Peroxisome Proliferator-activated Receptor gamma  Thiazolidinedione Agonists Increase Glucose Metabolism in Astrocytes*

Cinzia Dello RussoDagger §, Vitaliy GavrilyukDagger , Guy WeinbergDagger ||, Angeles Almeida**, Juan P. Bolanos**, June PalmerDagger , Dale PelligrinoDagger , Elena GaleaDagger , and Douglas L. FeinsteinDagger ||

From the Dagger  Department of Anesthesiology, University of Illinois, Chicago, Illinois, 60612, || Veterans Affairs Chicago Health Care System West Side Division, Chicago, Illinois, 60680, ** Departmento de Bioquimica y Biologia Molecular, Universidad de Salamanca, Salamanca 37007, Spain, and § Institute of Pharmacology, Catholic University Medical School, Rome 00168, Italy

Received for publication, August 8, 2002, and in revised form, December 5, 2002

    ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
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Activation of peroxisome proliferator-activated receptors (PPARs) can regulate brain physiology and provide protection in models of neurological disease; however, neither their exact targets nor mechanisms of action in brain are known. In many cells, PPARgamma agonists increase glucose uptake and metabolism. Because astrocytes store glucose and provide lactate to neurons on demand, we tested effects of PPARgamma agonists on astroglial glucose metabolism. Incubation of cortical astrocytes with the PPARgamma thiazolidinedione (TZD) agonist pioglitazone (Pio) significantly increased glucose consumption in a time- and dose-dependent manner, with maximal increase of 36% observed after 4 h in 30 µM Pio. Pio increased 2-deoxy-glucose uptake because of increased flux through the type 1 glucose transporter. However, at this time point Pio did not increase type 1 glucose transporter expression, nor were its effects blocked by transcriptional or translational inhibitors. Pio also increased astrocyte lactate production as soon as 3 h after incubation. These effects were replicated by other TZDs; however, the order of efficacy (troglitazone > pioglitazone > rosiglitazone) suggests that effects were not mediated via PPARgamma activation. TZDs increased astrocyte cAMP levels, and their glucose modifying effects were reduced by protein kinase A inhibitors. TZDs inhibited state III respiration in isolated brain mitochondria, whereas in astrocytes they caused mitochondrial membrane hyperpolarization. Pio protected astrocytes against hypoglycemia-induced cell death. Finally, glucose uptake was modified in brain sections prepared from Pio-fed rats. These results demonstrate that TZDs modify astrocyte metabolism and mitochondrial function, which could be beneficial in neurological conditions where glucose availability is reduced.

    INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The peroxisome proliferator-activated receptors (PPARs)1 are nuclear hormone receptors that can bind to PPAR elements (AGGTCA n AGGTCA) to activate transcription (1-3) normally as heterodimers with the retinoic acid receptor (4-6). Three major subtypes have been identified (alpha , delta  (or beta ), and gamma ) with distinct actions on cell physiology and different specificity in their ligand-binding properties (7). PPARgamma is widely expressed in the adipose tissue where it controls adipocyte differentiation and lipid metabolism (8). The agonists of PPARgamma include fatty acids, non-steroidal anti-inflammatory drugs like ibuprofen (9), the natural ligand 15-deoxy-Delta -12,14-prostaglandin J2 (10), thiazolidinediones (TZDs) such as troglitazone (Trog), pioglitazone (Pio), and rosiglitazone (Rosi) (11), and high affinity tyrosine-based agonists like GW347845 (7). TZDs were originally designed as antidiabetic drugs because of their insulin-sensitizing effects, and several are in clinical use (12-14).

Recently, it has been shown that PPARgamma is involved in the regulation of inflammatory responses (15-18). Thus, PPARgamma activation contributes to reduce the secretion of proinflammatory cytokines and neurotoxic substances from activated monocytes (19-21) and microglia (22). Our previous studies showed that PPARgamma agonists are able to down-regulate neuronal inducible nitric-oxide synthase expression and to reduce cerebellar granule cell death in vitro (23) and in vivo (24). More recently, we demonstrated that PPARgamma agonists reduced the development of clinical symptoms in experimental autoimmune encephalomyelitis, a commonly used animal model for multiple sclerosis (25). These findings have led to the possibility that PPARgamma agonists could provide protection in other neurodegenerative diseases, such as Alzheimer's disease (26), stroke (27), Parkinson's disease (28), and multiple sclerosis (25, 29-31). PPARgamma activation may regulate several functions in brain, in addition to inflammation, including promoting neurite extension (32) and inducing myelin gene expression (33). However, neither the exact targets nor the mechanisms of protection due to PPARgamma activation in brain are well known.

Studies carried out in liver, adipose tissue (34-37), and muscle (38-40) showed that in periphery, PPARgamma regulates glucose metabolism by increasing glucose uptake through facilitative glucose transporter proteins (GLUTs). Delivery of glucose in the central nervous system is mainly mediated by GLUTs present on the brain-blood barrier, on glial cells, and on neurons (41, 42). However the primary energy source in brain is provided by astrocytes. These cells are able to store glucose in the form of glycogen and provide lactate to neurons on demand (43). Because glucose metabolism could be adversely affected in some neurodegenerative disorders (44-47), we hypothesized that one mechanism of PPARgamma agonists protection during disease could be related to an increase of cerebral metabolism of glucose.

To test this hypothesis we examined the effects of TZDs on glucose uptake and metabolism in primary enriched cultures of rat cortical astrocytes. Incubation with these drugs increased glucose utilization (assessed as loss of glucose from the incubation media), 2-deoxy-glucose uptake, and lactate production. These effects did not appear to be mediated by activation of PPARgamma or to changes in gene expression but instead because of a rapid effect on other cellular signaling systems possibly related to changes in mitochondrial respiration. Our results demonstrate that TZDs can increase astroglial glucose metabolism, suggesting that this class of drugs may be therapeutically useful in conditions in which brain glucose levels or availability are limited.

