Glucose metabolism in insulin administered euthyroid, hypothyroid and hyperthyroid rats

Glucose metabolism was studied as evidenced by the sugar and pyruvic acid levels in blood and glycogen and pyruvic acid content of tissues in euthyroid, hypothyroid and hyperthyroid rats by giving insulin. Results show that in a normal thyroxine-excess insulin state, the rise in blood sugar was less, glycogenesis was much enhanced and glycolysis was reduced in comparison to these data in the euthyroid state. When tyroxine deficiency was associated with excess insulin, glycogenesis was enhanced further and an almost complete inhibition of glycolysis was observed. In excess thyroxine-excess insulin state glycogenesis was increased at the expense of glycolysis in comparison to the finding in the hyperthyroid state. Thus exogenous insulin in the euthyroid state altered the pattern of carbohydrate metabolism enhancing glycogenesis and inhibiting glycolysis. In a low thyroxine-excess insulin state, further enhancement of glycogenesis and inhibition of glycolysis were observed. But in an excess thyroxine-excess insulin state, the higher thyroxine activity was somewhat neutralized by higher insulin action allowing glycogenesis with glucose to proceed to some extent.     

The selective control of glycolysis,gluconeogenesis and glycogenesis by temporal insulin patterns

Insulin governs systemic glucose metabolism, including glycolysis, gluconeogenesis and glycogenesis, through temporal change and absolute concentration. However, how insulin‐signalling pathway selectively regulates glycolysis, gluconeogenesis and glycogenesis remains to be elucidated. To address this issue, we experimentally measured metabolites in glucose metabolism in response to insulin. Step stimulation of insulin induced transient response of glycolysis and glycogenesis, and sustained response of gluconeogenesis and extracellular glucose concentration (GLC _ex ). Based on the experimental results, we constructed a simple computational model that characterises response of insulin‐signalling‐dependent glucose metabolism. The model revealed that the network motifs of glycolysis and glycogenesis pathways constitute a feedforward (FF) with substrate depletion and incoherent feedforward loop (iFFL), respectively, enabling glycolysis and glycogenesis responsive to temporal changes of insulin rather than its absolute concentration. In contrast, the network motifs of gluconeogenesis pathway constituted a FF inhibition, enabling gluconeogenesis responsive to absolute concentration of insulin regardless of its temporal patterns. GLC _ex was regulated by gluconeogenesis and glycolysis. These results demonstrate the selective control mechanism of glucose metabolism by temporal patterns of insulin.     

Effect of exercise training on insulin binding and glucose metabolism in mouse soleus muscle

Training stimulates glucose uptake and metabolism by muscles independent of a rise in serum glucose. Whether this increased insulin action is associated with enhanced insulin binding in muscles is unknown. We studied the effect of 6 weeks of treadmill running on insulin binding, uptake of 2-deoxy-D-glucose, glycolysis, and glycogenesis by the soleus muscle of Swiss Webster mice. Training was progressively increased. The in vitro studies using intact soleus preparations were done 48 h after the last exercise bout. Training increased insulin binding, insulin-stimulated uptake of 2-deoxy-D-glucose, and glycogenesis but not glycolysis in the soleus. Our data suggest that the enhanced glucose uptake and metabolism in muscles induced by exercise training are associated with an increase in insulin binding.     

The in vitro effect of corticosterone on insulin binding and glucose metabolism in mouse skeletal muscles

We studied the in vitro effect of corticosterone on insulin binding, uptake of 2-deoxy-D-glucose, glycolysis, and glycogenesis in the soleus and extensor digitorum longus (EDL) of Swiss-Webster mice. In each experiment, one muscle (soleus/EDL) was incubated with corticosterone (0.1, 1, 50, and 100 micrograms/mL) and the respective contralateral muscle was incubated without corticosterone, but at the same insulin and pH levels. Corticosterone did not affect insulin binding in both muscles. However, corticosterone decreased the uptake of 2-deoxy-D-glucose and the rate of glycolysis and glycogenesis in both muscles when the dose was pharmacologic (50 and 100 micrograms/mL), but not when it was physiologic (0.1 and 1 microgram/mL). For glycolysis and glycogenesis, the suppression was greater in the EDL when compared with the soleus. This suppression was seen in both basal and insulin-stimulated conditions. In this in vitro system, where the experimental muscle is not exposed to prior hyperinsulinemia as in the in vivo model, corticosterone, at pharmacologic doses, affects postreceptor events without altering the insulin binding in the skeletal muscle.     

