Rôle du transporteur de glucose GLUT2 dans les mécanismes centraux de glucodétection impliqués dans le contrôle de la sécrétion du glucagon et de la prise alimentaire

Résumé Rôle du transporteur de glucose GLUT2 dans les mécanismes centraux de glucodétection impliqués dans le contrôle de la sécrétion du glucagon et de la prise alimentaire. Les mécanismes centraux de glucodétection jouent un rôle majeur dans le contrôle de l'homéostasie glucidique. Ces senseurs régulent principalement la sécrétion des hormones contre-régulatrices, la prise alimentaire et la dépense énergétique. Cependant, la nature cellulaire et le fonctionnement moléculaire de ces mécanismes ne sont encore que partiellement élucidés. Dans cette étude, nous avons tout d'abord mis en évidence une suppression de la stimulation de la sécrétion du glucagon et de la prise alimentaire en réponse à une injection intracérébroventriculaire (i.c.v.) de 2-déoxy-D-glucose (2-DG) chez les souris de fond génétique mixte et déficientes pour le gène glut2 (souris RIPG1xglut2-/-). De plus, chez ces souris, l'injection de 2-DG n'augmente pas l'activation neuronale dans l'hypothalamus et le complexe vagal dorsal. Nous avons ensuite montré que la ré-expression de GLUT2 dans les neurones des souris RIPG1xg1ut2-/- ne restaure pas la sécrétion du glucagon et la prise alimentaire en réponse à une injection i.c.v. de 2-DG. En revanche, l'injection de 2-DG réalisée chez les souris RIPG1xg1ut2-/- ré-exprimant le GLUT2 dans leurs astrocytes, stimule la sécrétion du glucagon et l'activation neuronale dans le complexe vagal dorsal mais n'augmente pas la prise alimentaire ni l'activation neuronale dans l'hypothalamus. L'ensemble de ces résultats démontre l'existence de différents mécanismes centraux de glucodétection dépendants de GLUT2. Les mécanismes régulant la sécrétion du glucagon sont dépendants de GLUT2 astrocytaire et pourraient être localisés dans le complexe vagal dorsal. L'implication des astrocytes dans ces mécanismes suggère un couplage fonctionnel entre les astrocytes et les neurones adjacents « sensibles au glucose ». Lors de cette étude, nous avons remarqué chez les souris RIPG1xg1ut2-/- de fond génétique pur C57B1/6, que seul le déclenchement de la prise alimentaire en réponse à l'injection i.p. ou i.c.v. de 2-DG est aboli. Ces données mettent en évidence que suivant le fond génétique de la souris, les mécanismes centraux de glucodétection impliqués dans la régulation de la sécrétion peuvent être indépendants de GLUT2. Summary. Role of transporter GLUT2 in central glucose sensing involved in the control of glucagon secretion and food intake. Central glucose sensors play an important role in the control of glucose homeostasis. These sensors regulate general physiological functions, including food intake, energy expenditure and hormones secretion. So far the cellular and molecular basis of central glucose detection are poorly understood. Hypoglycemia, or cellular glucoprivation by intraperitoneal injection of 2-deoxy¬glucose (2-DG) injection, elicit multiple glucoregulatory responses, in particular glucagon secretion and stimulation of feeding. We previously demonstrated that the normal glucagon response to insulin-induced hypoglycemia was suppressed in mice lacking GLUT2. This indicated the existence of extra-pancreatic, GLUT2-dependent, glucose sensors controllling glucagon secretion. Here, we have demonstrated that the normal glucagon and food intake responses to central glucoprivation, by intracerebroventricular (i.c.v.) injections of 2-DG, were suppressed in mice lacking GLUT2 (RIPG1xglut2-/- mice) indicating that GLUT2 plays a role in central glucose sensing units controlling secretion of glucagon and food intake. Whereas it is etablished that glucose responsive neurons change their firing rate in response to variations of glucose concentrations, the exact mechanism of glucose detection is not established. In particular, it has been suggested that astrocytic cells may be the primary site of glucose detection and that a signal is subsequently transmitted to neurons. To evaluate the respective role of glial and neuronal expression of GLUT2 in central glucodetection, we studied hypoglycemic and glucoprivic responses following cellular glucoprivation in RIPG1xglut2-/- mice reexpressing the transgenic GLUT2 specifially in their astrocytes (pGFAPG2xRIPG1xglut2-/- mice) or their neurons (pSynG2xRIPG1xglut2-/- mice). The increase of food intake after i.p. injection of 2-DG in control mice was not observed in the pGFAPG2xRIPG1xglut2-/- mice. Whereas a strong increase of glucagon secretion was observed in control and pGFAPG2xRIPG1xglut2-/- mice, not glucagonemic response was induced in pSynG2xRIPG1xglut2-/- mice. Our results show that GLUT2 reexpression in glial cells but not in neurons restored glucagon secretion and thus present a strong evidence that glucose detection and the control of glucagon secretion require a coupling between glial cells and neurons. Furthermore, these results show the existence of differents glucose sensors in CNS. Résumé tout public. Rôle du transporteur de glucose GLUT2 dans les mécanismes centraux de glucodétection impliqués dans le contrôle de la sécrétion du glucagon et de la prise alimentaire. Chez les mammifères, en dépit des grandes variations dans l'apport et l'utilisation du glucose, la glycémie est maintenue à une valeur relativement constante d'environ 1 g/l. Cette régulation est principalement sous le contrôle de deux hormones produites par le pancréas l'insuline et le glucagon. A la suite d'un repas, la détection de l'élévation de la glycémie par le pancréas permet la libération pancréatique de l'insuline dans le sang. Cette hormone va alors permettre le stockage dans le foie du glucose sanguin en excès et diminuer ainsi la glycémie. Sans insuline, le glucose s'accumule dans le sang. On parle alors d'hyperglycémie chronique. Cette situation est caractéristique du diabète et augmente les risques de maladies cardiovasculaires. A l'inverse, lors d'un jeûne, la détection de la diminution de la glycémie par le cerveau permet le déclenchement de la prise alimentaire et stimule la sécrétion de glucagon par le pancréas. Le glucagon va alors permettre la libération dans le sang du glucose stocké par le foie. Les effets du glucagon et de la prise de nourriture augmentent ainsi les concentrations sanguines de glucose pour empêcher une diminution trop importante de la glycémie. Une hypoglycémie sévère peut entraîner un mauvais fonctionnement du cerveau allant jusqu'à des lésions cérébrales. Contrairement aux mécanismes pancréatiques de détection du glucose, les mécanismes de glucodétection du cerveau ne sont encore que partiellement élucidés. Dans le laboratoire, nous avons observé, chez les souris transgéniques n'exprimant plus le transporteur de glucose GLUT2, une suppression de la stimulation de la sécrétion du glucagon et du déclenchement de la prise alimentaire en réponse à une hypoglycémie, induite uniquement dans le cerveau. Dans le cerveau, le GLUT2 est principalement exprimé par les astrocytes, cellules gliales connues pour soutenir, nourrir et protéger les neurones. Nous avons alors ré-exprimé spécifiquement le GLUT2 dans les astrocytes des souris transgéniques et nous avons observé que seule la stimulation de la sécrétion du glucagon en réponse à l'hypoglycémie est restaurée. Ces résultats mettent en évidence que la sécrétion du glucagon et la prise alimentaire sont contrôlées par différents mécanismes centraux de glucodétection dépendants de GLUT2.