    EXPERIMENTAL PROCEDURES
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Materials-- Cell culture reagents (DMEM and antibiotics) and LPS (Salmonella typhimurium) were from Sigma. Fetal calf serum (FCS) was from Invitrogen. Pio was from Takeda Pharmaceuticals North America (Lincolnshire, IL). Rosi was from GlaxoSmithKline. Trog was from Parke-Davis. GW347845 was a gift of Tim Willson (GlaxoSmithKline). Polyclonal antibodies directed against GLUT-1 (AB-1340, which recognizes the carboxyl terminus of rat GLUT-1) and GLUT-3 (AB-1344, which recognizes the carboxyl terminus of the mouse GLUT-3) were from Chemicon International (Temecula, CA). Horseradish peroxidase-conjugated rabbit secondary antibodies were from Vector Laboratories (Burlingame, CA). Enhanced chemiluminescence reagents were from Pierce. Taq polymerase and cDNA synthesis reagents were from Promega. Cell viability was assessed by measurement of released lactate dehydrogenase according to the manufacturer's procedures, using the CytoTox-96 kit from Promega.

Cells-- Primary astrocytes were from cerebral cortices of postnatal day 1-2 Harlan Sprague-Dawley rats as described previously (48). Media were changed every 3 days. After 2 weeks growth in DMEM containing 25 mM glucose, 10% FCS, and antibiotics (penicillin and streptomycin) the cultures consisted of 95-98% astrocytes and 2-3% microglia.

Glucose and Lactate Assays-- Glucose and lactate concentrations in the incubation media was assessed by a quantitative enzymatic colorimetric kit, according the manufacturer's instructions with some modifications. Briefly, 5-µl aliquots of media were incubated with 100 µl of Sigma Diagnostic Glucose Trinder reagent for 10 min at 37 °C, and the absorbance was read at 492 nm. For lactate, samples were incubated with 90 µl of Sigma Diagnostic Lactate reagent for 20 min at room temperature, and absorbance was read at 550 nm. In each assay, a standard curve was prepared in the range of 0 to 100 mg/100 ml of D-glucose or 0 to 50 mg/100 ml of L-lactate in DMEM. Levels in each sample were calculated by interpolation from standard curves.

2-Deoxy-Glucose Uptake-- For glucose uptake experiments, astrocytes were pre-incubated in low glucose (5 mM instead of 25 mM) DMEM with 1% FCS containing different concentrations of Pio. During pre-incubation, aliquots were collected at different time points for subsequent glucose and lactate assessments. After 6 h of pre-incubation, the medium was replaced by 250 µl of glucose-free DMEM to which was added increasing concentrations of D-glucose (0.05-1 mM) and 1 µCi/ml of 2-deoxy-D-[2,6-3H]glucose (2-DG; Amersham Biosciences), final concentration 24 nM, and cells were further incubated for 10-90 min. At the end of the uptake experiment the medium was removed, and the cells were washed three times with 1 ml of ice-cold phosphate-buffered saline and then lysed by adding 250 µl of 200 mM NaOH. An aliquot of 200 µl was assayed for 3H by liquid scintillation counting. Protein content was measured in the same samples by Bradford's method in 50 µl of the remaining lysates. [3H]2-DG uptake was expressed in pmol/mg of protein or nmol of glucose/mg protein.

NOS2 Induction and Activity Measurements-- Cells were grown to 90-95% confluency, the growth media were removed, the cells were washed in serum-free media, and incubations were carried out in fresh DMEM containing antibiotics and 1% FCS. NOS2 was induced by incubation with bacterial endotoxin LPS (1 µg/ml). Induction of NOS2 was assessed indirectly by nitrite production in the cell culture media. An aliquot of the cell culture media (80 µl) was mixed with one-half volume of Griess reagent (49), and the absorption was measured at 550 nm. Solutions of NaNO2 dissolved in DMEM/1% FCS served as standards.

mRNA Analysis-- Total cytoplasmic RNA was prepared from cells using TRIZOL reagent (Invitrogen), aliquots were converted to cDNA using random hexamer primers, and mRNA levels were estimated by real time, quantitative RT-PCR (50). The primers used for GLUT-1 detection were 939F (5'-TGA AAG AAG AGG GTC GGC AGA TAA-3'), corresponding to bases 939-960, and 1301R (5' AGA TGG CCA CGA TGC TCA GAT AGG-3'), complementary to bases 1278-1301 of the rat GLUT-1 cDNA sequence, which yield a 363-bp product. The primers used for GLUT-3 were 978F (5'-GGA GCG GGC AGG AAG GAG AA-3') and 1305R (5'-AGA AAA CGA GGA AGG CAG CGA AGA-3'), which correspond to bases 978-998 and 1281-1305, respectively, and which yield a 328-bp product. The primers used for glyceraldehyde-3-phosphate dehydrogenase detection were 796F (5' GCC AAG TAT GAT GAC ATC AAG AAG) and 1059R (5' TCC AGG GGT TTC TTA CTC CTT GGA), which yield a 264-bp product. The primers used for PPARgamma were 642F (5'-GCC TTG CTG TGG GGA TGT CTG-3') and 995R (5'-CGA AAC TGG CAC CCT TGA AAA ATG-3') from the rat PPARgamma sequence NM_013124.1, and they yield a 354-bp product. Cycling conditions were 35 cycles of denaturation at 94 °C for 10 s, annealing at 61 °C for 15 s, and extension at 72 °C for 20 s, followed by 2 min at 72 °C, in the presence of SYBR Green (1:10,000 dilution of stock solution from Molecular Probes, Eugene, OR) carried out in a 20-µl reaction in a Corbett Rotor-Gene (Corbett Research, Sydney, Australia). Relative mRNA concentrations were calculated from the relative take-off point of the PCR reactions using the manufacturer's software included in the unit. Correct product synthesis was confirmed by melting curve analysis, which yielded a single melting point, and by electrophoresis through 2% agarose gels containing ethidium bromide of the PCR products.

