MDMA-like behavioral effects of N-substituted piperazines in the mouse.

Few studies have characterized the subjective effects of N-substituted piperazines, but these drugs show potential for abuse in humans, and have often been associated with MDMA ("ecstasy") in this regard. The aim of the present study was to test the capacity of N-substituted piperazines to induce a head twitch response, alter locomotor activity, and induce MDMA-like discriminative stimulus effects in mice. Various doses of l-benzylpiperazine (BZP), 1-(3-trifluoromethylphenyl) piperazine (TFMPP), 1-(3-methoxybenzyl) piperazine (m-MeO-BZP) or meta-chlorophenyl piperazine (m-CPP) were administered to mice to determine the effects on these behavioral endpoints. BZP, but not its meta-methoxyl analogue, increased locomotor activity in a dose-dependent manner; the phenylpiperazines and m-MeO-BZP only decreased locomotor activity. TFMPP was the only compound active in the head twitch assay, eliciting a moderate head twitch response which was comparable to that previously observed with the MDMA enantiomers. BZP, TFMPP and m-CPP fully substituted in S(+)-MDMA-trained animals, but did not elicit significant drug lever responding in mice trained to discriminate R(-)-MDMA. m-MeO-BZP partially substituted for both training drugs. The present results suggest that BZP has stimulant-like effects, and that TFMPP has hallucinogen-like effects. Their structural analogues, however, do not share these behavioral profiles. Further studies into the relationships between the N-substituted piperazines and MDMA are warranted.

GLUT4 ablation in mice results in redistribution of IRAP to the plasma membrane.

Glucose transporter (GLUT) 4 is the insulin responsive glucose transporter in adipose tissue, skeletal muscle, and heart. Insulin elicits increased glucose uptake by recruiting GLUT4 from a specialized intracellular storage site to the cell surface. Expression of various proteins that colocalize with GLUT4 and/or are involved in insulin-stimulated GLUT4 translocation was examined in adipocytes as well as skeletal and cardiac muscles from GLUT4 null mice. Our data demonstrate that expression of insulin-regulated aminopeptidase (IRAP) is divergently regulated in GLUT4 null tissues, e.g., upregulated 1.6-fold in GLUT4 null adipocytes and downregulated in GLUT4 null skeletal muscle (40%) and heart (60%). IRAP exhibited abnormal subcellular distribution and impaired insulin-stimulated translocation in GLUT4-deficient tissues. We propose the compartment containing IRAP and proteins normally associated with GLUT4 vesicle traffics constitutively to the cell surface in GLUT4 null adipocytes and skeletal muscle.

Localization and regulation of GLUTx1 glucose transporter in the hippocampus of streptozotocin diabetic rats.

We describe the localization of the recently identified glucose transporter GLUTx1 and the regulation of GLUTx1 in the hippocampus of diabetic and control rats. GLUTx1 mRNA and protein exhibit a unique distribution when compared with other glucose transporter isoforms expressed in the rat hippocampus. In particular, GLUTx1 mRNA was detected in hippocampal pyramidal neurons and granule neurons of the dentate gyrus as well as in nonprincipal neurons. With immunohistochemistry, GLUTx1 protein expression is limited to neuronal cell bodies and the most proximal dendrites, unlike GLUT3 expression that is observed throughout the neuropil. Immunoblot analysis of hippocampal membrane fractions revealed that GLUTx1 protein expression is primarily localized to the intracellular compartment and exhibits limited association with the plasma membrane. In streptozotocin diabetic rats compared with vehicle-treated controls, quantitative autoradiography showed increased GLUTx1 mRNA levels in pyramidal neurons and granule neurons; up-regulation of GLUTx1 mRNA also was found in nonprincipal cells, as shown by single-cell emulsion autoradiography. In contrast, diabetic and control rats expressed similar levels of hippocampal GLUTx1 protein. These results indicate that GLUTx1 mRNA and protein have a unique expression pattern in rat hippocampus and suggest that streptozotocin diabetes increases steady-state mRNA levels in the absence of concomitant increases in GLUTx1 protein expression.

Preservation of glucose metabolism in hypertrophic GLUT4-null hearts.

GLUT4-null mice lacking the insulin-sensitive glucose transporter are not diabetic but do exhibit abnormalities in glucose and lipid metabolism. The most striking morphological consequence of ablating GLUT4 is cardiac hypertrophy. GLUT4-null hearts display characteristics of hypertrophy caused by hypertension. However, GLUT4-null mice have normal blood pressure and maintain a normal cardiac contractile protein profile. Unexpectedly, although they lack the predominant glucose transporter in the heart, GLUT4-null hearts transport glucose and synthesize glycogen at normal levels, but gene expression of rate-limiting enzymes involved in fatty acid oxidation is decreased. The GLUT4-null heart represents a unique model of hypertrophy that may be used to study the consequences of altered substrate utilization in normal and pathophysiological conditions.