Effects of exercise on insulin binding and glucose metabolism in muscle

To elucidate the mechanism of enhanced insulin sensitivity by muscle after exercise, we studied insulin binding, 2-deoxy-D-[1-14C]glucose (2-DOG) uptake and [5-3H]glucose utilization in glycolysis and glycogenesis in soleus and extensor digitorum longus (EDL) muscles of mice after 60 min of treadmill exercise. In the soleus, glycogenesis was increased after exercise (P less than 0.05) and remained sensitive to the action of insulin. Postexercise insulin-stimulated glycolysis was also increased in the soleus (P less than 0.05). In the EDL, glycogenesis was increased after exercise (P less than 0.05). However, this was already maximal in the absence of insulin and was not further stimulated by insulin (0.1-4 nM). The disposal of glucose occurred primarily via the glycolytic pathway (greater than 60%) in the soleus and EDL at rest and after exercise. The uptake of 2-DOG uptake was not altered in the soleus after exercise (4 h incubation at 18 degrees C). However, with 1-h incubations at 37 degrees C, a marked increase in 2-DOG uptake after exercise was observed in the soleus (P less than 0.05) in the absence (0 nM) and presence of insulin (0.2-4 nM) (P less than 0.05). A similar postexercise increase in 2-DOG uptake occurred in EDL. Despite the marked increase in glucose uptake and metabolism, no changes in insulin binding were apparent in either EDL or soleus at 37 degrees C or 18 degrees C. This study shows that the postexercise increase of glucose disposal does not appear to be directly attributable to increments in insulin binding to slow-twitch and fast-twitch muscles.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hindlimb suspension increases insulin binding and glucose metabolism

After 28 days of hindlimb-suspension, insulin binding, 2-deoxy-D-glucose (2-DG) uptake, and glucose metabolism (glycolysis and glycogenesis) were determined at various insulin concentrations (0.2-30 nM) in soleus muscle of young (18-day-old) and adult (150-day-old) rats. Compared with age-matched controls the young (YS) and adult suspended (AS) rats had lower soleus and body weights and insulin levels (P less than 0.05). Per milligram of protein, insulin binding, 2-DG uptake, and the rate of glycolysis were increased by approximately 200%, and the rate of glycogenesis was increased approximately 100% in the YS group (P less than 0.05). Except for a reduction in glycogenesis (P less than 0.05) all other parameters also increased in the AS rats (P less than 0.05). On the basis of the whole muscle the rate of glucose metabolism (glycogenesis + glycolysis) was reduced in the YS rats (P less than 0.05), but in the AS rats glucose metabolism was similar to the controls. Thus the increased glucose metabolism (i.e., per milligram of protein) in the YS and AS groups may represent a compensatory response by atrophied muscle to attempt to sustain glucose removal from the circulation. Because greater insulin binding occurred in YS muscle [35% slow-twitch (ST)] than in the control group (70% ST), and greater insulin binding occurred in the AS (81% ST) than in the control group (90% ST), higher insulin binding capacities are not always related to a high proportion of ST muscle fibers. In conclusion, after hindlimb suspension, marked increments in insulin binding and glucose metabolism occur in the soleus muscle.     

Role of membranes and energy-producing reactions in cellular processing of insulin in primary cultures of rat hepatocytes

Incubation of primary cultures of rat hepatocytes with the local anesthetics, procaine or lidocaine, had little or no effect on insulin uptake or degradation but caused an inhibition of insulin-stimulated glycogenesis. While exposure of cultures to the amines, monodansylcadaverine or CH3NH2, resulted in significant dose-dependent decreases in glycogenesis, only monodansylcadaverine (an inhibitor of receptor clustering) decreased uptake whereas CH3NH2 (a lysosomotropic agent) caused increases in both insulin uptake and degradation. When cells were treated with agents which inhibit glycolysis (NaF, 2-deoxy-D-glucose) or oxidative metabolism (2,4-dinitrophenol, carbonyl cyanide m-chlorophenyl hydrazone, NaN3, antimycin A), pronounced inhibitions of each of the bioactivities studied (syntheses of glycogen, protein, lipid) were observed, but only the glycolytic inhibitors decreased insulin uptake. These results suggest that insulin is internalized by an endocytotic process involving receptor clustering and requiring metabolic energy derived from glycolysis. The post-receptor biosynthetic processes involved in the expression of the biological activities of insulin (syntheses of glycogen, protein, lipid) require energy produced by oxidative metabolism while the degradation of insulin is carried out by nonlysosomal mechanisms which are not energy-requiring.     