Western Blot Analysis-- Astrocytes were grown until confluent and then incubated in DMEM containing 5 mM glucose and 30 µM Pio or the equivalent amount of Me2SO for 6 or 24 h. Cells were washed twice with ice-cold phosphate-buffered saline, harvested by scraping, collected by centrifugation (700 × g for 10 min), and placed on ice. Subcellular fractionation was carried out as described (51, 52). Briefly, cells were resuspended in lysis buffer (250 mM sucrose, 5 mM NaN3, 2 mM EGTA, 1/100 protease inhibitor mixture (P8320; Sigma), and 20 mM HEPES, pH 7.4) and then homogenized using a Dounce homogenizer. The homogenate was centrifuged at 760 × g for 5 min to remove unbroken cells and nuclei; the supernatant was collected and centrifuged at 31,000 × g for 60 min to pellet the crude plasma membrane and collect the supernatant as cytoplasmic fraction. Protein content was determined by Bradford's method using bovine serum albumin as standard. Ten µg of protein of each sample were mixed 1:3 with 3× gel sample buffer (150 mM Tris-HCl, pH 6.8, 7.5% SDS, 45% glycerol, 7.5% bromphenol blue, 15% beta -mercaptoethanol), denatured at 70 °C for 5 min, and separated through SDS-10% acrylamide gels. Denaturation at 70 °C versus boiling reduces aggregation of GLUT-1 in gels.2 Apparent molecular weights were estimated by comparison to BenchMarkTM prestained protein ladder standards (Invitrogen). After electrophoresis, proteins were transferred to polyvinylidene difluoride membranes by semi-dry electrophoretic transfer. The membranes were blocked with 10% (w/v) low-fat milk in TBST (10 mM Tris, 150 mM NaCl, 0.1% (w/v) Tween 20, pH 7.6) for 1 h and incubated in the presence of antibody (anti-GLUT-1 at 1:5000 dilution, anti-GLUT-3 at 1:1000 dilution) overnight with gentle shaking at 4 °C (53). The primary antibody was removed, and the membranes were washed four times in TBST and incubated for 1 h at room temperature with horseradish peroxidase-conjugated anti-rabbit IgG secondary antibody diluted 1:40,000 for GLUT-1 and 1:8,000 for GLUT-3. After four washes in TBST, bands were visualized by incubation in enhanced chemiluminescence reagents for 1 min and exposure to x-ray film for 1 min (for membranes) or 5-10 min (for cytosolic). Band intensities were determined using ImageJ software (National Institutes of Health) from autoradiographs obtained from at least two different exposure times, and background intensities (determined from an equal-sized area of the film immediately below the band of interest) were subtracted.

cAMP Assay-- Cells were incubated in 1% FCS in DMEM in the presence of indicated drugs. An initial time course (10-90 min) was carried out in the presence of 10 µM Pio, and a 30-min incubation time was chosen for the experiments. After incubation, cells were washed three times with physiological saline (Ca2+- and Mg2+-free) and then flooded with 100 µl of 5% trichloroacetic acid. After 5 min, the supernatant was removed, and cells were washed again with 100 µl of water. Trichloroacetic acid supernatant and wash water were combined and extracted with ether. cAMP was assessed using an enzymatic immunoassay kit purchased from Biomedical Technologies Inc. (Staughton, MA) according to the manufacturer's instructions. Sample concentrations were calculated using a standard curve constructed by plotting relative binding values (B/Bo = cAMP bound/cAMP total) versus log of concentration (pg/ml).

Isolation and Assay of Brain Mitochondria-- Rat brain mitochondria were isolated as described (54). Briefly, brains were homogenized in isolation buffer using 10 ml per gram of brain, in a 50-ml centrifuge tube with a tight fitting pestle. The homogenate was centrifuged at 5,000 × g for 10 min, the supernatant was removed, and the pellet was re-extracted with isolation buffer. The two supernatants were combined and centrifuged at 16,700 × g. The upper half from this was discarded, and the lower portion combined 1:1 with 15% Percoll and mixed gently. The resulting material was layered onto a Percoll step gradient (23% on top of 40%) and centrifuged at 30,700 × g. The fraction accumulating at the interface was collected, slowly diluted 1:4 with isolation buffer, and centrifuged at 16,700 × g for 10 min to yield the final mitochondrial pellet.

Mitochondrial respiration was carried out at 30 °C and monitored as described previously (55). Respiratory control ratios measured as the ratio of state III (ADP-supported) to state IV (resting) were consistently above ten. Respiration was initiated by the addition of substrate (pyruvate, 10 mM final concentration). Calculations of respiratory rates, in units of ng atoms oxygen per min per mg, were derived from the slopes of oxygen consumption in the reaction chamber, which were linear for over 10 min.

Measurement of Mitochondrial Membrane Potential-- Primary rat astrocytes were grown in 25-cm2 Petri dishes at a density of about 200,000 cells/cm2 in DMEM containing 1% FCS. When confluent, cells were treated with 10 µM of Pio or Trog or the corresponding amount of vehicle (Me2SO). After 6 h, the medium was removed, and cells were trypsinized and used for measurements of JC-1 aggregate fluorescence as described (56). For each sample, the measurements were made three times, and the S.D. values were within 10% of the means. The ratios of FL2 (fluorescence because of JC-1 aggregation) to FL1 fluorescence (because of monomeric JC-1) were determined and normalized to the values obtained for incubation in vehicle alone. Complete mitochondrial depolarization was obtained by addition of carbonyl cyanide p-trifluoromethoxyphenylhydrazone (5 µM for 5 min) to the cells, and that value was assigned as 0%.