A study of the translational regulation exerted by some neuroactive substances on the expression of the monocarboxylate transporter MCT2 in cultured cortical neurons

Summary of the thesis Glucose has been considered the major, if not the exclusive, energy substrate for the brain. But under certain conditions other substrates, namely monocarboxylates (lactate, pyruvate, and ketone bodies), can contribute significantly to satisfy brain energy demands. These monocarboxylates need to be transported across the blood brain barrier as well as out of astrocytes into the extracellular space and taken up into neurons. It has been shown that monocarboxylates are transported by a family of proton-linked transporters called monocarboxylate transporters (MCTs). In the central nervous system, MCT2 is the predominant neuronal form and little is known about the regulation of its expression. The neurotransmitter noradrenaline (NA) was shown previously to enhance the expression of MCT2 in cultured cortical neurons via a translational mechanism. Here, we demonstrate that two other substances, namely, insulin and IGF-1 enhance MCT2 protein expression in cultured mouse cortical neurons in a time- and concentrationdependent manner without affecting MCT2 mRNA levels. This result confirmed that MCT2 protein expression is translationally regulated and extend the observation to different types of neuroactive substances. Then we sought to determine by which signaling pathway(s) NA, insulin and IGF-1 can induce MCT2 protein expression. First, we observed by Western blot that all three substances cause activation of the MAP kinase ERK as well as the kinase Akt via their phosphorylation. Moreover, the mTOR/S6K pathway which is known to play an important role in translation initiation regulation was also strongly stimulated by all three substances. Second, we sought to determine the implication of these signaling pathways on the NA-, insulin- and IGF-1-induced enhancement of MCT2 protein expression and used specific inhibitors of these signaling pathways. We observed that the Pia kinase and mTOR inhibitors LY294002 and rapamycin respectively, strongly prevent the enhancement. of MCT2 expression caused by either NA, insulin ar IGF-1. In contrast, the MEK inhibitor PD98059 and the p38 MAP kinase inhibitor SB202190 had only a slight effect on the enhancement of MCT2 expression in all three cases. These results suggest that NA, insulin and IGF-1 regulate MCT2 protein expression by a common mechanism most likely involving the Akt/PKB pathway and translational activation via mTOR. In conclusion, considering the roles of NA, insulin and IGF-1 in synaptic plasticity, the tight translational regulation of MCT2 expression by these substances may represent a common mechanism through which supply of potentiated synapses with nonglucose energy substrates can be adapted to the level of activity. Résumé du travail de thèse Le glucose représente le substrat énergétique majeur pour le cerveau. Cependant, dans certaines conditions physiologiques ou pathologiques, le cerveau a la capacité d'utiliser des substrats énergétiques appartenant à la classe des monocarboxylates (lactate, pyruvate et corps cétoniques) afin de satisfaire ses besoins énergétiques. Ces monocarboxylates doivent être transportés à travers la barrière hématoencéphalique mais aussi hors des astrocytes vers l'espace extracellulaire puis re-captés par les neurones. Leur transport est assuré par une famille de transporteurs spécifiques, protons-dépendants, appelés transporteurs aux monocarboxylates (MCTs). Dans le système nerveux central, les neurones expriment principalement l'isoforme MCT2 mais peu d'informations sont disponibles concernant la régulation de son expression. Il a été montré que le neurotransmetteur noradrénaline (NA) augmente l'expression de MCT2 dans les cultures de neurones corticaux de souris par le biais d'un mécanisme de régulation traductionnel. La présente étude nous a permis de démontrer que deux autres substances, l'insuline et 17GF-1, induisent une augmentation de la protéine MCT2 dans ces mêmes cultures selon un décours temporel et une gamme de concentrations particulière. Etonnamment, aucun changement n'a été observé concernant les niveaux d'ARNm de MCT2. Ce résultat .confirme que la protéine MCT2 est régulée de manière traductionnelle et révèle que différentes substances neuro-actives peuvent réguler l'expression de MCT2. Compte tenu de ces observations, nous avons voulu