急性低血糖应激对大鼠下丘脑orexin-A表达的影响

目的研究胰岛素诱导的急性低血糖应激对大鼠下丘脑增食欲素-A(orexin-A)的表达影响。方法通过皮下注射胰岛素建立急性低血糖大鼠模型。采用免疫组织化学染色方法观察大鼠下丘脑orexin-A和Fos双标情况,并采用ELISA方法对脑脊液中的orexin-A含量进行检测。结果禁食组、低血糖进食组和低血糖禁食组阳性神经元计数明显高于对照组(P0.05),但三组之间计数比较差异无统计学意义(P0.05);Orexin-A/Fos双标细胞率(双标细胞占orexin-A阳性细胞的百分率)在低血糖禁食组最高,与禁食组和低血糖进食组比较差异有统计学意义(P0.05)。ELISA检测结果显示,低血糖禁食组脑脊液中的orexin-A含量显著高于其它三组,差异有统计学意义(P0.05)。结论急性血糖的降低可以增强大鼠下丘脑中orexin-A的表达,而摄食行为可以抑制此调控效应。     

Orexin-A immunoreactive neurons in the rat hypothalamus do not contain neuronal nitric oxide synthase (nNOS)

The lateral hypothalamic area (LHA), a key site involved in the central control of feeding and energy homeostasis, contains populations of neurons that produce the orexin peptides or nitric oxide, two chemical factors that increase food intake. In this study, we used immunohistochemistry to investigate the possibility that rat LHA neurons co-express orexin-A and neuronal nitric oxide synthase (nNOS). The orexin-A and nNOS cell populations in the LHA showed extensive overlap without co-localization, and no evidence of direct anatomic contact was found. The finding that LHA neurons do not co-localize orexin-A and nNOS may suggest that the actions of the orexins and nitric oxide on food intake are mediated via independent mechanisms, however, nitric oxide is a diffusible molecule and could potentially affect the activity of orexin neurons via a non-synaptic mechanism.     

Centrally administered orexin-A activates corticotropin-releasing factor-containing neurons in the hypothalamic paraventricular nucleus and central amygdaloid nucleus of rats: possible involvement of central orexins on stress-activated central CRF neurons

We examined the effects of centrally administered orexin-A on corticotropin-releasing factor (CRF)-containing neurons in the hypothalamic paraventricular nucleus (PVN) and the central amygdaloid nucleus (CeA) of rats, using dual immunostaining for CRF and Fos. Ninety minutes after intracerebroventricular administration of orexin-A, approximately 96% and 45% of CRF-containing neurons expressed Fos-like immunoreactivity (LI) in the PVN and the CeA, respectively. We also examined the effects of immobilized stress and cold exposure on orexin-A-containing neurons in the rat hypothalamus using dual immunostaining for orexin-A and Fos. After immobilized stress for 20 min and cold exposure at 4 degrees C for 30 min, approximately 24% and 15% of orexin-A-containing neurons expressed Fos-LI, respectively. These results suggest that orexins in the central nervous system may be involved in the activation of central CRF neurons induced by stress.     

Acute and repeated restraint differentially activate orexigenic pathways in the rat hypothalamus

Stress and obesity are highly prevalent conditions, and the mechanisms through which stress affects food intake are complex. In the present study, stress-induced activation in neuropeptide systems controlling ingestive behavior was determined. Adult male rats were exposed to acute (30 min/d × 1 d) or repeated (30 min/d × 14 d) restraint stress, followed by transcardial perfusion 2 h after the termination of the stress exposure. Brain tissues were harvested, and 30 μm sections through the hypothalamus were immunohistochemically stained for Fos protein, which was then co-localized within neurons staining positively for the type 4 melanocortin receptor (MC4R), the glucagon-like peptide-1 receptor (GLP1R), or agouti-related peptide (AgRP). Cell counts were performed in the paraventricular (PVH), arcuate (ARC) and ventromedial (VMH) hypothalamic nuclei and in the lateral hypothalamic area (LHA). Fos was significantly increased in all regions except the VMH in acutely stressed rats, and habituated with repeated stress exposure, consistent with previous studies. In the ARC, repeated stress reduced MC4R cell activation while acute restraint decreased activation in GLP1R neurons. Both patterns of stress exposure reduced the number of AgRP-expressing cells that also expressed Fos in the ARC. Acute stress decreased Fos-GLP1R expression in the LHA, while repeated restraint increased the number of Fos-AgRP neurons in this region. The overall profile of orexigenic signaling in the brain is thus enhanced by acute and repeated restraint stress, with repeated stress leading to further increases in signaling, in a region-specific manner. Stress-induced modifications to feeding behavior appear to depend on both the duration of stress exposure and regional activation in the brain. These results suggest that food intake may be increased as a consequence of stress, and may play a role in obesity and other stress-associated metabolic disorders.     