In Vivo Experiments-- Female Sprague-Dawley rats (Charles River Laboratories, Wilmington MA), weighing 250-300 g were housed in groups of four at 22 °C and in a 12-h light/dark cycle with free access to food and water. Pio was added to Purina chow 5002 at 0 or 100 ppm. Rats were provided free access to diets for different days as indicated. On the day of the experiment, the animals were killed by decapitation. The brains were quickly removed from the skull, and the cortices were dissected under aseptic conditions. Coronal slices were made across the cortex to produce sections with two cut surfaces and having approximately the same weight, as assessed by protein measurement at the end of each experiment. All slices from the same animal were collected in a 35-mm Petri dish containing 7 ml of DMEM containing 5 mM glucose and 1% FCS and incubated at 37 °C in a humidified atmosphere containing 5% CO2. After 45 min of pre-incubation, during which the incubation medium was replaced twice, the slices were transferred to a 48-well plate containing 500 µl/well of low glucose DMEM and further incubated for 4 h. Aliquots of 5 µl were collected after different times to assess glucose levels. At the end of each experiment measurements of lactate dehydrogenase showed no differences in lactate dehydrogenase released between control and Pio-treated slices.

Data Analysis-- Experiments were done at least in triplicate unless noted otherwise. Data were analyzed by one- or two-way ANOVA followed by Dunnett's multiple comparison or Bonferroni post hoc tests, and p values < 0.05 were considered significant.

    RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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Rat Astrocytes Express PPARgamma -- PCR analysis showed that the mRNA corresponding to PPARgamma is present in unstimulated confluent primary cultures of rat cortical astrocytes (Fig. 1). Incubation with the PPARgamma agonist Pio (30 µM) did not significantly modify steady state PPARgamma mRNA levels measured after 24 h. Inflammatory activation with bacterial endotoxin LPS significantly reduced (by about 50%) PPARgamma steady state mRNA levels measured after 24 h, and this decrease was not significantly affected by co-incubation with Pio. These results demonstrate that as reported previously (57), rat astrocytes express PPARgamma mRNA and that its levels, although responsive to inflammatory stimuli, are not significantly altered upon incubation with a selective PPARgamma agonist.


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Fig. 1.   Rat astrocytes express PPARgamma . Total RNA was prepared from primary cortical astrocytes after 24 h of incubation in media alone, with 30 µM Pio, with 1 µg/ml LPS, or with Pio and LPS. Real time RT-PCR analysis for levels of the PPARgamma mRNA was carried out described under "Experimental Procedures." The top panel shows a representative gel image of PCR products obtained at the end of the analysis from two different RNA samples for each condition. The bottom panel shows the real time quantitative results and is the mean ± S.D. of two different samples for each group, each measured in triplicate. The experiment was carried out two other times with similar results. Incubation with LPS significantly reduced PPARgamma mRNA levels (p = 0.0011, two-way ANOVA).

Pioglitazone Increases Glucose Utilization-- Cortical rat astrocytes were incubated in low glucose (5 mM) containing medium, and glucose consumption, assessed as loss of glucose from the incubation media, was measured after different times up to 24 h in the presence of increasing amounts of Pio (0-30 µM). Control cells used glucose from the media (8.1 ± 1.0% per h), most likely because of maintenance of basal energetic needs. Pio time- and dose-dependently increased the rate of glucose utilization (9.0 ± 0.9 and 12.8 ± 0.5% per h, at 10 and 30 µM, respectively; see Fig. 2), and this effect was significant at 30 µM Pio as soon as 4 h of incubation. After 24 h, Pio-treated cells continued to show an increased amount of glucose utilization (control, 80.0 ± 1.6% compared with 30 µM Pio with almost 100% of the available glucose used) (data not shown).


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Fig. 2.   Pio dose- and time-dependently increases glucose utilization. Primary cortical astrocytes were incubated in DMEM containing 5 mM glucose and 1% FCS, together with 0, 10, or 30 µM Pio. Glucose levels in the culture media were measured at indicated times. Data are means ± S.E. of n = 4 replicates and are expressed as % of glucose consumed, determined as loss of glucose from the incubation media. *, p < 0.05; ***, p < 0.001 versus control (two-way ANOVA, Bonferroni multiple post hoc comparison).

Pioglitazone Increases 2-Deoxy-glucose Uptake-- In control astrocytes, uptake of 2-DG was linear during 90 min of incubation (Fig. 3A). Pre-treatment with Pio (30 µM for 6 h) increased subsequent 2-DG uptake by ~33% (from 151 ± 9 to 196 ± 3 fmol per min per mg of protein; p < 0.0001, two-way ANOVA). To characterize which glucose transporter(s) were involved in this increase, a similar experiment was performed in the presence of different amounts of cold D-glucose, and the amount of 2-DG taken up was measured after 45 min (Fig. 3B). The stimulatory effect of Pio was observed primarily at the higher doses of cold D-glucose (0.5-1 mM), suggesting an increased glucose flux through GLUT-1, which has a lower affinity for glucose than does GLUT-3 (53).


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Fig. 3.   Pio increases 2-deoxy glucose uptake. A, astrocytes were pre-incubated in DMEM with 5 mM glucose containing 0 or 30 µM Pio. After 6 h, cells were incubated in DMEM containing 0.5 mM D-glucose and 1 µCi/ml 2-DG (24 nM) for indicated times. Data are means ± S.E. of n = 3-6 replicates and are expressed as pmol of 2-DG per mg of protein. ***, p < 0.001 versus control (two-way ANOVA, Bonferroni multiple post hoc comparison). B, astrocytes were treated as in A, after which 2-DG uptake was measured in the presence of different concentrations of cold D-glucose. Data are means ± S.E. and are expressed as nmol of total glucose taken up per mg of protein. *, p < 0.05; ***, p < 0.001 versus control (two-way ANOVA, Bonferroni multiple post hoc comparison).

Effect of Pioglitazone on Glucose Transporter Expression-- The effects of Pio on astrocyte glucose utilization measured after 6 h were not significantly reduced by co-incubation with either a transcriptional (5 µg/ml actinomycin D) or translational (10 µg/ml cycloheximide) inhibitor (Fig. 4), suggesting that effects on gene transcription or protein translation were not involved in this process. Consistent with this, we found that Pio treatment (6 h with 30 µM) did not modify the steady state mRNA levels of either GLUT-1, which is mainly expressed in glial and endothelial cells, or GLUT-3, which is mainly expressed in neurons (Fig. 5, A and B). Similar results were obtained after longer incubation periods (up to 24 h) (data not shown) suggesting that increases in GLUT mRNA levels were not responsible for increased glucose uptake.


