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The use of HIV protease inhibitors (PIs) may be associated with serious adverse side effects that include fat tissue redistribution, hyperlipidemia, and insulin resistance. The etiology of this toxic metabolic syndrome (commonly referred to as 'HIV lipodystrophy syndrome') remains to be elucidated. The interpretation of available clinical data on this subject is complicated in part by the pervasiveness of potential confounding factors that cannot be easily eliminated or adequately controlled. Numerous investigators have examined the effects of PIs on cellular processes in model systems amenable to extensive experimental manipulations; the present review primarily focuses on these efforts. The ultimate goal is the unambiguous identification of discrete cellular targets being surreptitiously impacted by PIs. SREBP and Glut4 are discussed as candidate target molecules in this context. The identification of cellular factors interacting with PIs represents a necessary first step in devising rational strategies for improvement in drug therapy.

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The structure of the human erythrocyte facilitative glucose transporter (GLUT1) has been intensively investigated using a wide array of chemical and biophysical approaches. Despite the lack of a crystal structure for any of the facilitative monosaccharide transport proteins, detailed information regarding primary and secondary structure, membrane topology, transport kinetics, and functionally important residues has allowed the construction of a sophisticated working model for GLUT1 tertiary structure. The existing data support the formation of a central aqueous channel formed by the juxtaposition of several amphipathic transmembrane-spanning alpha-helices. The results of extensive mutational analysis of GLUT1 have elucidated many of the structural determinants of the glucose permeation pathway. Continued application of currently available technologies will allow further refinement of this working model. In addition to providing insights into the molecular basis of both normal and disordered glucose homeostasis, this detailed understanding of structure/function relationships within GLUT1 can provide a basis for understanding transport carried out by other members of the major facilitator superfamily.

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Although the clinical introduction of human immunodeficiency virus (HIV) protease inhibitors (PIs) has resulted in a dramatic decline in HIV-related morbidity and mortality, it is now recognized that PI therapy is associated with serious adverse metabolic effects, including peripheral lipoatrophy, increased visceral fat, hyperlipidemia, and insulin resistance. Despite increasing awareness of this metabolic syndrome, the etiology of these side effects remains obscure. This review critically examines current mechanistic hypotheses in the context of the available experimental data. To date, a single unifying explanation for this syndrome has not been confirmed. As data accumulate, it is becoming clear that PIs lack precision in their cellular targets and it is likely that many of the side effects of these drugs are due to inhibition of a number of unrelated molecules.

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The glucose permeation pathway within the GLUT1 facilitative glucose transporter is hypothesized to be formed by the juxtaposition of the hydrophilic faces of several transmembrane alpha-helices. The role of transmembrane segment 11 in forming a portion of this central aqueous channel was investigated using cysteine-scanning mutagenesis in conjunction with sulfhydryl-directed chemical modification. Each of the amino acid residues within transmembrane segment 11 were individually mutated to cysteine in an engineered GLUT1 molecule devoid of all native cysteines (C-less). Measurement of 2-deoxyglucose uptake in a Xenopus oocyte expression system revealed that all of these mutants retain measurable transport activity. Four of the cysteine mutants (N411, W412, N415, and F422) had significantly reduced specific activity relative to the C-less protein. Specific activity was increased in five of the mutants (A402, A405, V406, F416, and M420). The solvent accessibility and relative orientation of the residues to the glucose permeation pathway were investigated by determining the sensitivity of the mutant transporters to inhibition by the sulfhydryl-directed reagent p-chloromercuribenzenesulfonate (pCMBS). Cysteine replacement at five positions (I404, G408, F416, G419, and M420) produced transporters that were inhibited by incubation with extracellular pCMBS. All of these residues cluster along a single face of the alpha-helix within the regions showing altered specific activities. These data demonstrate that the exofacial portion of transmembrane segment 11 is accessible to the external solvent and provide evidence for the positioning of this alpha-helix within or near the glucose permeation pathway.

