Administration Of 2DG Research Articles

2-Deoxy-D-glucose administration after seizures has disease-modifying effects on kindling progression

2-deoxy-D-glucose (2DG) is a glucose analog and reversible inhibitor of glycolysis with anticonvulsant and antiepileptic effects in multiple seizure models. 2DG at a dose of 250 mg/kg intraperitoneally (IP) delays progression of repeated seizures evoked by kindling in rats when administered 30 min prior to twice daily kindling stimulation. As toxicological studies have demonstrated that repeated daily oral administration of 2DG at doses of 60–375 mg/kg/day in rats induces dose-dependent, reversible cardiac myocyte vacuolation, it was of interest to determine if 2DG also slowed kindling progression when administered at or below doses causing cardiac toxicity and at various time points after evoked seizures. We found that: (1) 2DG slowed kindling progression nearly 2-fold when administered at a dose of 37.5 mg/kg given IP 30 min prior to kindling stimulation, and (2) 2DG 37.5 mg/kg IP also slowed kindling progression when given immediately after, and for as long as 10 min after evoked (kindled) seizures. These observations suggest potential clinical usefulness of post-seizure administration of 2DG to reduce seizure clusters and long-term consequences of repeated seizures at human equivalent doses that are likely to be safe and well tolerated in patients.

COVID-19: Pathophysiology, Transmission, and Drug Development for Therapeutic Treatment and Vaccination Strategies.

COVID-19, a dreaded and highly contagious pandemic, is flagrantly known for its rapid prevalence across the world. Till date, none of the treatments are distinctly accessible for this life-threatening disease. Under the prevailing conditions of a medical emergency, one creative strategy for the identification of novel and potential antiviral agents gaining momentum in research institutions and progressively being leveraged by pharmaceutical companies is target-based drug repositioning/repurposing. Continuous monitoring and recording of results offer anticipation that this strategy may help to reveal new medications for viral infections. This review recapitulates the neoteric illation of COVID-19, its genomic dispensation, molecular evolution via phylogenetic assessment, drug targets, the most frequently worldwide used repurposed drugs and their therapeutic applications, and a recent update on vaccine management strategies. The available data from solidarity trials exposed that the treatment with several known drugs, viz. lopinavir-ritonavir, chloroquine, hydroxychloroquine, etc. had displayed various antagonistic effects along with no impactful result in the diminution of mortality rate. The drugs, like remdesivir, favipiravir, and ribavirin, have proved to be quite safer therapeutic options for treatment against COVID-19. Similarly, dexamethasone, convalescent plasma therapy and oral administration of 2DG are expected to reduce the mortality rate of COVID-19 patients.

Helicobacter pylori-mediated gastric pathogenesis is attenuated by treatment of 2-deoxyglucose and metformin.

Helicobacter pylori infection causes chronic inflammation in the stomach, which is linked to the development of gastric cancer. The anti-inflammatory and anticancer effects of a glycolysis inhibitor 2-deoxyglucose (2DG) and an antidiabetic medication metformin (Met) have gotten attention. Using a Mongolian gerbil animal model, we investigated H. pylori-mediated gastric pathogenesis and how this pathogenesis is influenced by 2DG and Met. Five-week-old male gerbils were infected with H. pylori strain 7.13. After 2 weeks of infection, gerbils were fed 2DG-containing food (0.03% w/w), Met-containing water (0.5% w/v), or both (Combi) for 2 (short-term) or 10 weeks (long-term). Gastric pathogenesis and host response to H. pylori infection were examined by macroscopic and histopathologic analysis of gerbils' stomach. As a result, indicators of gastric pathogenesis by H. pylori infection including infiltration of polymorphonuclear neutrophils and lymphocytes, intestinal metaplasia, atrophy, and proliferation of gastric epithelial cells were attenuated by short-term administration of 2DG, Met, or Combi. When the infection was sustained for long-term, gastric pathogenesis in drug-treated gerbils was equivalent to that in untreated gerbils, with the exception that the infiltration of neutrophil was reduced by 2DG. Colonization of H. pylori in stomach was unaffected by both short- and long-term treatments. Our findings demonstrate that the progression of gastric pathogenesis induced by H. pylori infection can be attenuated by the short-term individual or combinational treatment of 2DG and Met, implying that 2DG or Met could be considered as a treatment option for gastric diseases in the early stages of infection.