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Fig. 4.   Transcriptional and translational inhibitors do not prevent Pio effects. Cortical rat astrocytes were coincubated with a transcriptional (5 µg/ml actinomycin D) (Act D) or translational (10 µg/ml cycloheximide (CHX) inhibitors in the presence of DMEM containing 5 mM glucose and 0 or 30 µM Pio. Glucose utilization was assessed after 6 h as loss of glucose from the media. The data are means ± S.E. of n = 4 samples and are expressed as % loss of starting glucose levels. ***, p < 0.001 versus no Pio (one-way ANOVA followed by Newman-Keuls multiple comparison test).


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Fig. 5.   Effect of Pio on glucose transporter mRNA expression. Astrocytes were incubated in DMEM containing 5 mM glucose in the presence of 0 or 30 µM Pio. After 6 h, total cytosolic RNA was prepared and used for RT-PCR analysis of Glut-1, Glut-3, and glyceraldehyde-3-phosphate dehydrogenase (GDH) mRNA levels. A, representative agarose gel electrophoresis showing levels of GLUT-1 and GLUT-3 PCR products from control and Pio-treated samples (results for two different samples from each group, each done in duplicate, are shown). B, results of real-time PCR analysis showing the mean ± S.E. of the calculated cycle number take-off values (n = 4 replicates per group).

Analysis of GLUT-1 and GLUT-3 protein levels revealed that incubation with Pio for 6 h did not significantly increase either membrane or cytosolic levels of GLUT-1 (Fig. 6, left panels) although a slight increase (~20% increase in two experiments) in cytosolic levels was observed. However, after 24 h of incubation, we observed a significant increase (greater than 2-fold) in cytosolic levels and a slight increase (roughly 25%) in membrane levels of GLUT-1 in Pio-treated versus control astrocytes (Fig. 6, right panels). These results suggest that increased glucose utilization observed up to 6 h of incubation is not because of an increase in GLUT-1 levels but more likely because of an increase in glucose flux through pre-existing GLUT-1 protein.


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Fig. 6.   Effect of Pio on GLUT-1 expression. Astrocytes were incubated 6 (left panels) or 24 h (right panels) in complete media containing 0 or 30 µM Pio. Whole cell lysates were prepared and used to isolate membrane and cytoplasmic fractions, and equal aliquots were used for Western blot analysis of GLUT-1. In each panel, membrane and cytoplasmic samples from two different preparation are shown (C1 and P1). The bottom bar graphs show calculated band densities, and the error bars represent analytical error in the densitometric analysis for each sample. Note that film exposure times were 1 min for membrane samples and 5 or 10 min for cytoplasmic samples, and therefore the relative intensities cannot be compared directly.

Pioglitazone Increases Lactate Production-- Rat cortical astrocytes were incubated in DMEM containing 5 mM glucose, and lactate levels in the incubation media were measured after different times (Fig. 7). Treatment with Pio significantly increased lactate production (p < 0.0001, two-way ANOVA), suggesting that Pio influences glucose metabolism, as well as its uptake.


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Fig. 7.   Effect of Pio on lactate production. Astrocytes were incubated in 5 mM glucose in the presence of 0 or 30 µM Pio. Lactate levels were assessed at the indicated times. Data are means ± S.E. of n = 4 replicates, and there was a significant effect of Pio on lactate production (p < 0.001, two-way ANOVA). ***, p < 0.001 versus control (Bonferroni post hoc comparison).

TZD Effects Are Not Mediated by PPARgamma Activation-- Although Pio can bind to and activate PPARgamma , it can elicit PPARgamma -independent effects, as well. We therefore examined the effects of several different TZDs on astrocyte lactate production (Fig. 8). The order of efficacy for lactate production was found to be Trog > Pio > Rosi, which is the inverse order of their reported efficacies for activating the PPARgamma . Furthermore, co-incubation with GW347845, a high affinity, non-TZD PPARgamma agonist (7), failed to increase lactate production (Fig. 8A). Indeed, even at a concentration of 10 µM, at which dose Pio shows only a slight increase in glucose utilization, Trog significantly increased glucose utilization (Fig. 8B) whereas GW347485 had no effects. Together, these results suggest that the effects of Pio (and other TZDs) on astrocyte lactate and glucose metabolism could be mediated by a mechanism of action not involving PPARgamma activation, in contrast to their more well characterized anti-inflammatory actions (20, 58). In contrast, inflammatory activation of astrocytes by LPS, as assessed by expression of NOS2 and nitrite production (see Fig. 8C), was inhibited by TZDs in approximately the same order of potency as their ability to activate PPARgamma (GW347845 > Rosi > Pio > Trog).


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Fig. 8.   TZDs metabolic effects are not mediated by PPARgamma activation. A, astrocytes were incubated in presence of 10 µM of different PPARgamma agonists, and lactate production was measured at indicated times. Data are means ± S.E. of n = 4 replicates, ***, p < 0.001; **, p < 0.01; and *, p < 0.05 Pio-treated versus control, one-way ANOVA. B, at the end of the experiment, glucose levels were assessed in the incubation media. Data are expressed as % of glucose consumed and are analyzed by one-way ANOVA, followed by Dunnett's multiple comparison test. *, p < 0.05 versus control. GW, GW347845. C, astrocytes were incubated with 1 µg/ml of endotoxin LPS in the presence of indicated PPARgamma agonists (all at 10 µM) and nitrite levels after indicated times as a marker of NOS2 induction. Data are nmol of nitrite per well and are means ± S.E. of n = 4 replicates. Data are analyzed by two-way ANOVA.