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Mammalian preimplantation blastocysts exhibit insulin-stimulated glucose uptake despite the absence of the only known insulin-regulated transporter, GLUT4. We describe a previously unidentified member of the mammalian facilitative GLUT superfamily that exhibits approximately 20-25% identity with other murine facilitative GLUTs. Insulin induces a change in the intracellular localization of this protein, which translates into increased glucose uptake into the blastocyst, a process that is inhibited by antisense oligoprobes. Presence of this transporter may be necessary for successful blastocyst development, fuel metabolism, and subsequent implantation. Moreover, the existence of an alternative transporter may explain examples in other tissues of insulin-regulated glucose transport in the absence of GLUT4.

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Retroviral protease inhibitors used as therapy for HIV-1 infection have been causally associated with serious metabolic side effects, including peripheral lipodystrophy, hyperlipidemia, insulin resistance, and in some cases, overt type 2 diabetes. The etiology of this characteristic clinical syndrome remains unknown. We demonstrate that the HIV protease inhibitor, indinavir, dramatically inhibits insulin-stimulated glucose uptake in 3T3-L1 adipocytes in a dose-dependent manner (63% inhibition observed with 100 micrometer indinavir). Indinavir treatment did not affect early insulin signaling events or the translocation of intracellular Glut1 or Glut4 glucose transporters to the cell surface. To determine whether indinavir may be directly affecting the intrinsic transport activity of glucose transporters, the Glut1 and Glut4 isoforms were heterologously expressed and analyzed in Xenopus laevis oocytes. Indinavir at 100 microm had no effect on Glut1 transport activity in Xenopus oocytes, whereas Glut4 activity was significantly inhibited (45% inhibition). Similar effects on glucose transport were observed for other HIV protease inhibitors. We conclude that HIV protease inhibitors as a class are capable of selectively inhibiting the transport function of Glut4 and that this effect may be responsible for a major iatrogenic complication frequently observed in HIV patients.

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Osmotic shock can cause insulin resistance in 3T3-L1 adipocytes by inhibiting insulin activation of glucose transport, p70S6 kinase, glycogen synthesis, and lipogenesis. By further investigating the relationship between insulin and hypertonic stress, we have discovered that osmotic shock enhanced by 10-fold the insulin-stimulated tyrosine phosphorylation of a 68-kDa protein. Phosphorylation by insulin was maximal after 1 min and was saturated with 50-100 nm insulin. The effect of sorbitol was completely reversible by 2.5 min. pp68 was a peripheral protein that was localized to the detergent insoluble fraction of the low density microsomes but was not associated with the cytoskeleton. Stimulation of the p42/44 and the p38 MAP kinase pathways by osmotic shock had no effect on pp68 phosphorylation. Treatment of adipocytes with the phosphotyrosine phosphatase inhibitor phenylarsine oxide also enhanced insulin-activated tyrosine phosphorylation of pp68 suggesting that osmotic shock may increase pp68 phosphorylation by inhibiting a phosphotyrosine phosphatase. Dissociation of pp68 from the low density microsomes with RNase A indicated that pp68 binds to RNA. Failure to immunoprecipitate pp68 using antibodies directed against known 60-70-kDa tyrosine-phosphorylated proteins suggest that pp68 may be a novel cellular target that lies downstream of the insulin receptor.

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Glut1 transgenic mice were bred with transgenic mice that overexpress hexokinase II in skeletal muscle in order to determine whether whole-body glucose disposal could be further augmented in mice overexpressing glucose transporters. Overexpression of hexokinase alone in skeletal muscle had no effect on glucose transport or metabolism in isolated muscles, nor did it alter blood glucose levels or the rate of whole-body glucose disposal. Expression of the hexokinase transgene in the context of the Glut1 transgenic background did not alter glucose transport in isolated muscles but did cause additional increases in steady-state glucose 6-phosphate (3.2-fold) and glycogen (7.5-fold) levels compared with muscles that overexpress the Glut1 transporter alone. Surprisingly, however, these increases were not accompanied by a change in basal or insulin-stimulated whole-body glucose disposal in the doubly transgenic mice compared with Glut1 transgenic mice, probably due to an inhibition of de novo glycogen synthesis as a result of the high levels of steady-state glycogen in the muscles of doubly transgenic mice (430 micromol/g versus 10 micromol/g in wild-type mice). We conclude that the hexokinase gene may not be a good target for therapies designed to counteract insulin resistance or hyperglycemia.