The absence of cellular glucose triggers oncogene AEG-1 that instigates VEGFC in HCC: A possible genetic root cause of angiogenesis

Background and ObjectiveAstrocyte Elevated Gene-1 (AEG-1) is the master and multi-regulator of the various transcriptional factor primarily regulating chemoresistance, angiogenesis, metastasis, and invasion under the pathological condition, including liver cancer. This study was focused on investigating the process of tumor angiogenesis in liver carcinoma by studying the role of AEG-1 under GD/2DG conditions. Method and resultsThe PCR and western blot analysis revealed that glucose depletion (GD) induces the overexpression of AEG-1. Further, it leads to the constant expression of VEGFC through the activation of HIF-1α/CCR7 via the stimulations of PI3K/Akt signaling pathways. GLUT2 is the major transporter of a glucose molecule that is highly participating under GD through the expression of AEG-1 and constantly expresses glucokinase (GCK). The obtained data suggest that AEG-1 act as an angiogenesis and glycolysis regulator by modulating the expression of GCK through HIF-1α and GLUT2. 2-deoxy-D-glucose (2DG) is a glycolysis inhibitor that induces impaired glycolysis and cellular apoptosis by cellular oxidative stress. The administration of 2DG has led to the chemoresistance of AEG-1. ConclusionThe total findings of the study judged that disruption of cellular energy metabolism induced by the absence of glucose or the presence of mutant glucose moiety (2DG) promotes the overexpression of AEG-1. The GD/2DG activates the VEGFC by inducing the HIF-1α and CCR7. Moreover, AEG-1 induces the expression of OPN, which regulates metastasis, angiogenesis, and actively participates in protective autophagy by promoting LC3 a/b.

Morphological Analysis of the Hindbrain Glucose Sensor-Hypothalamic Neural Pathway Activated by Hindbrain Glucoprivation.

Lowered glucose availability, sensed by the hindbrain, has been suggested to enhance gluconeogenesis and food intake as well as suppress reproductive function. In fact, our previous histological and in vitro studies suggest that hindbrain ependymal cells function as a glucose sensor. The present study aimed to clarify the hindbrain glucose sensor-hypothalamic neural pathway activated in response to hindbrain glucoprivation to mediate counterregulatory physiological responses. Administration of 2-deoxy-D-glucose (2DG), an inhibitor of glucose utilization, into the fourth ventricle (4V) of male rats for 0.5 hour induced messenger RNA (mRNA) expression of c-fos, a marker for cellular activation, in ependymal cells in the 4V, but not in the lateral ventricle, the third ventricle or the central canal without a significant change in blood glucose and testosterone levels. Administration of 2DG into the 4V for 1 hour significantly increased blood glucose levels, food intake, and decreased blood testosterone levels. Simultaneously, the expression of c-Fos protein was detected in the 4V ependymal cells; dopamine β-hydroxylase-immunoreactive cells in the C1, C2, and A6 regions; neuropeptide Y (NPY) mRNA-positive cells in the C2; corticotropin-releasing hormone (CRH) mRNA-positive cells in the hypothalamic paraventricular nucleus (PVN); and NPY mRNA-positive cells in the arcuate nucleus (ARC). Taken together, these results suggest that lowered glucose availability, sensed by 4V ependymal cells, activates hindbrain catecholaminergic and/or NPY neurons followed by CRH neurons in the PVN and NPY neurons in the ARC, thereby leading to counterregulatory responses, such as an enhancement of gluconeogenesis, increased food intake, and suppression of sex steroid secretion.

Glycolytic inhibitor 2-deoxyglucose suppresses inflammatory response in innate immune cells and experimental staphylococcal endophthalmitis

Previously, we have shown that Staphylococcus (S) aureus induces a glycolytic response in retinal residential (microglia) and infiltrated cells (neutrophils and macrophages) during endophthalmitis. In this study, we sought to investigate the physiological role of glycolysis in bacterial endophthalmitis using a glycolytic inhibitor, 2-deoxyglucose (2DG). Our data showed that 2DG treatment attenuated the inflammatory responses of mouse bone marrow-derived macrophages (BMDM) and neutrophils (BMDN) when challenged with either live or heat-killed S. aureus (HKSA). Among the inflammatory mediators, 2DG caused a significant reduction in levels of cytokines (TNF-α, IL-1β, IL-6) and chemokines (CXCL1 and CXCL2). Western blot analysis of 2DG treated cells showed downregulation of bacterial-induced MEK/ERK pathways. In vivo, intravitreal administration of 2DG both pre- and post-bacterial infection resulted in a significant reduction in intraocular inflammation in C57BL/6 mouse eyes and downregulation of ERK phosphorylation in retinal tissue. Collectively, our study demonstrates that 2DG attenuates inflammatory response in bacterial endophthalmitis and cultured innate immune cells via inhibition of ERK signaling. Thus glycolytic inhibitors in combination with antibiotics could mitigate inflammation-mediated tissue damage in ocular infections.