Reduced glucose uptake precedes insulin signaling defects in adipocytes from heterozygous GLUT4 knockout mice.

Decreased GLUT4 expression, impaired insulin receptor (IR), IRS-1, and pp60/IRS-3 tyrosine phosphorylation are characteristics of adipocytes from insulin-resistant animal models and obese NIDDM humans. However, the sequence of events leading to the development of insulin signaling defects and the significance of decreased GLUT4 expression in causing adipocyte insulin resistance are unknown. The present study used male heterozygous GLUT4 knockout mice (GLUT4(+/-)) as a novel model of diabetes to study the development of insulin signaling defects in adipocytes with the progression of whole body insulin resistance and diabetes. Male GLUT4(+/-) mice with normal fed glycemia and insulinemia (N/N), normal fed glycemia and hyperinsulinemia (N/H), and fed hyperglycemia with hyperinsulinemia (H/H) exist at all ages. The expression of GLUT4 protein and the maximal insulin-stimulated glucose transport was 50% decreased in adipocytes from all three groups. Insulin signaling was normal in N/N adipose cells. From 35 to 70% reductions in insulin-stimulated tyrosine phosphorylation of IR, IRS-1, and pp60/IRS-3 were noted with no changes in the cellular content of IR, IRS-1, and p85 in N/H adipocytes. Insulin-stimulated protein tyrosine phosphorylation was further decreased to 12-23% in H/H adipose cells accompanied by 42% decreased IR and 80% increased p85 expression. Insulin-stimulated, IRS-1-associated PI3 kinase activity was decreased by 20% in N/H and 68% reduced in H/H GLUT4(+/-) adipocytes. However, total insulin-stimulated PI3 kinase activity was normal in H/H GLUT4(+/-) adipocytes. Taken together, these results strongly suggest that hyperinsulinemia triggers a reduction of IR tyrosine kinase activity that is further exacerbated by the appearance of hyperglycemia. However, the insulin signaling cascade has sufficient plasticity to accommodate significant changes in specific components without further reducing glucose uptake. Furthermore, the data indicate that the cellular content of GLUT4 is the rate-limiting factor in mediating maximal insulin-stimulated glucose uptake in GLUT4(+/-) adipocytes.

Amelioration of insulin resistance but not hyperinsulinemia in obese mice overexpressing GLUT4 selectively in skeletal muscle.

The effects of gold-thioglucose (GTG) treatment were examined in mice overexpressing GLUT4 selectively in skeletal muscle (MLC-GLUT4 mice) and in age-matched controls. Groups of MLC-GLUT4 and control mice were injected with GTG or saline at 5 weeks of age. At 12 weeks following the injections, GTG-treated control mice exhibited a 35% increase in body weight versus saline-treated controls. Similarly, a 30% increase in body weight was observed in GTG-treated MLC-GLUT4 mice compared with saline-treated MLC-GLUT4 mice 12 weeks after the injections. In saline-treated lean MLC-GLUT4 and control mice, intraperitoneal injection of insulin decreased blood glucose in 1 hour by 63% and 38%, respectively. Insulin also decreased blood glucose by 40% in GTG-treated obese MLC-GLUT4 mice after 1 hour. However, insulin did not reduce blood glucose levels in GTG-treated obese control mice. The ability of insulin to clear blood glucose in GTG-treated obese MLC-GLUT4 mice is associated with increased skeletal muscle GLUT4 content and white adipose tissue (WAT) GLUT4 content as compared with GTG-treated obese controls. However, fasting blood glucose levels in GTG-treated obese MLC-GLUT4 and control mice were elevated by approximately 30% compared with saline-treated groups. Lastly, although GTG-treated obese MLC-GLUT4 mice exhibited improved glucose clearance in response to insulin, they nevertheless remained as hyperinsulinemic as GTG-treated obese control mice. These results suggest that genetic overexpression of GLUT4 in skeletal muscle may ameliorate the development of insulin resistance associated with obesity but cannot restore normal glucose and insulin levels.

Metabolic and therapeutic lessons from genetic manipulation of GLUT4.