Glucagon and regulation of glucose metabolism

As a counterregulatory hormone for insulin, glucagon plays a critical role in maintaining glucose homeostasis in vivo in both animals and humans. To increase blood glucose, glucagon promotes hepatic glucose output by increasing glycogenolysis and gluconeogenesis and by decreasing glycogenesis and glycolysis in a concerted fashion via multiple mechanisms. Compared with healthy subjects, diabetic patients and animals have abnormal secretion of not only insulin but also glucagon. Hyperglucagonemia and altered insulin-to-glucagon ratios play important roles in initiating and maintaining pathological hyperglycemic states. Not surprisingly, glucagon and glucagon receptor have been pursued extensively in recent years as potential targets for the therapeutic treatment of diabetes.     

Effect of down-regulation and return of insulin receptors on glycogen synthesis in cultured rat hepatocytes

The dependence of the regulation of insulin receptors by insulin on the time hepatocytes were maintained in culture and the relationship between the return of down-regulated receptors and glycogen synthesis from labelled glucose were investigated in primary cultures of adult rat hepatocytes. Insulin receptor numbers, but not ligand affinity, decreased significantly within the first 24 h of culture, even in the absence of insulin, and then returned to the immediate 'post-attachment' level during 24-48 h. Therefore, down-regulation of insulin receptors by 10 nmol/l insulin was only minor during the 1st day in culture, but amounted to 50% of control levels after the 2nd day, whereas the rate of insulin degradation remained unaltered throughout the entire period of culture. When down-regulated monolayers were switched to insulin-free medium, receptors returned to control levels within 5-10 h. The reduced basal rate of glycogenesis as well as insulin-sensitivity and insulin responsiveness of this metabolic pathway also gradually increased to control levels. However, the time-dependent receptor return was dissociated from the increase in insulin-sensitivity, emphasising the importance of postbinding events. Since the changes both in basal rates and in insulin responsiveness of glycogenesis during the period of receptor return were inversely related to differences in the actual glycogen content between control and down-regulated cells, cellular glycogen content might participate in the regulation of glycogenesis as a 'feedback inhibitor'.     

Dissociation between insulin binding and glucose utilization after intense exercise in mouse skeletal muscles

Since there are data to indicate that heavy exercise decreases insulin binding to skeletal muscle at a point when glucose uptake is known to be augmented, we tested the hypothesis that insulin-stimulated glucose uptake and metabolism are dissociated from insulin binding after exercise. Therefore, insulin binding, 2-deoxy-d-glucose (2-DOG) uptake and glucose incorporation into glycogen and glycolysis were compared in soleus and EDL muscles of intensively exercised (2-3 h) mice and non-exercised mice. Basal 2-DOG uptake was increased in the exercised EDL (P less than 0.05) but not in the exercised soleus (P greater than 0.05). However, in both muscles intense exercise increased insulin-stimulated (0.1-16 nM) 2-DOG uptake (P less than 0.05). The rates of glycogenesis were increased in both the exercised muscles (P less than 0.05) as was the rate of glycolysis in the exercise soleus (P less than 0.05). Glycolysis was not altered in the EDL (P greater than 0.05). In the face of the increased 2-DOG uptake and glucose metabolism in the exercised muscles, insulin binding was not altered in the exercised soleus muscle (P greater than 0.05) and was decreased in the exercised EDL (P less than 0.05). These results indicate that after intense exercise there is a dissociation of insulin binding from insulin action on glucose uptake and metabolism in skeletal muscles.     