Radiosensitization of Prostate Cancer Cells by 2-Deoxyglucose

Prostate cancer is the most common malignancy of men. Treatment options include radiotherapy with or without hormonal manipulation and radical prostatectomy. However, there is no effective treatment for disseminated disease. A hallmark of malignancy is abnormal metabolism which also confers survival advantages and contributes to resistance to therapy. In response to exposure to ionizing radiation, metabolic pathways are activated which can protect the cell from irreversible injury. Tumor cell glycolytic activity is elevated and correlates with aggressiveness and radio resistance, indicating that targeting glucose metabolism may sensitize cancer cells to radiation. We have demonstrated that the clonogenic kill of PC3 cells induced by exposure to x-rays was enhanced by the glycolytic inhibitor 2-deoxyglucose (2DG). In contrast, treatment with 2DG failed to inhibit growth of multicellular spheroids derived from LNCaP cells. However, 2DG treatment, in the absence of irradiation, induced similar toxicity to PC3 and LNCaP cells cultured as monolayers. Radiation-induced cell cycle arrest was prevented by the simultaneous administration of 2DG in both cell lines, indicating a possible mechanism underlying sensitization. Therefore, we hypothesise that observed differences in cellular response to incubation with 2DG in the presence or absence of ionizing radiation resulted from variation in metabolic processes between tumor cell types. We conclude that inhibition of glucose metabolism by 2DG is an effective method for sensitizing prostate cancer cells to experimental radiotherapy and that this may occur by preventing DNA repair during radiation-induced cell cycle arrest.

Synergistic Anticancer Action of Lysosomal Membrane Permeabilization and Glycolysis Inhibition

We investigated the in vitro and in vivo anticancer effect of combining lysosomal membrane permeabilization (LMP)-inducing agent N-dodecylimidazole (NDI) with glycolytic inhibitor 2-deoxy-d-glucose (2DG). NDI-triggered LMP and 2DG-mediated glycolysis block synergized in inducing rapid ATP depletion, mitochondrial damage, and reactive oxygen species production, eventually leading to necrotic death of U251 glioma cells but not primary astrocytes. NDI/2DG-induced death of glioma cells was partly prevented by lysosomal cathepsin inhibitor E64 and antioxidant α-tocopherol, suggesting the involvement of LMP and oxidative stress in the observed cytotoxicity. LMP-inducing agent chloroquine also displayed a synergistic anticancer effect with 2DG, whereas glucose deprivation or glycolytic inhibitors iodoacetate and sodium fluoride synergistically cooperated with NDI, thus further indicating that the anticancer effect of NDI/2DG combination was indeed due to LMP and glycolysis block. The two agents synergistically induced ATP depletion, mitochondrial depolarization, oxidative stress, and necrotic death also in B16 mouse melanoma cells. Moreover, the combined oral administration of NDI and 2DG reduced in vivo melanoma growth in C57BL/6 mice by inducing necrotic death of tumor cells, without causing liver, spleen, or kidney toxicity. Based on these results, we propose that NDI-triggered LMP causes initial mitochondrial damage that is further increased by 2DG due to the lack of glycolytic ATP required to maintain mitochondrial health. This leads to a positive feedback cycle of mitochondrial dysfunction, ATP loss, and reactive oxygen species production, culminating in necrotic cell death. Therefore, the combination of LMP-inducing agents and glycolysis inhibitors seems worthy of further exploration as an anticancer strategy.

2-Deoxy-d-Glucose Ameliorates PKD Progression.