This review focuses on the effects of varying levels of GLUT4, the insulin-sensitive glucose transporter, on insulin sensitivity and whole body glucose homeostasis. Three mouse models are discussed including MLC-GLUT4 mice which overexpress GLUT4 specifically in skeletal muscle, GLUT4 null mice which express no GLUT4, and the MLC-GLUT4 null mice which express GLUT4 only in skeletal muscle. Overexpressing GLUT4 specifically in the skeletal muscle results in increased insulin sensitivity in the MLC-GLUT4 mice. In contrast, the GLUT4 null mice exhibit insulin intolerance accompanied by abnormalities in glucose and lipid metabolism. Restoring GLUT4 expression in skeletal muscle in the MLC-GLUT4 null mice results in normal glucose metabolism but continued abnormal lipid metabolism. The results of experiments using these mouse models demonstrates that modifying the expression of GLUT4 profoundly affects whole body insulin action and consequently glucose and lipid metabolism.

GLUT4 heterozygous knockout mice develop muscle insulin resistance and diabetes.

GLUT4, the insulin-responsive glucose transporter, plays an important role in postprandial glucose disposal. Altered GLUT4 activity is suggested to be one of the factors responsible for decreased glucose uptake in muscle and adipose tissue in obesity and diabetes. To assess the effect of GLUT4 expression on whole-body glucose homeostasis, we disrupted the murine GLUT4 gene by homologous recombination. Male mice heterozygous for the mutation (GLUT4 +/-) exhibited a decrease in GLUT4 expression in adipose tissue and skeletal muscle. This decrease in GLUT4 expression did not result in obesity but led to increased serum glucose and insulin, reduced muscle glucose uptake, hypertension, and diabetic histopathologies in the heart and liver similar to those of humans with non-insulin-dependent diabetes mellitus (NIDDM). The male GLUT4 +/- mice represent a good model for studying the development of NIDDM without the complications associated with obesity.

Peripheral but not hepatic insulin resistance in mice with one disrupted allele of the glucose transporter type 4 (GLUT4) gene.

Glucose transporter type 4 (GLUT4) is insulin responsive and is expressed in striated muscle and adipose tissue. To investigate the impact of a partial deficiency in the level of GLUT4 on in vivo insulin action, we examined glucose disposal and hepatic glucose production (HGP) during hyperinsulinemic clamp studies in 4-5-mo-old conscious mice with one disrupted GLUT4 allele [GLUT4 (+/-)], compared with wild-type control mice [WT (+/+)]. GLUT4 (+/-) mice were studied before the onset of hyperglycemia and had normal plasma glucose levels and a 50% increase in the fasting (6 h) plasma insulin concentrations. GLUT4 protein in muscle was approximately 45% less in GLUT4 (+/-) than in WT (+/+). Euglycemic hyperinsulinemic clamp studies were performed in combination with [3-3H]glucose to measure the rate of appearance of glucose and HGP, with [U-14C]-2-deoxyglucose to estimate muscle glucose transport in vivo, and with [U-14C]lactate to assess hepatic glucose fluxes. During the clamp studies, the rates of glucose infusion, glucose disappearance, glycolysis, glycogen synthesis, and muscle glucose uptake were approximately 55% decreased in GLUT4 (+/-), compared with WT (+/+) mice. The decreased rate of in vivo glycogen synthesis was due to decreased stimulation of glucose transport since insulin's activation of muscle glycogen synthase was similar in GLUT4 (+/-) and in WT (+/+) mice. By contrast, the ability of hyperinsulinemia to inhibit HGP was unaffected in GLUT4 (+/-). The normal regulation of hepatic glucose metabolism in GLUT4 (+/-) mice was further supported by the similar intrahepatic distribution of liver glucose fluxes through glucose cycling, gluconeogenesis, and glycogenolysis. We conclude that the disruption of one allele of the GLUT4 gene leads to severe peripheral but not hepatic insulin resistance. Thus, varying levels of GLUT4 protein in striated muscle and adipose tissue can markedly alter whole body glucose disposal. These differences most likely account for the interindividual variations in peripheral insulin action.

Muscle-specific transgenic complementation of GLUT4-deficient mice. Effects on glucose but not lipid metabolism.

