964 resultados para Glucose Transporter Genes
Resumo:
OBJECTIVE: In vivo differentiation of cardiac myocytes is associated with downregulation of the glucose transporter isoform GLUT1 and upregulation of the isoform GLUT4. Adult rat cardiomyocytes in primary culture undergo spontaneous dedifferentiation, followed by spreading and partial redifferentiation, which can be influenced by growth factors. We used this model to study the signaling mechanisms modifying the expression of GLUT4 in cardiac myocytes. RESULTS: Adult rat cardiomyocytes in primary culture exhibited spontaneous upregulation of GLUT1 and downregulation of GLUT4, suggesting resumption of a fetal program of GLUT gene expression. Treatment with IGF-1 and, to a minor extent, FGF-2 resulted in restored expression of GLUT4 protein and mRNA. Activation of p38 MAPK mediated the increased expression of GLUT4 in response to IGF-1. Transient transfection experiments in neonatal cardiac myocytes confirmed that p38 MAPK could activate the glut4 promoter. Electrophoretic mobility shift assay in adult rat cardiomyocytes and transient transfection experiments in neonatal cardiac myocytes indicated that MEF2 was the main transcription factor transducing the effect of p38 MAPK activation on the glut4 promoter. CONCLUSION: Spontaneous dedifferentiation of adult rat cardiomyocytes in vitro is associated with downregulation of GLUT4, which can be reversed by treatment with IGF-1. The effect of IGF-1 is mediated by the p38 MAPK/MEF2 axis, which is a strong inducer of GLUT4 expression.
Resumo:
The aim of this work was to study the distribution and cellular localization of GLUT2 in the rat brain by light and electron microscopic immunohistochemistry, whereas our ultrastructural observations will be reported in a second paper. Confirming previous results, we show that GLUT2-immunoreactive profiles are present throughout the brain, especially in the limbic areas and related nuclei, whereas they appear most concentrated in the ventral and medial regions close to the midline. Using cresyl violet counterstaining and double immunohistochemical staining for glial or neuronal markers (GFAp, CAII and NeuN), we show that two limited populations of oligodendrocytes and astrocytes cell bodies and processes are immunoreactive for GLUT2, whereas a cross-reaction with GLUT1 cannot be ruled out. In addition, we report that the nerve cell bodies clearly immunostained for GLUT2 were scarce (although numerous in the dentate gyrus granular layer in particular), whereas the periphery of numerous nerve cells appeared labeled for this transporter. The latter were clustered in the dorsal endopiriform nucleus and neighboring temporal and perirhinal cortex, in the dorsal amygdaloid region, and in the paraventricular and reuniens thalamic nuclei, whereas they were only a few in the hypothalamus. Moreover, a group of GLUT2-immunoreactive nerve cell bodies was localized in the dorsal medulla oblongata while some large multipolar nerve cell bodies peripherally labeled for GLUT2 were scattered in the caudal ventral reticular formation. This anatomical localization of GLUT2 appears characteristic and different from that reported for the neuronal transporter GLUT3 and GLUT4. Indeed, the possibility that GLUT2 may be localized in the sub-plasmalemnal region of neurones and/or in afferent nerve fibres remains to be confirmed by ultrastructural observations. Because of the neuronal localization of GLUT2, and of its distribution relatively similar to glucokinase, it may be hypothesized that this transporter is, at least partially, involved in cerebral glucose sensing.
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Glucose exerts inverse effects upon the secretory function of islet alpha- and beta-cells, suppressing glucagon release and increasing insulin release. This diverse action may result from differences in glucose transport and metabolism between the two cell types. The present study compares glucose transport in rat alpha- and beta-cells. beta-Cells transcribed GLUT2 and, to a lesser extent, GLUT 1; alpha-cells contained GLUT1 but no GLUT2 mRNA. No other GLUT-like sequences were found among cDNAs from alpha- or beta-cells. Both cell types expressed 43-kDa GLUT1 protein which was enhanced by culture. The 62-kDa beta-cell GLUT2 protein was converted to a 58-kDa protein after trypsin treatment of the cells without detectable consequences upon glucose transport kinetics. In beta-cells, the rates of glucose transport were 10-fold higher than in alpha-cells. In both cell types, glucose uptake exceeded the rates of glucose utilization by a factor of 10 or more. Glycolytic flux, measured as D-[5(3)H]glucose utilization, was comparable in alpha- and beta-cells between 1 and 10 mmol/liter substrate. In conclusion, differences in glucose transporter gene expression between alpha- and beta-cells can be correlated with differences in glucose transport kinetics but not with different glucose utilization rates.