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The purpose of the present study was to determine the rates of muscle glycogenolysis and glycogenesis during and after exercise in GLUT-1 transgenic mice and their age-matched littermates. Male transgenic mice (TG) expressing a high level of human GLUT-1 and their nontransgenic (NT) littermates underwent 3 h of swimming. Glycogen concentration was determined in gastrocnemius and extensor digitorum longus (EDL) muscles before exercise and at 0, 5, and 24 h postexercise, during which food (chow) and 10% glucose solution (as drinking water) were provided. Exercise resulted in approximately 90% reduction in muscle glycogen in both NT (from 11.2 +/- 1.4 to 2. 1 +/- 1.3 micromol/g) and TG (from 99.3 +/- 4.7 to 11.8 +/- 4.3 micromol/g) in gastrocnemius muscle. During recovery from exercise, the glycogen concentration increased to 38.2 +/- 7.3 (5 h postexercise) and 40.5 +/- 2.8 micromol/g (24 h postexercise) in NT mice. In TG mice, however, the increase in muscle glycogen concentration during recovery was greater (to 57.5 +/- 7.4 and 152.1 +/- 15.7 micromol/g at 5 and 24 h postexercise, respectively). Similar results were obtained from EDL muscle. The rate of 2-deoxyglucose uptake measured in isolated EDL muscles was 7- to 10-fold higher in TG mice at rest and at 0 and 5 h postexercise. There was no difference in muscle glycogen synthase activation measured in gastrocnemius muscles between NT and TG mice immediately after exercise. These results demonstrate that the rate of muscle glycogen accumulation postexercise exhibits two phases in TG: 1) an early phase (0-5 h), with rapid glycogen accumulation similar to that of NT mice, and 2) a progressive increase in muscle glycogen concentration, which differs from that of NT mice, during the second phase (5-24 h). Our data suggest that the high level of steady-state muscle glycogen in TG mice is due to the increase in muscle glucose transport activity.

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The transport and metabolism of glucose modify programmed cell death in a number of different cell types. This review presents three cell death paradigms that link a decrease in glucose transport to apoptosis. Although these pathways overlap, the glucose-dependent stimuli that trigger cell death differ. These paradigms include glucose deprivation-induced ATP depletion and stimulation of the mitochondrial death pathway cascade; glucose deprivation-induced oxidative stress and triggering of Bax-associated events including the JNK/MAPK signalling pathways; and finally hypoglycemia-regulated expression of HIF-1 alpha, stabilization of p53 leading to an increase in p53-associated apoptosis. Several examples of each paradigm are presented. Future studies of glucose transport-associated apoptotic events will allow better understanding of the role of cellular metabolism in programmed cell death.

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The human erythrocyte facilitative glucose transporter (Glut1) is predicted to contain 12 transmembrane spanning alpha-helices based upon hydropathy plot analysis of the primary sequence. Five of these helices (3, 5, 7, 8, and 11) are capable of forming amphipathic structures. A model of GLUT1 tertiary structure has therefore been proposed in which the hydrophilic faces of several amphipathic helices are arranged to form a central aqueous channel through which glucose traverses the hydrophobic lipid bilayer. In order to test this model, we individually mutated each of the amino acid residues in transmembrane segment 7 to cysteine in an engineered GLUT1 molecule devoid of all native cysteines (C-less). Measurement of 2-deoxyglucose uptake in a Xenopus oocyte expression system revealed that nearly all of these mutants retain measurable transport activity. Over one-half of the cysteine mutants had significantly reduced specific activity relative to the C-less protein. The solvent accessibility and relative orientation of the residues within the helix was investigated by determining the sensitivity of the mutant transporters to inhibition by the sulfhydryl directed reagent p-chloromercuribenzene sulfonate (pCMBS). Cysteine replacement at six positions (Gln(282), Gln(283), Ile(287), Ala(289), Val(290), and Phe(291)), all near the exofacial side of the cell membrane, produced transporters that were inhibited by incubation with extracellular pCMBS. Residues predicted to be near the cytoplasmic side of the cell membrane were minimally affected by pCMBS. These data demonstrate that the exofacial portion of transmembrane segment 7 is accessible to the external solvent and provide evidence for the positioning of this alpha-helix within the glucose permeation pathway.