We have taken the approach of introducing the muscle-specific myosin light chain (MLC)-GLUT4 transgene into the GLUT4-null background to assess the relative role of muscle and adipose tissue GLUT4 in the etiology of the GLUT4-null phenotype. The resulting MLC-GLUT4-null mice express GLUT4 predominantly in the fast-twitch extensor digitorum longus (EDL) muscle. GLUT4 is nearly absent in female white adipose tissue (WAT) and slow-twitch soleus muscle of both sexes of MLC-GLUT4-null mice. GLUT4 content in male MLC-GLUT4-null WAT is 20% of that in control mice. In transgenically complemented EDL muscle, 2-deoxyglucose (2-DOG) uptake was restored to normal (male) or above normal (female) levels. In contrast, 2-DOG uptake in slow-twitch soleus muscle of MLC-GLUT4-null mice was not normalized. With the normalization of glucose uptake in fast-twitch skeletal muscle, whole body insulin action was restored in MLC-GLUT4-null mice, as shown by the results of the insulin tolerance test. These results demonstrate that skeletal muscle GLUT4 is a major regulator of skeletal muscle and whole body glucose metabolism. Despite normal skeletal muscle glucose uptake and insulin action, the MLC-GLUT4-null mice exhibited decreased adipose tissue deposits, adipocyte size, and fed plasma FFA levels that are characteristic of GLUT4-null mice. Together these results indicate that the defects in skeletal muscle and whole body glucose metabolism and adipose tissue in GLUT4-null mice arise independently.

Metabolic and molecular consequences of modifying GLUT4 expression in skeletal muscle.

We have described mouse models in which the expression levels of GLUT4 in skeletal muscle have been modified. GLUT4 null mice, which lack skeletal-muscle GLUT4, are insulin-resistant. In contrast, MLC-GLUT4 mice, which overexpress GLUT4 specifically in the skeletal muscle, exhibit an increase in insulin-sensitivity and glucose disposal. Restoring GLUT4 expression specifically in the skeletal muscle of the GLUT4 null mice by mating with MLC-GLUT4 transgenic mice normalizes the reduced glucose uptake and glucose metabolism of the skeletal muscle of the MLC-GLUT4 null mouse. These models represent unique agents to dissect the mechanism for insulin signalling and GLUT4 translocation in skeletal muscle that expresses varying levels of GLUT4.

Molecular and cellular aspects of the glucagon receptor: role in diabetes and metabolism.

The role of glucagon in eliciting hyperglycaemia has been studied extensively for more than 20 years. However, little has been learned about the specific targeted tissues and intracellular effects of glucagon since no specific causal interactions have been established between glucagon and the so called "glucagon-binding site". Indeed, glucagon and related hormones, such as glucagon-like peptide, glucoin-sulinotropic hormone and vasoactive intestinal peptide acting through different receptors, have similar effects in hyperglycaemic syndromes. The recent cloning of the glucagon receptor (GR) encoding sequences has clarified many aspects of its structure as well as its integrated role in the cell and the entire body. The GR contains seven transmembrane domains and is characterised by a conserved G-protein binding site and a large amino-terminal domain containing the amino-acid residues mainly involved in ligand binding. The GR is expressed in liver, pancreatic beta cells, kidney, adipose tissues, heart, and vascular tissues, as well as in some region of brain, stomach, and adrenal glands. The precise role of the GR in most of these tissues is still unclear. However, with the cloning of the coding sequences, genetic manipulations of the GR should provide specific indications of the normal metabolic effects of the GR system on these tissues and how altered glucagon signalling might contribute to the development of diabetes.

The metabolic consequences of altered glucose transporter expression in transgenic mice.

Glucose transporters are a family of membrane proteins which mediate glucose uptake across the cell membrane. The facilitative glucose transporter proteins are products of unique genes and are expressed in a tissue-specific manner. They are very similar structurally, containing 12 putative membrane spanning domains. Functionally they vary in their affinity for glucose and sensitivity to hormones such as insulin. Glucose homeostasis depends mainly on controlled changes in glucose transport in insulin-responsive tissues such as skeletal muscle and adipose cells where both glucose transporter 1 and glucose transporter 4 are expressed. Glucose transporter 4 is the major glucose transporter in these tissues and translocates from an intracellular vesicle to the cell membrane in response to insulin. Alterations of the level of expression of these glucose transporters should result in changes in insulin sensitivity and modification of whole-body metabolism. To test these hypotheses transgenic mouse models have been generated which overexpress glucose transporters in specific tissues or in the whole body. Glucose transporter 1 and glucose transporter 4 have been overexpressed specifically in skeletal muscle and glucose transporter 4 specifically in adipose tissue. Mice have also been made which overexpress glucose transporter 4 in the whole body. Using homologous recombination technology to disrupt the glucose transporter 4 gene, a "knockout" mouse has been created which expresses no glucose transporter 4. The metabolic consequences of these genetic manipulations on the level of expression of glucose transporters in the mouse are reviewed. The future applications of transgenic mouse technology in creating models which mimic human diseases are also discussed.

Diverse effects of Glut 4 ablation on glucose uptake and glycogen synthesis in red and white skeletal muscle.