Resumo:
In mammals, glucose transporter (GLUT)-4 plays an important role in glucose homeostasis mediating insulin action to increase glucose uptake in insulin-responsive tissues. In the basal state, GLUT4 is located in intracellular compartments and upon insulin stimulation is recruited to the plasma membrane, allowing glucose entry into the cell. Compared with mammals, fish are less efficient restoring plasma glucose after dietary or exogenous glucose administration. Recently our group cloned a GLUT4-homolog in skeletal muscle from brown trout (btGLUT4) that differs in protein motifs believed to be important for endocytosis and sorting of mammalian GLUT4. To study the traffic of btGLUT4, we generated a stable L6 muscle cell line overexpressing myc-tagged btGLUT4 (btGLUT4myc). Insulin stimulated btGLUT4myc recruitment to the cell surface, although to a lesser extent than rat-GLUT4myc, and enhanced glucose uptake. Interestingly, btGLUT4myc showed a higher steady-state level at the cell surface under basal conditions than rat-GLUT4myc due to a higher rate of recycling of btGLUT4myc and not to a slower endocytic rate, compared with rat-GLUT4myc. Furthermore, unlike rat-GLUT4myc, btGLUT4myc had a diffuse distribution throughout the cytoplasm of L6 myoblasts. In primary brown trout skeletal muscle cells, insulin also promoted the translocation of endogenous btGLUT4 to the plasma membrane and enhanced glucose transport. Moreover, btGLUT4 exhibited a diffuse intracellular localization in unstimulated trout myocytes. Our data suggest that btGLUT4 is subjected to a different intracellular traffic from rat-GLUT4 and may explain the relative glucose intolerance observed in fish.
Resumo:
Newly synthesized glucose transporter 4 (GLUT4) enters into the insulin-responsive storage compartment in a process that is Golgi-localized γ-ear-containing Arf-binding protein (GGA) dependent, whereas insulin-stimulated translocation is regulated by Akt substrate of 160 kDa (AS160). In the present study, using a variety of GLUT4/GLUT1 chimeras, we have analyzed the specific motifs of GLUT4 that are important for GGA and AS160 regulation of GLUT4 trafficking. Substitution of the amino terminus and the large intracellular loop of GLUT4 into GLUT1 (chimera 1-441) fully recapitulated the basal state retention, insulin-stimulated translocation, and GGA and AS160 sensitivity of wild-type GLUT4 (GLUT4-WT). GLUT4 point mutation (GLUT4-F5A) resulted in loss of GLUT4 intracellular retention in the basal state when coexpressed with both wild-type GGA and AS160. Nevertheless, similar to GLUT4-WT, the insulin-stimulated plasma membrane localization of GLUT4-F5A was significantly inhibited by coexpression of dominant-interfering GGA. In addition, coexpression with a dominant-interfering AS160 (AS160-4P) abolished insulin-stimulated GLUT4-WT but not GLUT4-F5A translocation. GLUT4 endocytosis and intracellular sequestration also required both the amino terminus and large cytoplasmic loop of GLUT4. Furthermore, both the FQQI and the SLL motifs participate in the initial endocytosis from the plasma membrane; however, once internalized, unlike the FQQI motif, the SLL motif is not responsible for intracellular recycling of GLUT4 back to the specialized compartment. Together, we have demonstrated that the FQQI motif within the amino terminus of GLUT4 is essential for GLUT4 endocytosis and AS160-dependent intracellular retention but not for the GGA-dependent sorting of GLUT4 into the insulin-responsive storage compartment.