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ADP-ribosylation factor 6 (ARF6) appears to play an essential role in the endocytic/recycling pathway in several cell types. To determine whether ARF6 is involved in insulin-regulated exocytosis, 3T3-L1 adipocytes were infected with recombinant adenovirus expressing wild-type ARF6 or an ARF6 dominant negative mutant (D125N) that encodes a protein with nucleotide specificity modified from guanine to xanthine. Overexpression of these ARF6 proteins affected neither basal nor insulin-regulated glucose uptake in 3T3-L1 adipocytes, nor did it affect the subcellular distribution of Glut1 or Glut4. In contrast, the secretion of adipsin, a serine protease specifically expressed in adipocytes, was increased by the expression of wild-type ARF6 and was inhibited by the expression of D125N. These results indicate a requirement for ARF6 in basal and insulin-regulated adipsin secretion but not in glucose transport. Our results suggest the existence of at least two distinct pathways that undergo insulin-stimulated exocytosis in 3T3-L1 adipocytes, one for adipsin release and one for glucose transporter translocation.

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The Glut1 glucose transporter is one of over 300 members of the major facilitator superfamily of membrane transporters. These proteins are extremely diverse in substrate specificity and differ in their transport mechanisms. The two most common features shared by many members of this superfamily are the presence of 12 predicted transmembrane segments and an amino acid motif, R-X-G-R-R, present at equivalent positions within the cytoplasmic loops joining transmembrane segments 2-3 and 8-9. The structural and functional roles of the arginine residues within these motifs in Glut1 were investigated by expression of site-directed mutant transporters in Xenopus oocytes followed by analyses of intrinsic transport activity and the membrane topology of mutant glycosylation-scanning reporter Glut1 molecules. Substitution of lysine residues for the cluster of 3 arginine residues in each of the 2 cytoplasmic pentameric motifs of Glut1 revealed no absolute requirement for arginine side chains at any of the 6 positions for transport of 2-deoxyglucose. However, removal of the 3 positive charges at either site by substitution of glycines for the arginines completely abolished transport activity as the result of a local perturbation in the membrane topology in which the cytoplasmic loop was aberrantly translocated into the exoplasm along with the two flanking transmembrane segments. Substitution of lysines for the arginines had no affect on membrane topology. We conclude that the positive charges in the R-X-G-R-R motif form critical local cytoplasmic anchor points involved in determining the membrane topology of Glut1. These data provide a simple explanation for the presence of this conserved amino acid motif in hundreds of functionally diverse membrane transporters that share a common predicted membrane topology.