déterminer par quelle(s) voie(s) de signalisation la NA, l'insuline et l'IGF-1 exercent leur effet sur l'expression de MCT2. Dans un premier temps, nous avons pu observer par Western blot que ces trois substances activent la MAP kinase ERK ainsi que la kinase Akt via leur phasphorylation. De plus, la voie mTOR/S6K, connue pour son implication dans la régulation de l'initiation de la traduction est aussi fortement activée par ces trois substances. Dans un second temps, nous avons voulu déterminer I implication de chacune de ces voies de signalisation dans l'augmentation de l'expression de la protéine MCT2 observée après stimulation à la NA, à l'insuline et à l'IGF-1. Pour ce faire, nous avons utilisé des inhibiteurs spécifiques de chacune de ces voies. (Vous avons observé que les inhibiteurs des voies PI3 kinase et mTOR (LY294002 et rapamycin respectivement), prévenaient fortement l'augmentation de l'expression de MCT2 induite par la NA, l'insuline ou (IGF-1. A l'inverse, les inhibitions de la MAP kinase .kinase MEK ainsi que de la MAP kinase p38 (par l'utilisation des inhibiteurs spécifiques PD98059 et SB202190 respectivement) n'ont eu qu'un léger effet dans ces mêmes conditions. Ces résultats suggèrent que la NA, 'l'insuline et I~GF-1 régulent l'expression de la protéine MCT2 par un mécanisme commun impliquant probablement la voie Akt/PKB et l'activation de la traduction via mTOR. En conclusion, considérant l'implication de la NA, de l'insuline et de I`IGF-1 dans la plasticité synaptique, le contrôle traductionnel étroit exercé par ces substances sur l'expression de MCT2 pourrait être un moyen d'alimenter en substrats énergétiques autres que le glucose les synapses activées et également d'adapter l'approvisionnement en substrats énergétiques au niveau d'activité. Résumé « grand public » Le cerveau est un organe qui réalise des tâches complexes nécessitant un apport important en énergie. La principale source d'énergie du cerveau est le glucose. Bien que le cerveau ne représente que 2% de la masse corporelle, il consomme à lui seul plus de 25% du glucose et 20% de l'oxygène provenant de la circulation sanguine. La nécessité d'un tel apport en énergie réside dans la nature -même du fonctionnement des milliards de neurones qui utilisent des signaux électriques et chimiques pour communiquer entre eux. Hormis l'utilisation massive du glucose comme source d'énergie, le cerveau est capable de consommer d'autres substrats énergétiques dans certaines conditions physiologiques ou pathologiques. Les monocarboxylates (lactate, pyruvate et corps cétoniques) font partie de ces autres sources d'énergie. Contrairement au glucose, les monocarboxylates ne diffusent pas facilement de la circulation sanguine vers les neurones. Afin de pouvoir être consommés par les neurones, ils doivent être transportés par un système adapté. Ce sont des transporteurs appelés transporteurs aux monocarboxylates ou MCT qui permettent le passage de ces substrats énergétiques du sang vers les neurones. Le but de ce travail de thèse a été de comprendre comment est régulée l'expression de MCT2, l'un de ces transporteurs exprimé spécifiquement à la surface des neurones. Cette étude nous a permis de mettre en évidence que le neurotransmetteur noradrénaline ainsi que les hormones insuline et IGF-1 (insulinlike growth factor-1) sont capables d'induire une augmentation d'expression de MCT2 à la surface des neurones en culture. Nous avons ensuite voulu déterminer par quels mécanismes de signalisation ces substances agissent sur l'expression de MCT2. Nous avons pu observer que la surexpression de la protéine MCT2 est due à une augmentation d'activité traductionnelle (la traduction étant une des étapes qui permet la synthèse des protéines) induite par le biais d'une voie de signalisation particulière. En conclusion, lorsque la noradrénaline, l'insuline ou 17GF-1 agissent sur les neurones, la traduction de la protéine MCT2 est activée et on observe une augmentation de l'expression de MCT2. Ce mécanisme pourrait permettre d'augmenter l'apport énergétique au niveau des neurones en augmentant le nombre de transporteurs pour les substrats énergétiques que sont les monocarboxylates. D'un point de vue physiologique, cette régulation d'expression pourrait jouer un rôle primordial dans des situations d'apprentissage et de mémorisation. Sur le plan pathologique, cela pourrait permettre de prévenir les dommages causes aux neurones dans certains cas d'atteintes cérébrales.