Autosomal dominant polycystic kidney disease (ADPKD) is an important cause of ESRD for which there exists no approved therapy in the United States. Defective glucose metabolism has been identified as a feature of ADPKD, and inhibition of glycolysis using glucose analogs ameliorates aggressive PKD in preclinical models. Here, we investigated the effects of chronic treatment with low doses of the glucose analog 2-deoxy-d-glucose (2DG) on ADPKD progression in orthologous and slowly progressive murine models created by inducible inactivation of the Pkd1 gene postnatally. As previously reported, early inactivation (postnatal days 11 and 12) of Pkd1 resulted in PKD developing within weeks, whereas late inactivation (postnatal days 25-28) resulted in PKD developing in months. Irrespective of the timing of Pkd1 gene inactivation, cystic kidneys showed enhanced uptake of (13)C-glucose and conversion to (13)C-lactate. Administration of 2DG restored normal renal levels of the phosphorylated forms of AMP-activated protein kinase and its target acetyl-CoA carboxylase. Furthermore, 2DG greatly retarded disease progression in both model systems, reducing the increase in total kidney volume and cystic index and markedly reducing CD45-positive cell infiltration. Notably, chronic administration of low doses (100 mg/kg 5 days per week) of 2DG did not result in any obvious sign of toxicity as assessed by analysis of brain and heart histology as well as behavioral tests. Our data provide proof of principle support for the use of 2DG as a therapeutic strategy in ADPKD.

Abstract POSTER-BIOL-1314: Investigating fatty acid beta-oxidation in ovarian cancer cells

Abstract Purpose: To investigate the contribution of fatty acid beta-oxidation to the total energy budget of ovarian cancer cells. Experimental procedures: Several ovarian cancer cells lines (OVKATE, OVSAHO, NIHOVCAR3) as well as a patient derived primary cell line (GD13-13P) were utilized for all experiments. The Seahorse Flux Analyzer in conjunction with several metabolic inhibitors including etomoxir (a carnitine palmitoyltransferase 1 inhibitor), 2-deoxy glucose, FCCP and rotenone were utilized in these experiments to evaluate the oxygen consumption rate(ORC) and extracellular acidification rate(ECAR) of cells at their basal and post metabolic inhibitor state. OCR and ECAR were used as markers for mitochondrial respiration and lactate production, respectively. NIHOVCAR3 cells were co-cultured with differentiated 3T3L1 adipocytes and then subjected to BODIPY fluorophore (493/503) fatty acid staining and confocal microscopy to investigate the potential relationship between ovarian cancer cells, adipocytes and metabolism. Summary of data: All ovarian cancer cell lines demonstrated a significant decrease in their OCR with the administration of etomoxir (OVSAHO 78%, OVKATE 71%, NIHOVCAR 75%, GD13-13P 66%, p<0.001). The simultaneously measured ECAR was significantly increased in most cell lines (OVSAHO 62%, OVKATE 142%, GD13-13P 82%, p<0.001) after administration of etomoxir, while unchanged in the NIHOVCAR3 cell line. Metabolic activity was further evaluated by determining the effect administration of 2-deoxy glucose (2DG) had on the basal OCR and ECAR of OVKATE and OVSAHO cells. The basal OCR of both cell lines was essentially unchanged with the administration of 2DG; however a significant decrease was seen with the subsequent administration of etomoxir. The co-culture of NIHOVCAR3 cells and differentiated adipocytes resulted in a marked increase in visualization of BODIPY staining of cytoplasmic free fatty acids compared to NIHOVCAR3 cells grown without co-culture (control). The addition of the fatty acid synthase inhibitor orlistat to the culture media resulted in a marked decrease in the cytoplasmic staining of the control cells; however NIHOVCAR3 cells grown in co-culture had persistent cytoplasmic BODIPY staining. Conclusions: These results suggest that ovarian cancer cell lines, as well as primary ovarian cancer cells, derive a significant portion of their energy from fatty acid beta oxidation, despite the presence of abundant glucose. Additionally, co-culture of ovarian cancer cells with adipocytes appears to provide ovarian cancer cells with exogenous free fatty acids donated by the adipocytes. These results help to further the concept that metastasis of ovarian cancer to fatty rich areas such as the omentum and mesentery may provide a metabolic advantage. Citation Format: Karyn J. Hansen, Bennett Van Houten. Investigating fatty acid beta-oxidation in ovarian cancer cells [abstract]. In: Proceedings of the 10th Biennial Ovarian Cancer Research Symposium; Sep 8-9, 2014; Seattle, WA. Philadelphia (PA): AACR; Clin Cancer Res 2015;21(16 Suppl):Abstract nr POSTER-BIOL-1314.