The use of a cell-free perfusate in the perfused rat hindquarter: methodological concerns

The viability of using a cell-free perfusate in a rat hindlimb preparation to assess skeletal muscle glycogenesis was investigated. A perfusate containing 10 mM glucose and 10 microCi (1 Ci = 37 GBq) of D-[5-3H]glucose was recycled for a 60-min period. In agreement with other studies using more complex media, oxygen uptake of the preparation indicated adequate tissue oxygenation (8 mumol.min-1.g-1). Skeletal muscle fiber type heterogeneity in basal glycogen synthesis from glucose was shown (slow oxidative greater than fast oxidative glycolytic greater than fast glycolytic fibres). Insulin (4.2 mU/mL) markedly stimulated glycogenesis from D-[5-3H]glucose in the soleus (slow oxidative fiber), red gastrocnemius (fast oxidative glycolytic fiber), and white gastrocnemius muscles (p less than 0.05). A recent report indicates that tissue edema in this preparation did not affect insulin responsiveness of the tissue. In contrast, our observations indicate that glucos uptake was enhanced by insulin when edema was absent (p less than 0.05), but not when edema was present (p less than 0.05). In addition, the presence of tissue edema negated insulin-mediated glycogenesis in slow oxidative and fast oxidative glycolytic muscle (p less than 0.05 compared with control) but not in fast glycolytic muscle (p less than 0.05). These data warrant caution when using a cell-free media in the perfused rat hindquarter; however, in the absence of edema, normal responses of glucose metabolism are observed.     

Topical insulin and accumulation of excitotoxic and other amino acids in ischemic rat cerebral cortex

Insulin plays a neuroprotectant role in the brain and spinal cord during ischemia. However, studies have shown insulin to increase the sensitivity of cultured cortical cells to glutamate toxicity. The present study looked at the relationship between topically administered insulin (1 mIU insulin/ml and 100 mIU insulin/ml) during a four-vessel model of global ischemia and the accumulation of amino acids, especially glutamate, from the ischemic rat cerebral cortex. The lower dose of insulin was found to attenuate the release of excitotoxic and other amino acids from the cortex in ischemia/reperfusion. This may occur because insulin increases glucose availability to glial cells resulting in maintenance of glycolysis and ionic pumps that can reduce glutamate release and maintain uptake during ischemia/reperfusion. The higher dose of insulin, which significantly increased the amount of aspartate, glutamate, taurine, and GABA during reperfusion, may act to stimulate the amount of glycogen stored in astrocytes, reducing the availability of glucose for metabolic purposes.     

Effects of mild heat shock on glycogenesis and its regulation by insulin in cultured fetal hepatocytes

The effects of a mild heat shock were investigated using cultured 15-day-old fetal rat hepatocytes in which an acute glucocorticoid-dependent glycogenic response to insulin was present. After exposure from 15 min to 2 h at 42.5°C, cell surface [¹²⁵I]insulin binding progressively decreased down to 60% of the value shown in cells kept at 37°C, due to a decrease in the apparent number of insulin binding sites with little change in insulin receptor affinity. In parallel cultures, protein labeling with [³⁵S]methionine exhibited stimulated synthesis of specific proteins, in particular, 73-kDa Hsc (heat shock cognate) and 72-kDa Hsp (heat shock protein). When cells were returned to 37°C after 2 h at 42.5°C, cell surface insulin binding showed a two-third restoration within 3 h (insulin receptor half-life = 13 h), with similar concomitant return of Hsps72,73 synthesis to preinduction levels. The rate of [¹⁴C]glucose incorporation into glycogen measured at 37°C after 1- to 2-h heat treatment revealed a striking yet transient increase in basal glycogenesis (up to 5-fold). At the same time, the glycogenesis stimulation by insulin was reduced (from 3.2 to 1.4—fold), whereas that induced by a glucose load was maintained. Induction of thermotolerance after a first heating was obtained for the heat shock-dependent events except for the enhanced basal glycogenesis. In insulin-unresponsive cells grown in the absence of glucocorticoids, heat shock decreased the glycogenic capacity without modifying the glucose load stimulation, supporting the hypothesis that insulin and thermal stimulation of glycogenesis share at least part of the same pathway. Inverse variations were observed between Hsps72,73 synthesis and both cell surface insulin receptor level and insulin glycogenic response in fetal hepatocytes experiencing heat stress. © 1995 Wiley-Liss, Inc.     