Lack of thermogenic response to glucose/insulin infusion in diabetic obese subjects.

The change in energy expenditure consecutive to the infusion of glucose/insulin was examined in 17 non-obese (ten young, seven middle-aged) and 27 diabetic and non-diabetic obese subjects by employing the euglycemic insulin clamp technique in conjunction with continuous indirect calorimetry. The obese subjects were divided into four groups according to their response to a 100-g oral glucose test: group A, normal glucose tolerance; group B, impaired glucose tolerance; group C, diabetes with increased insulin response; group D, diabetes with reduced insulin response. The glucose/insulin infusion provoked an increase in energy expenditure in both young and middle-aged controls (+8.2 +/- 1.3 percent and +5.9 +/- 0.5 percent over the preinfusion baseline respectively), but a lower increase in the non-diabetic obese groups A and B (+4.0 +/- 0.7 percent and +2.0 +/- 1.0 percent over the preinfusion baseline respectively, P less than 0.05 and P less than 0.01 vs young controls). However, in the diabetic obese groups C and D, energy expenditure failed to increase in response to the glucose/insulin infusion (mean change: +0.1 +/- 1.0 percent and -2.0 +/- 1.9 percent (P less than 0.01, vs middle-aged) over the preinfusion baseline respectively). When the glucose-induced thermogenesis (GIT) was related to the glucose uptake--taking into account the hepatic glucose production--the GIT was found to be similarly reduced in the diabetics groups (C and D). The net change in the rate of energy expenditure was found to be significantly correlated with the rate of glucose uptake (r = +0.647, n = 44, P less than 0.001) when all the individuals were pooled. In conclusion, this study shows that the low glucose-induced thermogenesis in obese diabetics during glucose insulin infusion is mainly related to a reduced rate of glucose uptake; in addition, inhibition of gluconeogenesis by the glucose/insulin infusion may also contribute to decrease the thermogenic response.

Increased blood glucose variability during therapeutic hypothermia and neurological recovery after cardiac arrest