Resumo:
Summary Prevalence of type 2 diabetes is increasing worldwide at alarming rates, probably secondarily to that of obesity. As type 2 diabetes is characterized by blood hyperglycemia, controlling glucose entry into tissues from the bloodstream is key to maintain glycemia within acceptable ranges. In this context, several glucose transporter isoforms have been cloned recently and some of them have appeared to play important regulatory roles. Better characterizing two of them (GLUT8 and GLUT9) was the purpose of my work. The first part of my work was focused on GLUT8, which is mainly expressed in the brain and is able to transport glucose with high affinity. GLUT8 is retained intracellularly at basal state depending on an N-terminal dileucine motif, thus implying that cell surface expression may be induced by extracellular triggers. In this regard, I was interested in better defining GLUT8 subcellular localization at basal state and in finding signals promoting its translocation, using an adenoviral vector expressing a myc epitope-tagged version of the transporter, thus allowing expression and detection of cell-surface GLUT8 in primary hippocampal neurons and PC 12 cells. This tool enabled me to found out that GLUT8 resides in a unique compartment different from lysosomes, endoplasmic reticulum, endosomes and the Golgi. In addition, absence of GLUT8 translocation following pharmacological activation of several signalling pathways suggests that GLUT8 does not ever translocate to the cell surface, but would rather fulfill its role in its unique intracellular compartment. The second part of my work was focused on GLUT9, which -contrarily to GLUT8 - is unable to transport glucose, but retains the ability to bind glucose-derived cross-linker molecules, thereby suggesting that it may be a glucose sensor rather than a true glucose transporter. The aim of the project was thus to define if GLUT9 triggers intracellular signals when activated. Therefore, adenoviral vectors expressing GLUTS were used to infect both ßpancreatic and liver-derived cell lines, as GLUTS is endogenously expressed in the liver. Comparison of gene expression between cells infected with the GLUTS-expressing adenovirus and cells infected with a GFP-expressing control adenovirus ended up in the identification of the transcription factor HNF4α as being upregulated in aGLUT9-dependent manner. Résumé La prévalence du diabète de type 2 augmente de façon alarmante dans le monde entier, probablement secondairement à celle de l'obésité. Le diabète de type 2 étant caractérisé par une glycémie sanguine élevée, l'entrée du glucose dans les tissus depuis la circulation sanguine constitue un point de contrôle important pour maintenir la glycémie à des valeurs acceptables. Dans ce contexte, plusieurs isoformes de transporteurs au glucose ont été clonées récemment et certaines d'entre elles sont apparues comme jouant d'importants rôles régulateurs. Mieux caractériser deux d'entre elles (GLUT8 et GLUT9) était le but de mon travail. La première partie de mon travail a été centrée sur GLUT8, qui est exprimé principalement dans le cerveau et qui peut transporter le glucose avec une haute affinité. GLUT8 est retenu intracellulairement à l'état basal de façon dépendante d'un motif dileucine N-terminal, ce qui implique que son expression à la surface cellulaire pourrait être induite par des stimuli extracellulaires. Dans cette optique, je me suis intéressé à mieux définir la localisation subcellulaire de GLUT8 à l'état basal et à trouver des signaux activant sa translocation, en utilisant comme outil un vecteur adénoviral exprimant une version marquée (tag myc) du transporteur, me permettant ainsi d'exprimer et de détecter GLUT8 à la surface cellulaire dans des neurones hippocampiques primaires et des cellules PC12. Cet outil m'a permis de montrer que GLUT8 réside dans un compartiment unique différent des lysosomes, du réticulum endoplasmique, des endosomes, ainsi que du Golgi. De plus, l'absence de translocation de GLUT8 à la suite de l'activation pharmacologique de plusieurs voies de signalisation suggère que GLUT8 ne transloque jamais à la membrane plasmique, mais jouerait plutôt un rôle au sein même de son compartiment intracellulaire unique. La seconde partie de mon travail a été centrée sur GLUT9, lequel -contrairement à GLUT8 -est incapable de transporter le glucose, mais conserve la capacité de se lier à des molécules dérivées du glucose, suggérant que ce pourrait être un