TZD Effects Involve the cAMP/Protein Kinase A Signaling Pathway-- To begin to characterize possible mechanisms of action of Pio on astrocyte glucose metabolism, we tested inhibitors of several signaling pathways. The ability of Pio to increase lactate production was not modified by co-incubation with either an ATPase inhibitor (ouabain) or with a phosphatidylinositol 3-kinase inhibitor (wortmannin) (data not shown). However, incubation with a highly selective protein kinase A inhibitor (KT-5720; 100 nM) attenuated the effects of Pio (Fig. 9A). Consistent with this, we found that incubation with Trog significantly increased intracellular cAMP levels after 30 min. Treatment with Pio (10 µM) showed a tendency to increase cAMP levels at this time point, although the values were not significant (p = 0.07, unpaired t test) compared with vehicle (Fig. 9B).


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Fig. 9.   Pio affects glucose metabolism via the cAMP/protein kinase A pathway. A, the stimulatory effect of Pio (30 µM) on lactate was reversed by a selective protein kinase A inhibitor (KT-5720) used at 100 nM (Ki = 56 nM). Data were expressed as mg/100 ml of lactate and were analyzed by one-way ANOVA, followed by Newman-Keuls multiple comparison test. **, p < 0.01 versus control. B, astrocytes were incubated in low glucose DMEM for 30 min in the presence of 10 µM Pio or Trog, or vehicle alone, after which intracellular cAMP levels were determined. Trog (10 µM) increased cAMP levels (1.86 ± 0.5 versus 0.08 ± 0.02 pg of cAMP per ml of Trog and Me2SO, respectively, p < 0.05, unpaired t test); Pio (10 µM) induced a slight but non-significant increase (to 0.29 ± 0.08, p = 0.07, unpaired t test).

TZDs Influence Mitochondrial Function-- Because effects of TZDs on glucose metabolism and lactate production could be secondary consequences of effects on mitochondrial function, we tested whether TZDs directly modified mitochondrial respiration (Fig. 10). In freshly isolated rat brain mitochondria, incubation with Pio or Trog reduced the pyruvate-driven state III respiration, measured by loss of oxygen from the incubation media (Fig. 10A). The consequences of TZD inhibition of mitochondrial respiration was examined in whole astrocytes (Fig. 10B). Mitochondrial membrane potentials (Delta Psi ) were measured by using flow cytometry with the fluorescent day JC-1 (56). Incubation with TZDs significantly increased the ratio of aggregate to monomer JC-1 fluorescence in astrocytes (30% increase by Pio, 43% increase by Trog), indicating a hyperpolarization of mitochondria Delta Psi . The ability of an initial inhibition of respiration to cause subsequent mitochondrial hyperpolarization has been described previously (59, 60) and may involve intramitochondrial hydrolysis of anaerobically derived ATP (see "Discussion").


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Fig. 10.   TZDs modify mitochondrial function. A, freshly isolated rat brain mitochondria was incubated in the presence of the indicated concentrations of Pio or Trog or the appropriate amount of Me2SO vehicle. State III respiration was initiated by addition of pyruvate, and oxygen consumption was measured over the next 10 min. The data are means ± S.E. of three-four experiments. B, astrocytes were incubated for 6 h in 10 µM Pio or Trog, or vehicle only. At that time the mitochondrial membrane potential was determined by fluorescence measurement of JC-1 aggregation state. The data are means ± S.D. of n = 3 experiments. **, p < 0.05; ***, p < 0.01 versus vehicle, unpaired t test.

Pioglitazone Reduces Astrocyte Cell Death-- To test whether incubation with TZDs influenced cell viability, we tested the effects of Pio on astrocyte cell death because of glucose deprivation (Fig. 11). Astrocytes maintained for 24 h in either high (25 mM) or low (5 mM) glucose containing media showed some cell death (5 to 10%, assessed by lactate dehydrogenase release), which was not significantly reduced by co-incubation with Pio (30 µM). In contrast, overnight incubation in the absence of glucose increased lactate dehydrogenase release 4-fold over control values (to 18 ± 2%), and this was reduced to control values by Pio (p < 0.001, unpaired t test). These data suggest that the effects of TZDs on astrocytes can provide protection against hypoglycemia-induced injury.


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Fig. 11.   Pio reduces hypoglycemia-induced cell death. Astrocytes were incubated in DMEM containing 1% FCS and either 0, low (5 mM), or high (25 mM) glucose and in the presence or absence of Pio (30 µM). After 24 h, lactate dehydrogenase release and total lactate dehydrogenase levels were determined. Data are means ± S.E. of three-four measurements. ***, p < 0.001, unpaired t test.

TZD Effects on Glucose Metabolism in Vivo-- To establish whether TZDs could influence brain glucose metabolism in animals, we tested the effects of acute and of chronic TZD treatment on brain sections prepared from Pio-fed adult rats (Fig. 12). Incubation of cortical sections prepared from control rats with TZDs significantly increased glucose loss from the media, similar to what we observed in primary astrocyte cultures (data not shown). We then compared glucose utilization in sections prepared from rats that were provided oral Pio (100 ppm) for 1, 3, or 10 days. The glucose utilization in sections from 1 day Pio-fed rats was not significantly different from that of control rats. However, after 3 days of treatment, the glucose utilization was ~50% greater in sections prepared from Pio-fed animals than control animals. However, this potentiating effect of orally provided Pio was transient, because after a longer period (10 days) the sections from Pio-fed animals showed a similar glucose use as did control sections. Although we do not yet know the cellular source of glucose use in these sections, these results demonstrate that oral treatment with Pio can influence brain glucose metabolism.