The ability of muscles from Glut 4-null mice to take up and metabolize glucose has been studied in the isolated white EDL and red soleus muscles. In EDL muscles from male or female Glut 4-null mice, basal deoxyglucose uptake was lower than in control muscles and was not stimulated by insulin. In parallel, glycogen synthesis and content were decreased. Soleus muscles from male Glut 4-null mice took up twice more deoxyglucose in the absence of insulin than control muscles, but did not respond to insulin. In females, soleus deoxyglucose uptake measured in the absence of hormone was similar in Glut 4-null mice and in control mice. This uptake was stimulated twofold in Glut 4-null mice and threefold in control mice. Basal glycogen synthesis was increased by 4- and 2.2-fold in male and female null mice, respectively, compared to controls, and insulin had no or small (20% stimulation over basal) effect. These results indicate that while EDL muscles behaved as expected, soleus muscles were able to take up a large amount of glucose in the absence (males) or the presence of insulin (females). Whether this is due to a change in Glut 1 intrinsic activity or targeting and/or to the appearance of another glucose transporter remains to be determined.

Enhanced insulin action due to targeted GLUT4 overexpression exclusively in muscle.

Dysregulation of GLUT4, the insulin-responsive glucose transporter, is associated with insulin resistance in skeletal muscle. Although skeletal muscle is the major target of insulin action, muscle GLUT4 has not been linked causally to whole-body insulin sensitivity and regulation of glucose homeostasis. To address this, we generated a line of transgenic mice that overexpresses GLUT4 in skeletal muscle. We demonstrate that restricted overexpression of GLUT4 in fast-twitch skeletal muscles of myosin light chain (MLC)-GLUT4 transgenic mice induces a 2.5-fold increase in insulin-stimulated 2-deoxyglucose uptake in transgene-overexpressing cells. Consequently, glycogen content is increased in the fast-twitch skeletal muscles under insulin action (5.75 +/- 1.02 vs. 3.24 +/- 0.26 mg/g). This indicates that insulin-stimulated glucose transport is partly rate-limiting for glycogen synthesis. At the whole-body level, insulin-stimulated glucose turnover is increased 2.5-fold in unconscious MLC-GLUT4 mice. Plasma glucose and insulin levels in MLC-GLUT4 mice are altered as a result of increased insulin action. In 2- to 3-month-old MLC-GLUT4 mice, fasting insulin levels are decreased (0.43 +/- 0.05 vs. 0.74 +/- 0.10 microgram/l), whereas normal fasting glycemia is maintained. Conversely, 7- to 9-month-old MLC-GLUT4 mice exhibit decreased fasting glycemia (5.75 +/- 0.73 vs. 8.11 +/- 0.57 mmol/l) with normal insulin levels. Fasting plasma lactate levels are elevated in both age groups (50-100%). Additionally lipid metabolism is affected by skeletal muscle GLUT4 overexpression. This is indicated by changes in plasma free fatty acid and beta-hydroxybutyrate levels. These studies underscore the importance of GLUT4 in the regulation of glucose homeostasis and its interaction with lipid metabolism.

Cardiac and adipose tissue abnormalities but not diabetes in mice deficient in GLUT4.

The insulin-sensitive glucose transporter, GLUT4, is the most abundant facilitative glucose transporter in muscle and adipose tissue, the major sites for postprandial glucose disposal. To assess the role of GLUT4 in glucose homeostasis, we have disrupted the murine GLUT4 gene. Because GLUT4 has been shown to be dysregulated in pathological states such as diabetes and obesity, it was expected that genetic ablation of GLUT4 would result in abnormal glucose homeostasis. The mice deficient in GLUT4 (GLUT4-null) are growth-retarded and exhibit decreased longevity associated with cardiac hypertrophy and severely reduced adipose tissue deposits. Blood glucose levels in female GLUT4-null mice are not significantly elevated in either the fasting or fed state; in contrast, male GLUT4-null mice have moderately reduced glycaemias in the fasted state and increased glycaemias in the fed state. However, both female and male GLUT4-null mice exhibit postprandial hyperinsulinaemia, indicating possible insulin resistance. Increased expression of other glucose transporters is observed in the liver (GLUT2) and heart (GLUT1) but not skeletal muscle. Oral glucose tolerance tests show that both female and male GLUT4-null mice clear glucose as efficiently as controls, but insulin tolerance tests indicate that these mice are less sensitive to insulin action. The GLUT4-null mice demonstrate that functional GLUT4 protein is not required for maintaining nearly normal glycaemia but that GLUT4 is absolutely essential for sustained growth, normal cellular glucose and fat metabolism, and expected longevity.