INTRODUCTION. Recent studies suggest that increased blood glucose variability (BGV) is associated with ICU mortality1. Hypothermia is known to induce insulin resistance, thus potentially increasing BGV. No studies however have examined the effect of therapeutic hypothermia (TH) on insulin requirements and BGV. OBJECTIVES. To examine the effect of TH on BGV and its relationship to outcome in patients with coma after cardiac arrest (CA). METHODS. We prospectively studied 132 consecutive comatose CA patients treated with TH (target core temp 33_C for 24 h, using surface cooling). All patients were treated with intravenous insulin (blood glucose target 6-8 mM), according to a written algorithm, with nurse-driven adjustment of insulin dose. For each patient, standard deviation of repeated blood glucose samples was used to calculate BGV. Two time-points, comparable in duration, were studied: TH (stable maintenance phase, i.e. 6-24 h, core temp ± 33_C) vs. Normothermia (NT, i.e. after rewarming, stable normothermic phase, core temp ± 37_C). Mortality and neurological recovery (Glasgow-Pittsburgh Cerebral Performance Categories, CPC, dichotomized as good = CPC 1-2 vs. poor = CPC 3-5) were assessed at hospital discharge. Statistical analysis was performed with ANOVA for repeated measures. RESULTS. Compared to NT, TH was associated with increased intravenous insulin dose (0.8 ± 1.1 vs. 1.6 ± 2 U/h, P\0.0001), higher mean (6.9 ± 1.3 vs. 7.7 ± 1.8 mM, P\0.0001) and maximum (9.1 ± 3.7 vs. 10.9 ± 3.6 mM, P\0.0001) blood glucose, and increased BGV (1.3 ± 1.2 vs. 1.7 ± 1.1 mM, P = 0.004). Increased BGV was strongly associated with mortality (2.5 ± 1.5 mM in non-survivors vs. 1.6 ± 1 mM in survivors, P\0.001) and worse outcome (2.3 ± 1.4 mM in patients with poor vs. 1.5 ± 0.8 mM in those with good neurological recovery, P\0.0001). CONCLUSIONS. Therapeutic hypothermia is associated with increased insulin requirements and higher blood glucose variability,which in turn correlateswithworse prognosis in patientswith post- CA coma. Strategies aimed to maintain stable glycemic profile and avoid blood glucose variability might contribute to optimize the management of TH and may translate into better outcome.

The cataract and glucosuria associated monocarboxylate transporter MCT12 is a new creatine transporter.

Creatine transport has been assigned to creatine transporter 1 (CRT1), encoded by mental retardation associated SLC6A8. Here, we identified a second creatine transporter (CRT2) known as monocarboxylate transporter 12 (MCT12), encoded by the cataract and glucosuria associated gene SLC16A12. A non-synonymous alteration in MCT12 (p.G407S) found in a patient with age-related cataract (ARC) leads to a significant reduction of creatine transport. Furthermore, Slc16a12 knockout (KO) rats have elevated creatine levels in urine. Transport activity and expression characteristics of the two creatine transporters are distinct. CRT2 (MCT12)-mediated uptake of creatine was not sensitive to sodium and chloride ions or creatine biosynthesis precursors, breakdown product creatinine or creatine phosphate. Increasing pH correlated with increased creatine uptake. Michaelis-Menten kinetics yielded a Vmax of 838.8 pmol/h/oocyte and a Km of 567.4 µm. Relative expression in various human tissues supports the distinct mutation-associated phenotypes of the two transporters. SLC6A8 was predominantly found in brain, heart and muscle, while SLC16A12 was more abundant in kidney and retina. In the lens, the two transcripts were found at comparable levels. We discuss the distinct, but possibly synergistic functions of the two creatine transporters. Our findings infer potential preventive power of creatine supplementation against the most prominent age-related vision impaired condition.

Glucose and lactate are equally effective in energizing activity-dependent synaptic vesicle turnover in purified cortical neurons.

This study examines the role of glucose and lactate as energy substrates to sustain synaptic vesicle cycling. Synaptic vesicle turnover was assessed in a quantitative manner by fluorescence microscopy in primary cultures of mouse cortical neurons. An electrode-equipped perfusion chamber was used to stimulate cells both by electrical field and potassium depolarization during image acquisition. An image analysis procedure was elaborated to select in an unbiased manner synaptic boutons loaded with the fluorescent dye N-(3-triethylammoniumpropyl)-4-(4-(dibutylamino)styryl)pyridinium dibromide (FM1-43). Whereas a minority of the sites fully released their dye content following electrical stimulation, others needed subsequent K(+) depolarization to achieve full release. This functional heterogeneity was not significantly altered by the nature of metabolic substrates. Repetitive stimulation sequences of FM1-43 uptake and release were then performed in the absence of any metabolic substrate and showed that the number of active sites dramatically decreased after the first cycle of loading/unloading. The presence of 1 mM glucose or lactate was sufficient to sustain synaptic vesicle cycling under these conditions. Moreover, both substrates were equivalent for recovery of function after a phase of decreased metabolic substrate availability. Thus, lactate appears to be equivalent to glucose for sustaining synaptic vesicle turnover in cultured cortical neurons during activity.