Abstract 2311: Targeting EMT and MET breast cancer stem cell states through simultaneous inhibition of glycolytic and antioxidant pathways

Abstract Cancer stem cells (CSCs) drive tumor growth as well as mediating metastasis and treatment resistance. In breast cancer (BC), CSCs exist in alternative mesenchymal (EMT) and epithelial (MET)-like states characterized by the expression of CD44+CD24- and aldehyde dehydrogenase (ALDH) respectively. BCSCs display phenotypic plasticity allowing them to transition between EMT and MET states in a process regulated by the tumor microenvironment. The plasticity of BCSCs suggests that it may be necessary to simultaneously target alternative BCSC states to achieve maximal eradication of these cell populations. In order to develop strategies to target these BCSC states, we measured the cellular bioenergetics of EMT and MET BCSCs compared to non-stem bulk tumor cells as well as the sensitivity of distinct BCSC states to inhibitors of glucose and hydroperoxide metabolism. Using a Seahorse XCF instrument, we found that both MET and EMT BCSCs display higher glycolytic potential than bulk tumor cells. Increased glycolysis correlated with elevated expression of hexokinase 2, a rate limiting glycolytic enzyme in cancer. Interestingly, the glycolytic inhibitor, 2-deoxyglucose (2DG), specifically inhibited EMT BCSCs in a dose dependent fashion; however, MET BCSCs were completely refractory to this treatment. Proteomic and RNA-seq analyses revealed that two important arms of hydroperoxide metabolism, the thioredoxin- and glutathione-mediated antioxidant pathways, were robustly up-regulated in MET BCSCs, suggesting that these cells are rendered resistant to glycolysis inhibition via an enhanced anti-oxidant defense. Pharmacologic inhibition of this antioxidant defense by Auranofin (an inhibitor of thioredoxin reductase) is sufficient to deplete MET BCSCs in SUM149 BC cells which were rescued by NAC, a ROS scavenger, or catalase, a specific enzyme capable of degrading intracellular H2O2. Finally, administration of 2DG together with Auranofin and BSO (an inhibitor of glutathione metabolism) synergistically suppressed tumor growth in a patient derived xenograft (PDX) model by suppressing both EMT and MET BCSCs. This study suggests that utilizing metabolic inhibition to simultaneously target EMT and MET BCSCs is a viable therapeutic strategy with important clinical implications. Citation Format: Ming Luo, April Davis, Sean McDermott, Evelyn Jiagge, Michael Brooks, Elizabeth Gheordunescu, Tahra Luther, Shawn G. Clouthier, Sarah Conley, Douglas R. Spitz, Max S. Wicha. Targeting EMT and MET breast cancer stem cell states through simultaneous inhibition of glycolytic and antioxidant pathways. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 2311. doi:10.1158/1538-7445.AM2015-2311

Magnetic Resonance Spectroscopy of Metabolic Changes in the Brains of Mice Given 2-Deoxy-D-Glucose and Lipopolysaccharide

Studies in ICR mice using proton magnetic resonance spectroscopy (1H MRS) addressed the metabolomic reaction of the hippocampus to deficiency of available energy induced by administration of 2-deoxy-Dglucose (2DG) and activation of the mechanisms of inflammation due to injection of bacterial lipopolysaccharide (LPS). Administration of 2DG increased the proportion of excitatory metabolites (glutamate and glutamine) and decreased the proportions of the inhibitory transmitter gamma-aminobutyric acid (GABA) and metabolites involved in neurogenesis (N-acetylaspartate (NAA) and choline compounds). Administration of LPS, conversely, increased the levels of GABA, NAA, and choline compounds. The differently directed effects of energy deficiency and proinflammatory stimuli explain the contradictory nature of 1H MRS results in patients with neurodegenerative pathologies, which in most cases are combined with mitochondrial dysfunction and inflammatory processes. The predominance of excitatory metabolites after administration of 2DG and inhibitory metabolites after administration of LPS are in good agreement with behavioral reactions seen in acute energy deficiencies, for example in hypoxia and illness behavior induced by proinflammatory factors.

Involvement of orexin-A neurons but not melanin-concentrating hormone neurons in the short-term regulation of food intake in rats

In order to elucidate the involvement of melanin-concentrating hormone (MCH) and orexin-A (ORX-A) neurons of the perifornical/lateral hypothalamic areas (PF/LH) in the regulation of food intake induced by acutely reduced glucose availability, we examined the food intake response and c-Fos expression in the MCH and ORX-A neurons in the PF/LH during 2-deoxy-D-glucose (2DG)-induced glucoprivation (400 mg/kg; i.v.) and systemic insulin-induced hypoglycemia (5 U/kg; s.c.) in male Wistar rats. The administration of both 2DG and insulin stimulated food intake and induced c-Fos expression in the ORX-A neurons corresponding to food intake, but not in the MCH neurons. These data indicate that ORX-A neurons, but not MCH neurons, play a role in the short-term regulation of food intake, and that the input signals for the neurons containing MCH and ORX-A are different, and these neurons play different roles in the regulation of feeding behavior.