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Transmembrane segment 5 of the Glut1 glucose transporter has been proposed to form an amphipathic transmembrane helix that lines the substrate translocation pathway (Mueckler, M., Caruso, C., Baldwin, S. A., Panico, M., Blench, I., Morris, H. R., Allard, W. J., Lienhard, G. E., and Lodish, H. F. (1985) Science 229, 941-945). This hypothesis was tested using cysteine-scanning mutagenesis in conjunction with the membrane-impermeant, sulfhydryl-specific reagent, p-chloromercuribenzenesulfonate (pCMBS). A series of 21 mutants was created from a fully functional, cysteine-less, parental Glut1 molecule by changing each residue within putative transmembrane segment 5 to cysteine. Each mutant was then expressed in Xenopus oocytes and its steady-state protein level, 2-deoxyglucose uptake activity, and sensitivity to pCMBS were measured. All 21 mutants exhibited measurable transport activity, although several of the mutants exhibited reduced activity due to a corresponding reduction in steady-state protein. Six of the amino acid side chains within transmembrane segment 5 were clearly accessible to pCMBS in the external medium, as determined by inhibition of transport activity, and a 7th residue showed inhibition that lacked statistical significance because of the extremely low transport activity of the corresponding mutant. All 7 of these residues were clustered along one face of a putative alpha-helix, proximal to the exoplasmic surface of the plasma membrane. These results comprise the first experimental evidence for the existence of an amphipathic transmembrane alpha-helix in a glucose transporter molecule and strongly suggest that transmembrane segment 5 of Glut1 forms part of the sugar permeation pathway.

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Insulin-stimulated glucose uptake is defective in patients with type 2 diabetes. To determine whether transgenic glucose transporter overexpression in muscle can prevent diabetes induced by a high-fat, high-sugar diet, singly (GLUT-1, GLUT-4) and doubly (GLUT-1 and -4) transgenic mice were placed on a high-fat, high-sugar diet or a standard chow diet. On the high-fat, high-sugar diet, wild-type but not transgenic mice developed fasting hyperglycemia and glucose intolerance (peak glucose of 337 +/- 19 vs. 185-209 mg/dl in the same groups on the high-fat, high-sugar diet and 293 +/- 13 vs. 166-194 mg/dl on standard chow). Hyperinsulinemic clamps showed that transporter overexpression elevated insulin-stimulated glucose utilization on standard chow (49 +/- 4 mg. kg-1. min-1 in wild-type vs. 61 +/- 4, 67 +/- 5, and 63 +/- 6 mg. kg-1. min-1 in GLUT-1, GLUT-4, and GLUT-1 and -4 transgenic mice given 20 mU. kg-1. min-1 insulin, and 54 +/- 7, 85 +/- 4, and 98 +/- 11 in wild-type, GLUT-1, and GLUT-4 mice given 60-80 mU. kg-1. min-1 insulin). On the high-fat, high-sugar diet, wild-type and GLUT-1 mice developed marked insulin resistance, but GLUT-4 and GLUT-1 and -4 mice were somewhat protected (glucose utilization during hyperinsulinemic clamp of 28.5 +/- 3.4 vs. 42.4 +/- 5.9, 51.2 +/- 8.1, and 55.9 +/- 4. 9 mg. kg-1. min-1 in wild type, GLUT-1, GLUT-4, GLUT-1 and -4 mice). These data demonstrate that overexpression of GLUT-1 and/or GLUT-4 enhances whole body glucose utilization and prevents the development of fasting hyperglycemia and glucose intolerance induced by a high-fat, high-sugar diet. GLUT-4 overexpression improves the insulin resistance induced by the diet. We conclude that upregulation of glucose transporters in skeletal muscle may be an effective therapeutic approach to the treatment of human type 2 diabetes.

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Although perinatal mortality rates have improved for pregnant diabetic women because of insulin therapy and tight metabolic control, infants of diabetics still experience significantly higher rates of congenital malformations and spontaneous miscarriages compared with those of non-diabetic women. Our results here indicate that hyperglycemic conditions, either in vivo or in vitro, modulate the expression of an apoptosis regulatory gene as early as the pre-implantation blastocyst stage in the mouse. Apoptosis in the mammalian pre-implantation blastocyst is a normal process, thought to protect the early embryo by eliminating abnormal cells. Here we demonstrate that expression of Bax, a Bcl-2-like protein, is increased at the blastocyst stage in the presence of high concentrations of glucose, and that these changes correlate morphologically with increased DNA fragmentation. Expression of Bax and caspase are necessary for this in vitro glucose-induced apoptotic event, and ceramide is involved in mediating this embryotoxic effect of glucose. We also show that these apoptotic cellular changes can be prevented in vivo by treating hyperglycemic mice with insulin before and immediately after conception. These findings emphasize the importance of tight glycemic control in diabetic women at the earliest stages after conception.