Critical role for the lactate transporter, monocarboxylate transporter 1 (mct1), in the regeneration of peripheral nerves

Axons, and particularly regenerating axons, have high metabolic needs in order to maintain critical functions such as axon transport and membrane depolarization. Though some of the required energy likely comes form extracellular glucose and ATP generated in the soma, we and others hypothesize that some of the energy may be supplied by lactate. Unlike glucose that requires glycolytic enzymes to produce pyruvate, lactate can be converted directly to pyruvate by lactate dehydrogenase and transported into mitochondria for oxidative metabolism. In order to be transported into or out of cells, lactate requires specific monocarboxylate transporters (MCTs), the most abundant of which is MCT1. If MCT1 and lactate are critical for nerve function and regeneration, we hypothesize that MCT1 heterozygote null mice, which appear phenotypically normal despite having approximately 40% MCT1 as compared to wildtype littermate mice, would have reduced capacity for repair following nerve injury. To investigate this, adult MCT1 heterozygote null mice or wild-type mice underwent unilateral sciatic nerve crush in the proximal thigh. We found that regeneration of the sciatic nerve, as measured by recovery of compound muscle action potentials (CMAP) in the lateral plantar muscles following proximal sciatic nerve stimulation, was delayed from a median of 21 days in wildtype mice to 38.5 days in MCT1 heterozygote mice. In fact, half of the MCT1 heterozygote null mice had no recovery of CMAP by the endpoint of the study at 42 days, while all of the wild-type mice had recovered. In addition, the maximal amplitude of CMAP recovery in MCT1 heterozygote mull mice was reduced from a mean of 3 mV to 0.5 mV. As would be expected, the denervated gastrocnemius muscle of MCT1 heterozygote null mice remained atrophic at 42 days compared to wild-type mice. Our experiments show that lactate supplied through MCT1 is necessary for nerve regeneration. Experiments are underway to determine whether loss of MCT1 prevents nerve regrowth directly due to reduced energy supply to axons or indirectly by dysfunctional Schwann cells normally dependent on lactate supply through MCT1.

Use of an in-house approach to study the three-dimensional structures of various outer membrane proteins: structure of the alcaligin outer membrane transporter FauA from Bordetella pertussis.

Bordetella pertussis is the bacterial agent of whooping cough in humans. Under iron-limiting conditions, it produces the siderophore alcaligin. Released to the extracellular environment, alcaligin chelates iron, which is then taken up as a ferric alcaligin complex via the FauA outer membrane transporter. FauA belongs to a family of TonB-dependent outer membrane transporters that function using energy derived from the proton motive force. Using an in-house protocol for membrane-protein expression, purification and crystallization, FauA was crystallized in its apo form together with three other TonB-dependent transporters from different organisms. Here, the protocol used to study FauA is described and its three-dimensional structure determined at 2.3 A resolution is discussed.

The mif gene is transcriptionally regulated by glucose in insulin-secreting cells.

Macrophage migration inhibitory factor (MIF) is an important regulator of glucose homeostasis. In pancreatic beta-cells, MIF expression is regulated by glucose and its secretion potentiates the glucose-induced insulin secretion. The molecular mechanisms by which glucose mediates its effect on MIF expression are not elucidated. Herein, we report that incubating the differentiated insulin-secreting cell line INS-1 in high glucose concentration increases MIF transcriptional activity as well as the reporter gene activity driven by the -1033 to +63 bp fragment of the MIF promoter. A minimal region located between -187 and -98 bp of this promoter sequence contributes both to basal activity and glucose-responsiveness of the gene. Within this promoter region, two cis-binding sequences were identified by mobility shift assays and footprinting experiments. Both cis-elements interact with nuclear proteins expressed specifically in insulin-secreting cells. In conclusion, we identified a minimal region of the MIF promoter which contributes to the glucose stimulation of the mif gene in insulin-secreting cells.

Blood glucose and prognosis in children with presumed severe malaria: is there a threshold for 'hypoglycaemia'?

OBJECTIVES: Hypoglycaemia (glucose <2.2 mmol/l) is a defining feature of severe malaria, but the significance of other levels of blood glucose has not previously been studied in children with severe malaria. METHODS: A prospective study of 437 consecutive children with presumed severe malaria was conducted in Mali. We defined hypoglycaemia as <2.2 mmol/l, low glycaemia as 2.2-4.4 mmol/l and hyperglycaemia as >8.3 mmol/l. Associations between glycaemia and case fatality were analysed for 418 children using logistic regression models and a receiver operator curve (ROC). RESULTS: There was a significant difference between blood glucose levels in children who died (median 4.6 mmol/l) and survivors (median 7.6 mmol/l, P < 0.001). Case fatality declined from 61.5% of the hypoglycaemic children to 46.2% of those with low glycaemia, 13.4% of those with normal glycaemia and 7.6% of those with hyperglycaemia (P < 0.001). Logistic regression showed an adjusted odds ratio (AOR) of 0.75 (0.64-0.88) for case fatality per 1 mmol/l increase in baseline blood glucose. Compared to a normal blood glucose, hypoglycaemia and low glycaemia both significantly increased the odds of death (AOR 11.87, 2.10-67.00; and 5.21, 1.86-14.63, respectively), whereas hyperglycaemia reduced the odds of death (AOR 0.34, 0.13-0.91). The ROC [area under the curve at 0.753 (95% CI 0.684-0.820)] indicated that glycaemia had a moderate predictive value for death and identified an optimal threshold at glycaemia <6.1 mmol/l, (sensitivity 64.5% and specificity 75.1%). CONCLUSIONS: If there is a threshold of blood glucose which defines a worse prognosis, it is at a higher level than the current definition of 2.2 mmol/l.

