level of one or more intracellular enzymes involved in glucose catabolism.

The response of cyclic 3',5'-AMP and cyclic 3',5'-GMP phosphodiesterases to experimental diabetes

Alloxan diabetes caused a decrease in cyclic AMP phosphodiesterase in all affected rat tissues. Cyclic GMP phosphodiesterase activity was, however, decreased in adipose and liver, but increased increased in heart and uterus.

Regulation of lipogenesis in adipocytes. Independent effects of thyroid hormones, cyclic AMP and insulin on the uptake of deoxy-D-glucose

Thyroidectomy is known to enhance fat cell phosphodiesterase activity; as a result, the response to lipolytic hormones is markedly reduced. Thyroidectomy also stimulates overall lipogenesis and the uptake of glucose: the present experiments investigated whether there was a correlation between cyclic AMP and glucose uptake. The parameter measured was the transport and phosphorylation (uptake) of deoxy-D-glucose in the presence of two modifiers of the cyclic AMP pool: phosphodiesterase inhibitors and the analogue, dibutyryl cyclic AMP. The inhibition by methylxanthines and dibutyryl cyclic AMP of deoxy-D-glucose uptake observed, was the same in fat cells from normal and thyroidectomized rats: the latter nonetheless still maintained their enhanced glucose uptake. It was therefore concluded that thyroid hormones and cyclic AMP control this step by different, separate pathways. Insulin, well known for its lipogenic effect, enhanced deoxy-D-glucose uptake in fat cells from both normal and thyroidectomized rats to the same extent (about 40%). An additive effect of thyroidectomy and insulin on glucose uptake was thus demonstrated. These results imply that glucose uptake in the adipocyte is controlled by at least three factors: thyroid hormones, cyclic AMP and insulin, each of which can act independently. Maximum glucose uptake is achieved in the presence of a combination of low concentrations of cyclic AMP, of insulin, and in the absence of thyroid hormones.

Cyclic AMP and lipogenesis in fat cells from thyroidectomized rats

Thyroid hormones regulate lipid metabolism by affecting lipogenesis as well as lipolysis. The present paper discusses the way thyroidectomy induced an enhancement in lipogenesis in rat fat cells. The doubling in the conversion of glucose to CO2 and fatty acids seen after thyroidectomy was found to be due to a modification in the actual pathway of glucose metabolism: there was a preferential stimulation of the conversion of glucose to CO2 by the pentose cycle (utilisation of [1-14C]glucose) while the production of fatty acids and glyceride-glycerol proceeded, respectively, much more, or only slightly more, via the pathway of [6-14C]glucose metabolism. Studies employing the phosphodiesterase inhibitor MIX, or the cyclic AMP analogue, DBcAMP showed that the lipogenic process depends on cyclic AMP. As the stimulatory effect of thyroidectomy was not abolished, however, lipogenesis must be under the independent control of both cyclic AMP and absence of thyroid hormones. Insulin, a further mediator of lipogenesis was found to further enhance the already preexisting high conversion of glucose to CO2 in fat cells from thyroidectomized rats. It is concluded that at least three factors modify lipogenesis: thyroidectomy, cyclic AMP and insulin; each achieving its effect in an independent manner.

Hormonal regulation of cAMP-independent protein phosphokinase activities: thyroxine and cortisol control of enzymes from rat liver cytosol

Thyroxine control of cAMP-independent histone and casein phosphokinase activities was studied in thyroidectomized rats treated with thyroxine. All activities were evaluated in the presence of a thermostable inhibitor of cAMP-dependent enzymes. Cytosol enzymes can be resolved by sucrose gradient ultracentrifugation into three peaks of histone kinase activity (3.2S, 5S and 7.2S) and two peaks of casein kinases (3.6S and 7.1S). Neither thyroidectomy nor subsequent treatment of operated animals with thyroxine modifies the total histone kinase activity estimated, either in total cytosol or after its fractionation by the sucrose gradient ultracentrifugation. The activity ratios of different peaks were, however, changed. Casein kinase activity was significantly decreased after thyroidectomy (about 50%). Subsequent treatment with thyroxine restored this activity to its initial value. Sucrose gradient ultracentrifugation analysis showed that thyroxine action on the casein kinase activity is very specific. Only molecules that sediment in the 9S region were significantly stimulated by the hormone. Cortisol action on the casein kinase activity was studied in adrenalectomized animals treated with hormone for 24 h. Cortisol decreases the total casein kinase activity by about 30%. Sucrose gradient ultracentrifugation analysis showed that the population of molecules sedimenting at about 9S was the most sensitive to cortisol. The above data show that both thyroxine and cortisol control, in a selective way, the activities of cAMP-independent protein kinases. The same kinase molecules can be under double control by two different hormones that have opposite effects.

Adaptive responses of enzymes of carbohydrate and lipid metabolism to dietary alteration in genetically obese Zucker rats (fa/fa)

1. Measurements have been made of the activities of enzymes of the glycolytic route, the pentose phosphate pathway, the tricarboxylic acid cycle and lipogenesis in liver and adipose tissue from genetically obese (fa/fa) rats and their lean litter mates (fa/ --). The effect of food restriction for a period of three weeks on the enzyme profile of liver and adipose tissue of the obese rat was also studied. 2. The most striking increases in enzyme activity in livers from obese rats were: (a) among enzymes of lipogenesis; ATP-citrate lyase, acetyl-CoA carboxylase, fatty acid synthetase, malate dehydrogenase (decarboxylating) and cytoplasmic glycerolphosphate dehydrogenase; (b) within the pentose phosphate pathway; glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase; (c) within the glycolytic pathway; glucokinase, pyruvate kinase and lactate dehydrogenase. All of these enzymes showed a significant increase in activity on the basis of U/g liver and U/mg DNA. In adipose tissue all the enzymes of lipogenesis, of the glycolytic route, of the oxidative segment of the pentose phosphate pathway and of the tricarboxylic acid cycle were increased when expressed as U/2 fat pads or as U/mg DNA. 3. The restriction of the food intake of obese rats to that consumed by their lean litter mates for periods of three weeks did not produce the expected adaptive decrease in enzymes of lipogenesis; in adipose tissue, only ATP-citrate lyase and malate dehydrogenase (decarboxylating) showed a marked decrease; no significant change was found in adipose tissue or liver of the activities of acetyl-CoA carboxylase and fatty acid synthetase, when expressed on a cell basis (U/mg DNA). The non-oxidative enzymes of the pentose phosphate pathway and enzymes involved in glycerogenesis (pyruvate carboxylase, malate dehydrogenase and phosphoenolpyruvate carboxykinase) all increased in adipose tissue from limit-fed obese rats. 4. The rate of conversion of specifically labelled glucose to (14C)O2 and 14C-labelled lipid by pieces of adipose tissue and by liver slices was also measured. Insulin caused an increase in the conversion of (1-14C)glucose to (14C)O2 and 14C-labelled lipid in obese rats fed ad libitum, limit-fed rats and in their lean litter mates. 5. The results are discussed in relation to the raised insulin and hypothyroid state of the obese rat. The effect of this altered hormonal status on the activity of cyclic nucleotide phosphodiesterases and cellular levels of adenosine 3' :5'-monophosphate and guanosine 3' :5'-monophosphate and guanosine 3' :5'-monophosphate in relation to the obese syndrome is considered.