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Wolfram syndrome (WFS; OMIM 222300) is an autosomal recessive neurodegenerative disorder defined by young-onset non-immune insulin-dependent diabetes mellitus and progressive optic atrophy. Linkage to markers on chromosome 4p was confirmed in five families. On the basis of meiotic recombinants and disease-associated haplotypes, the WFS gene was localized to a BAC/P1 contig of less than 250 kb. Mutations in a novel gene (WFS1) encoding a putative transmembrane protein were found in all affected individuals in six WFS families, and these mutations were associated with the disease phenotype. WFS1 appears to function in survival of islet beta-cells and neurons.

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The Glut1 glucose transporter is a glycoprotein whose membrane topology has been verified by a number of experimental observations, all of which are consistent with a 12-transmembrane helix model originally based on hydrophobicity analysis. We used Glut1 as a model multispanning membrane protein to test the Charge Difference Hypothesis (Hartmann, E., Rapoport, T. A., and Lodish, H. F. (1989) Proc. Natl. Acad. Sci. U. S. A. 86, 5786-5790), which asserts that the topology of a eucaryotic multispanning membrane protein is determined solely by the amino acid charge difference across the first transmembrane segment. The charge difference across the first transmembrane segment of Glut1 was progressively inverted in two independent series of mutants, one series in which only the number of positively charged amino acid residues in the two flanking domains was altered and the other in which only the number of negatively charged residues in the two flanking domains was changed. The results indicate that the charge difference across the first transmembrane segment does affect the topology of the protein, but that contrary to the hypothesis, it only dictates the orientation of the first transmembrane segment and the disposition of the amino terminus and the first linker domain. Charge inversion resulted in the formation of aberrant molecules in which either the first or second transmembrane segment failed to insert into the membrane. The topology of downstream regions of Glut1 was unaffected by charge inversion across the first transmembrane segment, indicating that downstream sequences are important in determining the local topological disposition of the molecule.

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A high fat diet causes resistance of skeletal muscle glucose transport to insulin and contractions. We tested the hypothesis that fat feeding causes a change in plasma membrane composition that interferes with functioning of glucose transporters and/or insulin receptors. Epitrochlearis muscles of rats fed a high (50% of calories) fat diet for 8 weeks showed approximately 50% decreases in insulin- and contraction-stimulated 3-O-methylglucose transport. Similar decreases in stimulated glucose transport activity occurred in muscles of wild-type mice with 4 weeks of fat feeding. In contrast, GLUT1 overexpressing muscles of transgenic mice fed a high fat diet showed no decreases in their high rates of glucose transport, providing evidence against impaired glucose transporter function. Insulin-stimulated system A amino acid transport, insulin receptor (IR) tyrosine kinase activity, and insulin-stimulated IR and IRS-1 tyrosine phosphorylation were all normal in muscles of rats fed the high fat diet for 8 weeks. However, after 30 weeks on the high fat diet, there was a significant reduction in insulin-stimulated tyrosine phosphorylation in muscle. The increases in GLUT4 at the cell surface induced by insulin or muscle contractions, measured with the 3H-labeled 2-N-4-(1-azi-2,2, 2-trifluoroethyl)-benzoyl-1,3-bis-(D-mannose-4-yloxy)-2-propyla min e photolabel, were 26-36% smaller in muscles of the 8-week high fat-fed rats as compared with control rats. Our findings provide evidence that (a) impairment of muscle glucose transport by 8 weeks of high fat feeding is not due to plasma membrane composition-related reductions in glucose transporter or insulin receptor function, (b) a defect in insulin receptor signaling is a late event, not a primary cause, of the muscle insulin resistance induced by fat feeding, and (c) impaired GLUT4 translocation to the cell surface plays a major role in the decrease in stimulated glucose transport.

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