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Fig. 12.   Pio increases glucose utilization in rat cortical slices. Cortical slices were prepared from adult rats kept on a diet containing Pio for 1, 3, or 10 days and further incubated in vitro. Glucose levels in the incubation media were measured after 4 h. Data are expressed as % of glucose utilization and are means ± S.E. of n = 4 replicates per group. The same experiment was carried out twice. Data are analyzed by unpaired t test. *, p < 0.05 versus control.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Our data demonstrate for the first time that PPARgamma agonists of the TZD family can modify glucose metabolism in brain glial cells, despite the fact that the regulation of glucose metabolism in brain is primarily insulin-independent. TZDs increased astrocyte glucose uptake from the media and lactate production and release from the cells. The mechanism underlying this increase in glucose metabolism is not yet clear; however, in contrast to other studies, our results do not support an effect of TZDs, at least at early time points, on glucose transporter expression but instead point to rapid events occurring at the mitochondrial level. Furthermore, our results suggest that the effects of TZDs on astrocyte metabolism are not mediated by PPARgamma activation, because the most effective TZD was troglitazone, which of the TZDs tested has the lowest efficacy of PPARgamma activation (7), and because the highly selective PPARgamma agonist GW347485 was ineffective. Together, our data suggest the existence of a novel rapid and non-genomic action of TZDs upon astroglial cell physiology, which may involve changes in intracellular cAMP. These findings raise the possibility that TZDs could be used therapeutically to increase astroglial energy stores, as well as their ability to provide lactate to neurons when needed.

It has been shown that astrocytes are the main source of energy for neuronal activity (43). Therefore, in this study we examined the effect of Pio on glucose metabolism using primary enriched cultures of rat cortical astrocytes. In this model Pio increased glucose utilization as assessed by loss of glucose from the culture media and glucose uptake as measured by influx of radiolabeled 2-DG. Because the delivery of glucose within the brain is mediated primarily by GLUT-1, present in the blood-brain barrier, as well as in glial cells, and to a smaller extent by GLUT-3 presents in neurons (42), we tested whether Pio modified GLUT-1 or GLUT-3 expression. Measurements of 2-deoxy-glucose uptake suggested an increased flux through GLUT-1, because significant increases due to Pio occurred at the higher but not the lower glucose concentrations tested (53). In other systems, the regulation of GLUT-1 expression is under both transcriptional and post-transcriptional control (61, 62). However, in our studies the increase in glucose utilization observed at 6 h was not reduced by co-treatment with cycloheximide or actinomycin D, and measurements of GLUT-1 and GLUT-3 mRNA levels did not reveal significant effects due to Pio treatment at either early (6 h) or later (24 h) time points, again suggesting that glucose-modifying effects are mediated by non-genomic mechanisms.

In insulin-sensitive cells, about 50% of the GLUT-1 and most of the GLUT-4 is located in intracellular vesicles, and both are translocated to the plasma membrane in response to insulin (63). Because TZDs can increase GLUT-4 translocation from the intracellular pool to the plasma membrane (51) we assessed whether Pio modified either the cytosolic or membrane content of GLUT-1. However, no significant differences were observed after 6 h of incubation, whereas a slight increase in both cytoplasmic and plasma membrane content of GLUT-1 was observed after 24 h of incubation. We conclude that the effects of Pio on glucose uptake at early time points (within 6 h) are not associated with significant changes in glucose transporter expression. However, at later times, an increase in GLUT-1 content could contribute to or account for the increased rate of metabolism within the cells.

Our data also suggest that the effects of TZDs on astrocyte metabolism are not mediated by PPARgamma activation but instead by rapid activation of an intracellular signaling system, possibly leading to modification of mitochondrial function. Measurements of lactate production show that the order of efficacy for increasing production was Trog > Pio > Rosi, inverse of their reported affinities for binding and activating PPARgamma . We also found that Trog (at 10 µM) was the only TZD able to increase glucose utilization and moreover that the high affinity PPARgamma agonist GW347845 had no effect on glucose metabolism. In contrast, in the same cells the TZDs reduced LPS-dependent nitrite production (presumably because of increased NOS2 expression) with efficacies similar to their ability to activate PPARgamma , indicating the presence of functional PPARgamma on these cells.

Several studies (64-66) have now shown that TZDs can trigger specific effects within a relatively short time range, consistent with the existence of transcription-independent mechanisms of action. Incubation with 15-deoxy-Delta -12,14-prostaglandin J2 (as well as Pio and Trog) induces a rapid and transient activation of the mitogen-activated protein kinase/extracellular signal-regulated kinase pathway in vascular smooth muscle cells by an activation of phosphatidylinositol 3-kinase (65) suggesting that some actions of TZDs might be mediated via this protein kinase. However, incubation of astrocytes with a phosphatidylinositol 3-kinase inhibitor (wortmannin) had no significant effect on the Pio-dependent increases in glucose uptake or lactate production. Because glucose uptake and the rate of glycolytic metabolism are increased by activation of Na+K+ ATPase in astrocytes (67) we also tested the effect of a Na+K+ ATPase inhibitor (ouabain). However, under the conditions used, ouabain did not reverse Pio effects.

In contrast, we found that inhibition of protein kinase A with the selective inhibitor KT-5720 (100 nM) significantly reversed the metabolic effects of Pio. Consistent with this, we also found that astrocyte cAMP levels were increased (albeit slightly) after 30 min of incubation with Pio and significantly increased upon incubation with Trog. To our knowledge these results are the first demonstration of an effect of TZDs on intracellular cAMP levels. The greater effect due to incubation with Trog is consistent with our findings that Trog more potently increased glucose utilization and lactate production than did Pio. However, further studies are needed to better characterize the effects of TZDs on the kinetics and magnitude of intracellular cAMP levels. There are numerous pathways linking changes in cAMP to effects on glucose metabolism. For example chronic treatment with cAMP analogues increased glucose utilization by up-regulating GLUT-1 expression in human choriocarcinoma cells (68), although opposite results were observed in primary mouse placental cells (69). In insulin-sensitive tissues, several studies have shown that glucose uptake was enhanced by regulation of GLUT-1 expression through the cAMP/protein kinase A pathway. However, in myoblasts these effects were observed only after 24 h (70) and only at the higher concentrations (within the mM range) of cAMP analogues (71). Similarly, cAMP increased glucose uptake in T3T-L1 adipocytes by increasing GLUT-1 protein content in the plasma membrane after 8 (72) or 16 h (73). Interestingly, in brown adipocytes norepinephrine enhanced glucose transport across the membrane by a mechanism involving cAMP and increased GLUT-1 affinity for its substrate (63). Taken together, these reports indicate that glucose uptake can be regulated by cAMP via several distinct mechanisms. Finally, and in light of the fact that TZDs directly inhibit mitochondrial respiration, reports demonstrating inhibition of the pyruvate dehydrogenase complex by cAMP-dependent phosphorylation of pyruvate dehydrogenase kinase (74, 75) suggest an additional mechanism to account for suppression of pyruvate-driven respiration.