Impact of genetic SLC28 transporter and ITPA variants on ribavirin serum level, hemoglobin drop and therapeutic response in patients with HCV infection.

BACKGROUND & AIMS: In the last decade, pegylated interferon- 45; (PegIFN- 45;) plus ribavirin (RBV) was the standard treatment of chronic hepatitis C for genotype 1, and it remains the standard for genotypes 2 and 3. Recent studies reported associations between RBV-induced anemia and genetic polymorphisms of concentrative nucleoside transporters such as CNT3 (encoded by SLC28A3) and inosine triphosphatase (encoded by ITPA). We aimed at studying genetic determinants of RBV kinetics, efficacy and treatment-associated anemia. METHODS: We included 216 patients from two Swiss study cohorts (61% HCV genotype 1, 39% genotypes 2 or 3). Patients were analyzed for SLC28A2 single nucleotide polymorphism (SNP) rs11854484, SLC28A3 rs56350726, and SLC28A3 rs10868138 as well as ITPA SNPs rs1127354 and rs7270101, and followed for treatment-associated hemoglobin changes and sustained virological response (SVR). In 67 patients, RBV serum levels were additionally measured during treatment. RESULTS: Patients with SLC28A2 rs11854484 genotype TT had higher dosage- and body weight-adjusted RBV levels than those with genotypes TC or CC (p=0.02 and p=0.06 at weeks 4 and 8, respectively). ITPA SNP rs1127354 was associated with hemoglobin drop ≥3 g/dl during treatment, in genotype (relative risk (RR)=2.1, 95% CI 1.3-3.5) as well as allelic analyses (RR=2.0, 95%CI 1.2-3.4). SLC28A3 rs56350726 was associated with SVR in genotype (RR=2.2; 95% CI 1.1-4.3) as well as allelic analyses (RR=2.0, 95% CI 1.1-3.4). CONCLUSIONS: The newly identified association between RBV serum levels and SLC28A2 rs11854484 genotype, as well as the replicated association of ITPA and SLC28A3 genetic polymorphisms with RBV-induced anemia and treatment response, may support individualized treatment of chronic hepatitis C and warrant further investigation in larger studies.

Impaired activation of protein kinase C-zeta by insulin and phosphatidylinositol-3,4,5-(PO4)3 in cultured preadipocyte-derived adipocytes and myotubes of obese subjects.

Insulin resistance in obesity is partly due to diminished glucose transport in myocytes and adipocytes, but underlying mechanisms are uncertain. Insulin-stimulated glucose transport requires activation of phosphatidylinositol (PI) 3-kinase (3K), operating downstream of insulin receptor substrate-1. PI3K stimulates glucose transport through increases in PI-3,4,5-(PO(4))(3) (PIP(3)), which activates atypical protein kinase C (aPKC) and protein kinase B (PKB/Akt). However, previous studies suggest that activation of aPKC, but not PKB, is impaired in intact muscles and cultured myocytes of obese subjects. Presently, we examined insulin activation of glucose transport and signaling factors in cultured adipocytes derived from preadipocytes harvested during elective liposuction in lean and obese women. Relative to adipocytes of lean women, insulin-stimulated [(3)H]2-deoxyglucose uptake and activation of insulin receptor substrate-1/PI3K and aPKCs, but not PKB, were diminished in adipocytes of obese women. Additionally, the direct activation of aPKCs by PIP(3) in vitro was diminished in aPKCs isolated from adipocytes of obese women. Similar impairment in aPKC activation by PIP(3) was observed in cultured myocytes of obese glucose-intolerant subjects. These findings suggest the presence of defects in PI3K and aPKC activation that persist in cultured cells and limit insulin-stimulated glucose transport in adipocytes and myocytes of obese subjects.

Inhibitory effects of (2S, 3S)-3-[3-[4-(trifluoromethyl)benzoylamino]benzyloxy]aspartate (TFB-TBOA) on the astrocytic sodium responses to glutamate.