Effect of 2-Deoxyglucose, a Glycolytic Inhibitor, on the ATP Levels and Viability of B Lymphocytes from Subjects with Chronic Lymphocytic Leukemia (CLL).

One hallmark of tumor cells is a high rate of glycolysis, which underlies the utility of the glucose analog, 2-[18]fluoro-2-deoxyglucose for PET imaging of solid tumors. The glucose analog, 2-deoxyglucose (2DG), inhibits glycolysis, and is predicted to decrease the viability of tumor cells, which are primarily dependent on the glycolytic pathway for ATP generation. We have recently shown that 2DG enhances the efficacy of either adriamycin or paclitaxel in delaying tumor growth in mouse xenograft cancer models (Maschek et al, Cancer Res 64 (2004): 31). We are currently conducting a phase 1 clinical trial to examine the safety of a combination administration of 2DG and Taxotere in patients with solid tumors. The goal of the current study is to measure the extent to which 2DG inhibits energy production and, consequently, reduces viability of leukemic cells. Heparinized blood was obtained from four subjects with a confirmed diagnosis of CLL (peripheral lymphocyte blood count ranged from 5,000–24,000/mm3), with an additional sample drawn from each subject two weeks later for replicate determinations. The mononuclear cell fraction (predominantly B cells) was isolated using Histopaque. Subsequent treatment of isolated CLL cells with 2DG (164 μg/ml) at 37°C (in the presence of 0.5 mM glucose) resulted in a 20–30% decrease in cellular ATP levels after 1 hr (compared with untreated cells) and a 60–70% decrease in ATP levels after 24 hrs. In the presence of 5 mM glucose, incubation of CLL cells with 2DG elicited a 5–10% decrease in ATP at 1 hr and 15–20% reduction in ATP levels at 24 hrs. The effect of 2DG on cell viability was assessed using Alamar Blue. Treatment of CLL cells with 2DG (164 μg/ml, in the presence of 0.5 mM glucose) resulted in a 50% loss in cell viability at 24 hrs (compared with untreated cells at the same time point), and a 70% loss at 48 hrs. In the presence of 5 mM glucose, the effect of 2DG was more modest. At 24 hrs, there was a 20% loss of cell viability and a 30–50% loss at 48 hrs. In conclusion, these results demonstrate that in vitro treatment of CLL B cells with 2DG decreases cellular ATP levels, ultimately resulting in a loss of cell viability. Updated results with samples from additional CLL subjects will be presented, together with an assessment of the therapeutic potential of 2DG for the treatment of CLL.

Inverse relationship between plasma epinephrine and testosterone levels during acute glucoprivation in healthy men

In healthy men, a decrease in plasma testosterone levels was observed in the context of metabolic stress. While physiological mechanisms underlying this response are unclear, there are several lines of evidence suggesting circulating epinephrine's influence on plasma testosterone levels. The purpose of this study was to directly relate stress-induced changes in plasma testosterone and epinephrine. The stressor used was blockade of glucose metabolism with pharmacological doses (40mg/kg) of 2 deoxyglucose (2DG). Arterial plasma samples from 10 healthy males were assayed at 20 minutes intervals for 60 minutes for the concentrations of testosterone, epinephrine and related biochemicals. Bolus administration of 2DG resulted in progressive decline in testosterone and increases in epinephrine and norepinephrine plasma levels (mean change from baseline: 29, 2530 and 186%, respectively). Inverse correlation was detected between both absolute (r s=−0.72; df=8; p=0.017) and baseline-corrected testosterone concentrations at the 60 minute time point and epinephrine area under the curve values. Our results suggest that adrenomedullary activation may be involved in stress-induced testosterone effects. The implications of these data for the understanding of the role of catecholamines in glucoprivic stress response are discussed.

Central, but not peripheral, glucose-sensing mechanisms mediate glucoprivic suppression of pulsatile luteinizing hormone secretion in the sheep.