It has been shown that the glutamate released upon neuronal activity is taken up by astrocytes, causes an increase in astroglial glycolysis, and subsequently increases the uptake of glucose from the incubation media and lactate release into the media, thereby coupling in this way neuronal activity with energy metabolism (43). We therefore hypothesized that increased glucose uptake because of Pio might also increase lactate production by astrocytes. We observed that Pio induced a rapid increase in lactate production that was evident as soon as after 2 h of treatment, suggesting that the effect of Pio is to increase glucose metabolism and subsequently cause uptake from extracellular pools. A similar effect has been demonstrated in rat muscle cells in which inhibition of insulin-stimulated mitochondrial fuel oxidation by Trog leads to an increase of anaerobic glycolysis and glucose transport (76).

Our current findings demonstrate that TZDs also directly inhibit the ability of acutely isolated brain mitochondria to catalyze pyruvate-driven state III respiration, consistent with previous findings that TZDs directly inhibit mitochondrial fatty acid metabolism (64, 76). Although inhibitory effects on mitochondrial respiration are difficult to reconcile with subsequent protective actions, it has been hypothesized previously (56, 60) that the increase in anaerobically derived ATP due to mitochondrial impairment by nitric oxide subsequently contributes to sustained mitochondrial membrane potential, and we observe a similar phenomenon after 6 h of incubation with TZDs. Furthermore, mitochondrial hyperpolarization has been shown to protect cells against cytotoxic damage, and in our experiments we find that treatment with Pio reduced astrocyte cell death due to hypoglycemia.

Based upon the above considerations, we propose the following scheme to explain the ability of TZDs to increase astroglial glucose metabolism. A similar scheme has been proposed for the ability of low doses of nitric oxide to inhibit initial oxidative respiration but that eventually lead to higher intracellular ATP levels and protective effects. We suggest that after entry into the cell, TZDs modulate (either directly or possibly by a mechanism involving cAMP) enzyme activities present within the mitochondrial membrane causing inhibition of ongoing pyruvate-driven respiration. Whether this is a selective effect on pyruvate oxidation (i.e. by inhibition of pyruvate dehydrogenase) or is a more general inhibition of mitochondrial substrate utilization is not yet known. Increased cytosolic pyruvate results in greater lactate production, observed as an increase in extracellular lactate levels. In astrocytes, this inhibitory effect on mitochondrial function is compensated by an increase in anaerobic glycolysis allowing for continued ATP production, as well as further pyruvate and lactate synthesis. Eventually, the reduced intracellular glucose levels are replenished by glucose transport through the GLUT-1 because of mass action through the transporter and without significant change in GLUT-1 levels (at least initially).

At later times, mitochondrial respiration recovers, because the actions of TZDs are neither toxic nor irreversible. Accumulated ATP can be translocated via the adenine nucleotide translocase into the mitochondria, where hydrolysis to ADP releases protons that contribute to maintenance and increase of the membrane potential. Because hyperpolarization of the mitochondrial membrane is postulated to be protective, for example by conferring resistance to depolarization and release of pro-apoptotic factors, the net result of TZD treatment, at least in astrocytes, is protective and allows cells to withstand subsequent noxious stimuli.

It has been shown recently, both in vitro and in vivo, that PPARgamma activation can exert anti-inflammatory effects (25), regulate myelin gene expression (33), and increase neurite extension (32) in brain cells. For these reasons, PPARgamma agonists, including TZDs like Pio and Rosi, are being considered as potential neuroprotective agents in neurodegenerative disorders, including Alzheimer's disease, Parkinson's disease, stroke, and multiple sclerosis. It is possible that increases in intracellular glucose could contribute to the anti-inflammatory effects by increasing expression of stress proteins, such as inhibitory Ikappa B proteins, which would reduce glial inflammation. However, because glucose metabolism is perturbed in the early stages of Alzheimer's disease (77-79) and in multiple sclerosis (80-82), the effects described herein suggest an additional mechanism, i.e. maintenance of brain energy supplies, by which TZD treatment could provide benefit.

    ACKNOWLEDGEMENTS

We thank Anthony Sharp and Patricia Murphy for excellent technical assistance with cell culture and animal procedures, Chanannait Paisansathan and Richard Ripper for help with mitochondrial preparations, and Dr. Jonathan Art for help with immunocytochemical staining of astrocyte cultures.

    FOOTNOTES

* This work was supported in part by grants from the National Multiple Sclerosis Society, Takeda Pharmaceuticals North America, and GlaxoSmithKline.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

To whom correspondence should be addressed: 1819 West Polk St., MC519, Rm. 540, Chicago, IL 60612. Tel.: 312-996-8377; Fax: 312-996-9680; E-mail: cdr@uic.edu.

Published, JBC Papers in Press, December 16, 2002, DOI 10.1074/jbc.M208132200

2 C. Dello Russo and D. L. Feinstein, unpublished observations.

    ABBREVIATIONS

The abbreviations used are: PPAR, peroxisome proliferator-activated receptor; 2-DG, 2-deoxy-glucose; DMEM, Dulbecco's modified Eagle's medium; FCS, fetal calf serum; GLUT, glucose transporter; LPS, lipopolysaccharide; NOS, nitric-oxide synthase; Pio, pioglitazone; Rosi, rosiglitazone; Trog, troglitazone; TZD, thiazolidinedione; RT, reverse transcriptase; ANOVA, analysis of variance.

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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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