Insulin acutely improves mitochondrial function of rat and human skeletal muscle by increasing coupling efficiency of oxidative phosphorylation

Insulin is essential for the regulation of fuel metabolism and triggers the uptake of glucose by skeletal muscle. The imported glucose is either stored or broken down, as insulin stimulates glycogenesis and ATP synthesis. The mechanism by which ATP production is increased is incompletely understood at present and, generally, relatively little functional information is available on the effect of insulin on mitochondrial function. In this paper we have exploited extracellular flux technology to investigate insulin effects on the bioenergetics of rat (L6) and human skeletal muscle myoblasts and myotubes. We demonstrate that a 20-min insulin exposure significantly increases (i) the cell respiratory control ratio, (ii) the coupling efficiency of oxidative phosphorylation, and (iii) the glucose sensitivity of anaerobic glycolysis. The improvement of mitochondrial function is explained by an insulin-induced immediate decrease of mitochondrial proton leak. Palmitate exposure annuls the beneficial mitochondrial effects of insulin. Our data improve the mechanistic understanding of insulin-stimulated ATP synthesis, and reveal a hitherto undisclosed insulin sensitivity of cellular bioenergetics that suggests a novel way of detecting insulin responsiveness of cells.     

Compared roles of glucose, galactose and fructose as glycogen precursors during the acute response to insulin in cultured rat foetal hepatocytes

1. The efficiency of the contribution of hexoses to basal- and stimulated-glycogenesis, when studied in cultured 18 day-old rat foetal hepatocytes in the presence of glucose, was as follows: galactose greater than glucose greater than fructose. 2. Glucose deprivation had opposite effects on the contributions of [14C]galactose (decreased) and [14C]fructose (increased) to glycogenesis, which occurred independently of insulin and were reversed by glucose concentrations as low as 30-100 microM. 3. The stimulation of glycogenesis by insulin measured with [14C]glucose (3.2-fold) was superior to that obtained with either [14C]galactose or [14C]fructose (2.7-fold in both cases), which revealed a specific beneficial effect of insulin on glucose contribution.     

Potential role of kinins in the effects of taurine in high-fructose-fed rats

The present work investigates the involvement of kinins in the effects of taurine in fructose-fed hypertensive rats. The effects of taurine on blood pressure, plasma glucose, insulin, and the insulin sensitivity index were determined. Angiotensin-converting enzyme (ACE) activity and nitrite content in plasma, plasma and tissue kallikrein activity, and taurine content were also investigated. The blood pressure changes in response to the coadministration of inhibitors of the synthesis of nitric oxide (NO), prostaglandins (PGs), or a kinin receptor blocker along with taurine was also evaluated. Fructose-fed rats had higher blood pressure and elevated plasma levels of glucose and insulin. Kallikrein activity, taurine, and nitrite contents were significantly lower in fructose-fed rats as compared with controls. The increases in systolic blood pressure, hyperglycemia, and hyperinsulinemia were controlled by taurine administration in fructose-fed rats. ACE activity was lower, while nitrite and taurine content and kallikrein activity were higher, in taurine-supplemented rats as compared with fructose-fed rats. A significant increase in blood pressure was observed in rats cotreated with the inhibitors Hoe 140 (a kinin receptor blocker), L-NAME (a NO synthase inhibitor), or indomethacin (a PG synthesis inhibitor) with taurine for 1 week as compared with taurine-treated fructose-fed rats. This suggests that the antihypertensive effect of taurine in fructose-fed rats was blocked by the inhibitors. Augmented kallikrein activity and, hence, increased kinin availability may be implicated in the effects of taurine in fructose-fed hypertensive rats.     

Oxygen-transport function and carbohydrate metabolism in rat erythrocytes during hypoxic hypoxia and treatment with insulin

Hemoglobin affinity to oxygen, enzyme activity and metabolite concentration of carbohydrate metabolism were determined in erythrocytes of rats which were administered insulin solution. A valid decrease of the hemoglobin value P50 (pressure of hemoglobin half-saturation with oxygen), as well as a decrease of the enzyme activity of 2,3-diphosphoglycerate shunt and increase of the activity of regulatory glycolysis enzymes--hexokinase and pyruvate kinase in erythrocytes with multiple introduction of hormones to animals have been established. Such changes in rat erythrocytes were registered with the simultaneous effect of insulin and hypoxic hypoxia evoked by the "lift" of rats in the altitude chamber to the conditional altitude of 9000 m. It is found out that preliminary injection of insulin considerably increases survivability of rats under hypoxic hypoxia at great altitudes.     