senseur de glucose plutôt qu'un vrai transporteur. Le but du projet a donc été de définir si GLUT9 active des signaux intracellulaires quand il est lui-même activé. Pour ce faire, des vecteurs adénoviraux exprimant GLUT9 ont été utilisés pour infecter des lignées cellulaires dérivées de cellules ßpancréatiques et d'hépatocytes, GLUT9 étant exprimé de façon endogène dans le foie. La comparaison de l'expression des gènes entre des cellules infectées avec l'adénovirus exprimant GLUT9 et un adénovirus contrôle exprimant la GFP a permis d'identifier le facteur de transcription HNF4α comme étant régulé de façon GLUT9-dépendante. Résumé tout public Il existe deux types bien distincts de diabète. Le diabète de type 1 constitue environ 10 des cas de diabète et se déclare généralement à l'enfance. Il est caractérisé par une incapacité du pancréas à sécréter une hormone, l'insuline, qui régule la concentration sanguine du glucose (glycémie). Il en résulte une hyperglycémie sévère qui, si le patient n'est pas traité à l'insuline, conduit à de graves dommages à divers organes, ce qui peut mener à la cécité, à la perte des membres inférieurs, ainsi qu'à l'insuffisance rénale. Le diabète de type 2 se déclare plus tard dans la vie. Il n'est pas causé par une déficience en insuline, mais plutôt par une incapacité de l'insuline à agir sur ses tissus cibles. Le nombre de cas de diabète de type 2 augmente de façon dramatique, probablement à la suite de l'augmentation des cas d'obésité, le surpoids chronique étant le principal facteur de risque de diabète. Chez l'individu sain, le glucose sanguin est transporté dans différents organes (foie, muscles, tissu adipeux,...) où il est utilisé comme source d'énergie. Chez le patient diabétique, le captage de glucose est altéré, expliquant ainsi l'hyperglycémie. Il est ainsi crucial d'étudier les mécanismes permettant ce captage. Ainsi, des protéines permettant l'entrée de glucose dans la cellule depuis le milieu extracellulaire ont été découvertes depuis une vingtaine d'années. La plupart d'entre elles appartiennent à une sous-famille de protéines nommée GLUT (pour "GLUcose Transporters") dont cinq membres ont été caractérisés et nommés selon l'ordre de leur découverte (GLUT1-5). Néanmoins, la suppression de ces protéines chez la souris par des techniques moléculaires n'affecte pas totalement le captage de glucose, suggérant ainsi que des transporteurs de glucose encore inconnus pourraient exister. De telles protéines ont été isolées ces dernières années et nommées selon l'ordre de leur découverte (GLUT6-14). Durant mon travail de thèse, je me suis intéressé à deux d'entre elles, GLUT8 et GLUT9, qui ont été découvertes précédemment dans le laboratoire. GLUT8 est exprimé principalement dans le cerveau. La protéine n'est pas exprimée à la surface de la cellule, mais est retenue à l'intérieur. Des mécanismes complexes doivent donc exister pour déplacer le transporteur à la surface cellulaire, afin qu'il puisse permettre l'entrée du glucose dans la cellule. Mon travail a consisté d'une part à définir où se trouve le transporteur à l'intérieur de la cellule, et d'autre part à comprendre les mécanismes capables de déplacer GLUT8 vers la surface cellulaire, en utilisant des neurones exprimant une version marquée du transporteur, permettant ainsi sa détection par des méthodes biochimiques. Cela m'a permis de montrer que GLUT8 est localisé dans une partie de la cellule encore non décrite à ce jour et qu'il n'est jamais déplacé à la surface cellulaire, ce qui suggère que le transporteur doit jouer un rôle à l'intérieur de la cellule et non à sa surface. GLUT9 est exprimé dans le foie et dans les reins. Il ressemble beaucoup à GLUT8, mais ne transporte pas le glucose, ce qui suggère que ce pourrait être un récepteur au glucose plutôt qu'un transporteur à proprement parler. Le but de mon travail a été de tester cette hypothèse, en comparant des cellules du foie exprimant GLUT9 avec d'autres n'exprimant pas la protéine. Par des méthodes d'analyses moléculaires, j'ai pu montrer que la présence de GLUT9 dans les cellules du foie augmente l'expression de HNF4α, une protéine connue pour réguler la sécrétion d'insuline dans le pancréas ainsi que la production de glucose dans le foie. Des expériences complémentaires seront nécessaires afin de mieux comprendre par quels mécanismes GLUT9 influence l'expression de HNF4α dans le foie, ainsi que de définir l'importance de GLUT9 dans la régulation de la glycémie chez l'animal entier.