Changes in glucose availability are proposed to modulate pulsatile GnRH secretion, and at least two anatomical sites, the liver and hindbrain, may serve as glucose sensors. The present study determined the relative importance of these putative glucose-sensing areas in regulating pulsatile LH secretion in the sheep. Our approach was to administer the antimetabolic glucose analog, 2-deoxy-D-glucose (2DG) into either the hepatic portal vein or the fourth ventricle in gonadectomized females in which LH pulse frequency was high. In the first study, a catheter was placed in the ileocolic vein to determine the effects of local injection of 2DG into the hepatic portal system on the release of LH. After monitoring the pattern of LH secretion for 4 h, 2DG (250 mg/kg) was infused (500 microl/min) into the liver for 2 h. For comparison, animals were also given the same dose of 2DG into a jugular vein for 2 h. Administration of 2DG into either the hepatic portal or jugular vein reduced LH pulse frequency to the same extent. Infusion of the lower dose (50 mg/kg) locally into the hepatic portal vein did not affect plasma LH profiles. Collectively, these results are interpreted to indicate that the liver does not contain special glucose-sensing mechanisms for the glucoprivic suppression of LH pulses. In the second study, 2DG (5 mg/kg) was infused (50 l/min) for 30 min into the fourth ventricle or lateral ventricle. During the subsequent 4-h sampling period, pulsatile LH secretion was significantly suppressed, but there was no significant difference in LH pulse frequency between sites of infusion. Peripheral 2DG concentrations were not detectable after either fourth or lateral ventricle infusions, indicating that the 2DG had acted centrally to suppress LH pulses. Plasma cortisol concentrations increased more in animals infused with 2DG into the fourth ventricle than in those infused into the lateral ventricle, suggesting that 2DG infused into lateral ventricle is transported caudally into the fourth ventricle and acts within the area surrounding the fourth ventricle. Overall, these findings suggest that an important glucose-sensing mechanism is located circumventricularly in the fourth ventricle. Moreover, the liver does not appear to play an important role in detecting glucoprivic action of 2DG to suppress pulsatile LH secretion.

Central, But Not Peripheral, Glucose-Sensing Mechanisms Mediate Glucoprivic Suppression of Pulsatile Luteinizing Hormone Secretion in the Sheep

Changes in glucose availability are proposed to modulate pulsatile GnRH secretion, and at least two anatomical sites, the liver and hindbrain, may serve as glucose sensors. The present study determined the relative importance of these putative glucose-sensing areas in regulating pulsatile LH secretion in the sheep. Our approach was to administer the antimetabolic glucose analog, 2-deoxy-d-glucose (2DG) into either the hepatic portal vein or the fourth ventricle in gonadectomized females in which LH pulse frequency was high. In the first study, a catheter was placed in the ileocolic vein to determine the effects of local injection of 2DG into the hepatic portal system on the release of LH. After monitoring the pattern of LH secretion for 4 h, 2DG (250 mg/kg) was infused (500 μl/min) into the liver for 2 h. For comparison, animals were also given the same dose of 2DG into a jugular vein for 2 h. Administration of 2DG into either the hepatic portal or jugular vein reduced LH pulse frequency to the same extent. Infusion of the lower dose (50 mg/kg) locally into the hepatic portal vein did not affect plasma LH profiles. Collectively, these results are interpreted to indicate that the liver does not contain special glucose-sensing mechanisms for the glucoprivic suppression of LH pulses. In the second study, 2DG (5 mg/kg) was infused (50 μl/min) for 30 min into the fourth ventricle or lateral ventricle. During the subsequent 4-h sampling period, pulsatile LH secretion was significantly suppressed, but there was no significant difference in LH pulse frequency between sites of infusion. Peripheral 2DG concentrations were not detectable after either fourth or lateral ventricle infusions, indicating that the 2DG had acted centrally to suppress LH pulses. Plasma cortisol concentrations increased more in animals infused with 2DG into the fourth ventricle than in those infused into the lateral ventricle, suggesting that 2DG infused into lateral ventricle is transported caudally into the fourth ventricle and acts within the area surrounding the fourth ventricle. Overall, these findings suggest that an important glucose-sensing mechanism is located circumventricularly in the fourth ventricle. Moreover, the liver does not appear to play an important role in detecting glucoprivic action of 2DG to suppress pulsatile LH secretion.