miR-200s Contribute to Interleukin-6 (IL-6)-induced Insulin Resistance in Hepatocytes

By influencing the activity of the PI3K/AKT pathway, IL-6 acts as an important regulator of hepatic insulin resistance. miR-200s have been shown to control growth by regulating PI3K, but the role of miR-200s in the development of hepatic insulin resistance remains unclear. The present study showed that elevated serum concentration of IL-6 is associated with decreased levels of miR-200s, impaired activation of the AKT/glycogen synthase kinase (GSK) pathway, and reduced glycogenesis that occurred in the livers of db/db mice. As shown in the murine NCTC 1469 hepatocytes and the primary hepatocytes treated with 10 ng/ml IL-6 for 24 h and in 12-week-old male C57BL/6J mice injected with 16 μg/ml IL-6 by pumps for 7 days, IL-6 administration induced insulin resistance through down-regulation of miR-200s. Moreover, IL-6 treatment inhibited the phosphorylation of AKT and GSK and decreased the glycogenesis. The effects of IL-6 could be diminished by suppression of FOG2 expression. We concluded that IL-6 treatment may impair the activities of the PI3K/AKT/GSK pathway and inhibit the synthesis of glycogen, perhaps via down-regulating miR-200s while augmenting FOG2 expression.     

Global gene expression responses to waterlogging in roots of sesame (Sesamum indicum L.)

Waterlogging stress lowers yields in sesame (Sesamum indicum L.). A major component of waterlogging stress is the lack of oxygen available to submerged tissues. Although the morphology and physiology of plants grown under anaerobic conditions have been studied in detail, limited work has been done to elucidate adaptations at the molecular level. To gain comprehensive insight into how sesame responds to hypoxia at the genome level, we performed gene expression profiling at two time points during a 36-h period following hypoxic treatment using a whole-genome RNA-Seq analysis. We identified sets of significantly positively and negatively expressed genes (induced and repressed, respectively) in response to hypoxia with distinct temporal profiles. The genes that were affected were associated with glycolysis, nitrogen metabolism, starch and sucrose metabolism and plant hormone signal transduction and indicated the upregulation of particular pathways (glycolysis/glycogenesis) in the Kyoto Encyclopedia of Genes and Genomes. Moreover, significant changes in the expression of genes were found for pathways, including flavone and flavonol biosynthesis, steroid biosynthesis, photosynthesis, cysteine and methionine metabolism, glutathione metabolism, as well as phenylpropanoid biosynthesis, spliceosome, circadian rhythm. This study helps in elucidating the molecular mechanisms of waterlogging tolerance and provides a basis for the genetic engineering of sesame.     

Insulin, not glucose, controls hepatocellular glycogen deposition. A re-evaluation of the role of both agents in cultured liver cells

The direct effects of insulin and glucose on glycogen accumulation were compared using monolayers of chicken embryo hepatocytes which, when cultured in chemically defined medium without hormones, retain viability for several days but become depleted of glycogen. The data strongly suggest that insulin is the major direct signal for hepatic glycogen synthesis, while glucose supports glycogen accumulation primarily in its role as a substrate. Insulin alone, when added to the cells in physiological concentrations, either shortly after isolation or throughout culture, restored glycogen to the maximal levels found in the liver of the fed chicken. Addition of increasing amounts of glucose in the absence of insulin, in contrast, yielded proportional but limited increases in glycogen deposition attaining not more than 30% of the maximal storage capacity of the cells. This hormone-independent glycogenesis was characterized by a 30-min burst of glycogen deposition immediately following a stepped increase of glucose, with no detectable change in glycogen synthase activity. Insulin-dependent glycogenesis evidenced a much slower rate of glycogen deposition and was accompanied by a near tripling of glycogen synthase activity. Insulin-induced glycogen stores were broken down following removal of the hormone, even when glucose was present in great excess, indicating that the cells require insulin to maintain as well as build up maximal levels of glycogen. In the presence of glucagon, insulin-induced glycogen stores were rapidly degraded, but glucose-induced glycogenesis was not inhibited. The actions of insulin and glucose in this system are both qualitatively and quantitatively similar to those that have been observed in the diabetic animal.