Resumo:
Frogs have been used as an alternative model to study pain mechanisms. Since we did not find any reports on the effects of sciatic nerve transection (SNT) on the ultrastructure and pattern of metabolic substances in frog dorsal root ganglion (DRG) cells, in the present study, 18 adult male frogs (Rana catesbeiana) were divided into three experimental groups: naive (frogs not subjected to surgical manipulation), sham (frogs in which all surgical procedures to expose the sciatic nerve were used except transection of the nerve), and SNT (frogs in which the sciatic nerve was exposed and transected). After 3 days, the bilateral DRG of the sciatic nerve was collected and used for transmission electron microscopy. Immunohistochemistry was used to detect reactivity for glucose transporter (Glut) types 1 and 3, tyrosine hydroxylase, serotonin and c-Fos, as well as nicotinamide adenine dinucleotide phosphate diaphorase (NADPH-diaphorase). SNT induced more mitochondria with vacuolation in neurons, satellite glial cells (SGCs) with more cytoplasmic extensions emerging from cell bodies, as well as more ribosomes, rough endoplasmic reticulum, intermediate filaments and mitochondria. c-Fos immunoreactivity was found in neuronal nuclei. More neurons and SGCs surrounded by tyrosine hydroxylase-like immunoreactivity were found. No change occurred in serotonin- and Glut1- and Glut3-like immunoreactivity. NADPH-diaphorase occurred in more neurons and SGCs. No sign of SGC proliferation was observed. Since the changes of frog DRG in response to nerve injury are similar to those of mammals, frogs should be a valid experimental model for the study of the effects of SNT, a condition that still has many unanswered questions.
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This study aimed to evaluate the effects of exercise training on triglyceride deposition and the expression of musclin and glucose transporter 4 (GLUT4) in a rat model of insulin resistance. Thirty male Sprague-Dawley rats (8 weeks old, weight 160±10 g) were fed a high-fat diet (40% calories from fat) and randomly divided into high-fat control group and swimming intervention group. Rats fed with standard food served as normal control. We found that 8-week swimming intervention significantly decreased body weight (from 516.23±46.27 to 455.43±32.55 g) and visceral fat content (from 39.36±2.50 to 33.02±2.24 g) but increased insulin sensitivity index of the rats fed with a high-fat diet. Moreover, swimming intervention improved serum levels of TG (from 1.40±0.83 to 0.58±0.26 mmol/L) and free fatty acids (from 837.80±164.25 to 556.38±144.77 μEq/L) as well as muscle triglycerides deposition (from 0.55±0.06 to 0.45±0.02 mmol/g) in rats fed a high-fat diet. Compared with rats fed a standard food, musclin expression was significantly elevated, while GLUT4 expression was decreased in the muscles of rats fed a high-fat diet. In sharp contrast, swimming intervention significantly reduced the expression of musclin and increased the expression of GLUT4 in the muscles of rats fed a high-fat diet. In conclusion, increased musclin expression may be associated with insulin resistance in skeletal muscle, and exercise training improves lipid metabolism and insulin sensitivity probably by upregulating GLUT4 and downregulating musclin.
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Cancer cells are known to display increased glucose uptake and consumption. The glucose transporter (GLUT) proteins facilitate glucose uptake, however, their exact role in cancer metabolism remains unclear. The present study examined mRNA and protein expression of GLUT1, GLUT3, GLUT4 and GLUT12 in lung, breast and prostate cancer cells and corresponding noncancerous cells. Additionally, GLUT expression was determined in tumours from mice xenografted with human cancer cells. Differences in the mRNA and protein expression of GLUTs were found between cancerous and corresponding noncancerous cells. These findings demonstrate abundant expression of GLUT1 in cancer and highlight the importance of GLUT3 as it was expressed in several cancer cells and tumours. GLUT expression patterns in vitro were supported by the in vivo findings. The study of GLUT protein expression in cancer is important for understanding cancer metabolism and may lead to identification of biomarkers of cancer progression and development of target therapies.
Resumo:
A90