In Vivo 2-Deoxyglucose Administration Preserves Glucose and Glutamate Transport and Mitochondrial Function in Cortical Synaptic Terminals after Exposure to Amyloid β-Peptide and Iron: Evidence for a Stress Response

Mild metabolic stress can increase resistance of neurons in the brain to subsequent more severe insults, as exemplified by the beneficial effects of heat shock and ischemic preconditioning. Studies of Alzheimer's disease and other age-related neurodegenerative disorders indicate that dysfunction and degeneration of synapses occur early in the cell death process, and that oxidative stress and mitochondrial dysfunction are central events in this pathological process. It was recently shown that administration of 2-deoxy-d-glucose (2DG), a nonmetabolizable glucose analog that induces metabolic stress, to rats and mice can increase resistance of neurons in the brain to excitotoxic, ischemic, and oxidative injury. We now report that administration of 2DG to adult rats (daily i.p. injections of 100 mg/kg body weight) increases resistance of synaptic terminals to dysfunction and degeneration induced by amyloid β-peptide and ferrous iron, an oxidative insult. The magnitude of impairment of glucose and glutamate transport induced by amyloid β-peptide and iron was significantly reduced in cortical synaptosomes from 2DG-treated rats compared to saline-treated control rats. Mitochondrial dysfunction, as indicated by increased levels of reactive oxygen species and decreased transmembrane potential, was significantly attenuated after exposure to amyloid β-peptide and iron in synaptosomes from 2DG-treated rats. Levels of the stress proteins HSP-70 and GRP-78 were increased in synaptosomes from 2DG-treated rats, suggesting a mechanism whereby 2DG protects synaptic terminals. We conclude that 2DG bolsters cytoprotective mechanisms within synaptic terminals, suggesting novel preventative and therapeutic approaches for neurodegenerative disorders.

Effects of Acute Metabolic Stress on Striatal Dopamine Release in Healthy Volunteers

Several lines of evidence indicate that a variety of metabolic stressors, including acute glucose deprivation are associated with dopamine release. Pharmacologic doses of the glucose analogue, 2-deoxyglucose (2DG) cause acute glucoprivation and are associated with enhanced dopamine turnover in preclinical studies. In this study, we utilized [11C]raclopride PET to examine 2DG-induced striatal dopamine release in healthy volunteers. Six healthy volunteers underwent PET scans involving assessment of 2DG-induced (40 mg/kg) decrements in striatal binding of the D2/D3 receptor radioligand [11C]raclopride. Decreases in [11C]raclopride specific binding reflect 2DG-induced changes in synaptic dopamine. Specific binding significantly decreased following 2DG administration, reflecting enhanced synaptic dopamine concentrations (p = .02). The administration of 2DG is associated with significant striatal dopamine release in healthy volunteers. Implications of these data for investigations of the role of stress in psychiatric disorders are discussed.

Oxytocin and vasopressin neurones in principal and accessory hypothalamic magnocellular structures express Fos-immunoreactivity in response to acute glucose deprivation.

Neurohypophyseal secretion of oxytocin and vasopressin is elevated in response to decreased systemic glucose availability. In these studies, dual-label immunocytochemistry was used to identify hypothalamic neuropeptidergic magnocellular neurones that are transcriptionally activated in response to glucose substrate imbalance. Two h after i.p. injection of the glucose antimetabolite, 2-deoxy-D-glucose (2DG), or the vehicle, saline, groups of adult male rats were anaesthetized by i.p. injection with sodium pentobarbital and killed by transcardial perfusion. Sections (25 microm) through anterior and tuberal levels of the hypothalamus were processed for nuclear Fos- and cytoplasmic neuropeptide immunoreactivity (-ir). A high proportion of oxytocin-ir neurones in the supraoptic, paraventricular, and adjunct structures, including the anterior commissural, periventricular magnocellular, posterior perifornical, recurrent supraoptic, medial forebrain, and circular nuclei, were colabelled for nuclear Fos-ir following administration of 2DG. Large numbers of vasopressin neurones in the supraoptic, circular, posterior perifornical, and medial forebrain nuclei, and posterior magnocellular division and posterior subnucleus of the paraventricular nucleus were also immunostained for Fos in rats injected with the antimetabolite. These results show that decreased glucose metabolism is a stimulus for activation of the Fos stimulus-transcription cascade within oxytocin-and vasopressin-immunopositive neurones in several hypothalamic loci, findings that reflect activation of the Fos-stimulus transcription cascade within large proportions of these cell populations during this metabolic challenge. These data suggest that both peripheral hormonal and central modulatory functions of these neuropeptidergic neurones may be influenced by cellular glucose availability.