Astrocytes are responsible for the majority of the clearance of extracellular glutamate released during neuronal activity. dl-threo-beta-benzyloxyaspartate (TBOA) is extensively used as inhibitor of glutamate transport activity, but suffers from relatively low affinity for the transporter. Here, we characterized the effects of (2S, 3S)-3-[3-[4-(trifluoromethyl)benzoylamino]benzyloxy]aspartate (TFB-TBOA), a recently developed inhibitor of the glutamate transporter on mouse cortical astrocytes in primary culture. The glial Na(+)-glutamate transport system is very efficient and its activation by glutamate causes rapid intracellular Na(+) concentration (Na(+)(i)) changes that enable real time monitoring of transporter activity. Na(+)(i) was monitored by fluorescence microscopy in single astrocytes using the fluorescent Na(+)-sensitive probe sodium-binding benzofuran isophtalate. When applied alone, TFB-TBOA, at a concentration of 1 muM, caused small alterations of Na(+)(i). TFB-TBOA inhibited the Na(+)(i) response evoked by 200 muM glutamate in a concentration-dependent manner with IC(50) value of 43+/-9 nM, as measured on the amplitude of the Na(+)(i) response. The maximum inhibition of glutamate-evoked Na(+)(i) increase by TFB-TBOA was >80%, but was only partly reversible. The residual response persisted in the presence of the AMPA/kainate receptor antagonist CNQX. TFB-TBOA also efficiently inhibited Na(+)(i) elevations caused by the application of d-aspartate, a transporter substrate that does not activate non-NMDA ionotropic receptors. TFB-TBOA was found not to influence the membrane properties of cultured cortical neurons recorded in whole-cell patch clamp. Thus, TFB-TBOA, with its high potency and its apparent lack of neuronal effects, appears to be one of the most useful pharmacological tools available so far for studying glial glutamate transporters.

Effects of lactate on glucose metabolism in healthy subjects and in severely injured hyperglycemic patients.

Hepatic glucose production is autoregulated during infusion of gluconeogenic precursors. In hyperglycemic patients with multiple trauma, hepatic glucose production and gluconeogenesis are increased, suggesting that autoregulation of hepatic glucose production may be defective. To better understand the mechanisms of autoregulation and its possible alterations in metabolic stress, lactate was coinfused with glucose in healthy volunteers and in hyperglycemic patients with multiple trauma or critical illness. In healthy volunteers, infusion of glucose alone nearly abolished endogenous glucose production. Lactate increased gluconeogenesis (as indicated by a decrease in net carbohydrate oxidation with no change in total [13C]carbohydrate oxidation) but did not increase endogenous glucose production. In patients with metabolic stress, endogenous glucose production was not suppressed by exogenous glucose, but lactate did not further increase hepatic glucose production. It is concluded that 1) in healthy humans, autoregulation of hepatic glucose production during infusion of lactate is still present when glycogenolysis is suppressed by exogenous glucose and 2) autoregulation of hepatic glucose production is not abolished in hyperglycemic patients with metabolic stress.

Desensitization and phosphorylation of the glucagon-like peptide-1 (GLP-1) receptor by GLP-1 and 4-phorbol 12-myristate 13-acetate.

Glucagon-like peptide-1 (GLP-1) stimulates glucose-induced insulin secretion by binding to a specific G protein-coupled receptor linked to activation of the adenylyl cyclase pathway. Here, using insulinoma cell lines, we studied homologous and heterologous desensitization of GLP-1-induced cAMP production. Preexposure of the cells to GLP-1 induced a decrease in GLP-1-mediated cAMP production, as assessed by a 3- to 5-fold rightward shift of the dose-response curve and an approximately 20 percent decrease in the maximal production of cAMP. Activation of protein kinase C by the phorbol ester phorbol 12-myristate 13-acetate (PMA) also induced desensitization of the GLP-1-mediated response, leading to a 6- to 9-fold shift in the EC50 and a 30% decrease in the maximal production of cAMP. Both forms of desensitization were additive, and the protein kinase C inhibitor RO-318220 inhibited PMA-induced desensitization, but not agonist-induced desensitization. GLP-1- and PMA-dependent desensitization correlated with receptor phosphorylation, and the levels of phosphorylation induced by the two agents were additive. Furthermore, PMA-induced, but not GLP-1-induced, phosphorylation was totally inhibited by RO-318220. Internalization of the GLP-1 receptor did not participate in the desensitization induced by PMA, as a mutant GLP-1 receptor lacking the last 20 amino acids of the cytoplasmic tail was found to be totally resistant to the internalization process, but was still desensitized after PMA preexposure. PMA and GLP-1 were not able to induce the phosphorylation of a receptor deletion mutant lacking the last 33 amino acids of the cytoplasmic tail, indicating that the phosphorylation sites were located within the deleted region. The cAMP production mediated by this deletion mutant was not desensitized by PMA and was only poorly desensitized by GLP-1. Together, our results indicate that the production of cAMP and, hence, the stimulation of insulin secretion induced by GLP-1 can be negatively modulated by homologous and heterologous desensitization, mechanisms that involve receptor phosphorylation.