DISTRIBUTION OF GAMMA-AMINOBUTYRIC ACID (GABA) IN THE RAT HYPOTHALAMUS: FUNCTIONAL CORRELATES OF GABA WITH ACTIVITIES OF APPETITE CONTROLLING MECHANISMS

—In the hypothalamus, the highest GABA content (approx. 26 nmol/mm³) was constantly observed in the lateral hypothalamic area (LHA). In other parts of the hypothalamus uneven distribution of GABA was also observed, but areas showing high concentration of GABA did not coincide with the locations of various hypothalamic nuclei. In the LHA, which is known to contain a feeding centre, the anterior part (6.4 and 6.0 mm anterior (A 6.4 and A 6.0) respectively to the vertical zero plane of de Groot) showed a remarkably high content of GABA. The GABA content in the LHA at A 6.4 was decreased during the initial phase of insulin hypoglycemia and, in contrast, showed a significant increase following hyperglycemia induced by alloxan administration. In the ventromedial nucleus (VMH) of the hypothalamus, which is known to contain a satiety centre, the GABA content was increased during the initial phase of insulin hypoglycemia. The results suggest that both certain parts of the LHA and VMH contain or receive GABA-inhibitory neurons and that these neurons may play important physiological roles in controlling functional states of the feeding and satiety centres in the hypothalamus.     

侧脑室微量注射大麻素受体拮抗剂对orexin-A诱导大鼠能量代谢改变的影响及潜在机制研究

目的:探讨大麻素1型受体(CB1)抑制剂利莫那班对下丘脑外侧区(LHA)微量注射orexin-A诱导的小鼠能量代谢及相关行为变化改变的影响。方法:通过侧脑室微量注射(icv)利莫那班,同时LHA微量注射orexin-A,测量小鼠能量代谢、自主运动的变化,杏仁核(CeA)内多巴胺释放能力以及小鼠摄食量的变化。结果:侧脑室微量注射利莫那班可减弱因LHA微量注射orexin-A引起的小鼠能量代谢变化,降低小鼠自主运动,并且减弱小鼠CeA内多巴胺释放能力。注射(icv)利莫那班未改变LHA微量注射orexin-A所诱导的摄食量增多。此外,LHA双侧注射利莫那班可阻断LHA内注射orexin-A对运动活性的促进作用,但不影响小鼠的摄食量。结论:大麻素受体涉及orexin-A诱导的小鼠中脑边缘系统多巴胺系统活化的调控,对能量代谢及自主运动也有影响,但对食物摄入的调节无明显影响。     

Leptin differentially regulates NPY and POMC neurons projecting to the lateral hypothalamic area.

Recent studies have reinforced the view that the lateral hypothalamic area (LHA) regulates food intake and body weight. We identified leptin-sensitive neurons in the arcuate nucleus of the hypothalamus (Arc) that innervate the LHA using retrograde tracing with leptin administration. We found that retrogradely labeled cells in the Arc contained neuropeptide Y (NPY) mRNA or proopiomelanocortin (POMC) mRNA. Following leptin administration, NPY cells in the Arc did not express Fos but expressed suppressor of cytokine signaling-3 (SOCS-3) mRNA. In contrast, leptin induced both Fos and SOCS-3 expression in POMC neurons, many of which also innervated the LHA. These findings suggest that leptin directly and differentially engages NPY and POMC neurons that project to the LHA, linking circulating leptin and neurons that regulate feeding behavior and body weight homeostasis.     

Unchanged hypothalamic neuropeptide Y concentrations in hyperphagic, hypoglycemic rats: evidence for specific metabolic regulation of hypothalamic NPY

Hypothalamic concentrations of neuropeptide Y (NPY), a potent central appetite stimulant, increase dramatically in food-restricted and insulin-deficient diabetic rats. This suggest that NPY may drive hyperphagia in these conditions, which are characterized by weight loss and insulin deficiency. To test the hypothesis that insulin deficiency and weight loss are specific stimuli to hypothalamic NPY, we measured NPY concentrations in individual hypothalamic regions in rats with hyperphagia caused by insulin-induced hypoglycemia. Groups of 8 male Wistar rats were injected with ultralente insulin (20-60 U/kg) to induce either acute hypoglycemia (7 h after a single injection) or chronic hypoglycemia (8 days with daily injections). In hypoglycemic rats, plasma insulin concentrations were increased 6- to 7-fold compared with saline-injected controls; food intake was significantly increased with acute and chronic hypoglycemia and weight gain was significantly increased in the chronically hypoglycemic group. NPY concentrations were measured by radioimmunoassay in 8 hypothalamic regions microdissected from fresh brain slices. NPY concentrations were not increased in any region in either acute or chronic hypoglycemia. NPY therefore seems unlikely to mediate hyperphagia in hyperinsulinemia-induced hypoglycemia, supporting the hypothesis that weight loss is a specific stimulus to hypothalamic NPY and that insulin deficiency may be the metabolic signal responsible.     

Neuronal activation of brain vagal-regulatory pathways and upper gut enteric plexuses by insulin hypoglycemia

Neuronal activation of brain vagal-regulatory nuclei and gastric/duodenal enteric plexuses in response to insulin (2 U/kg, 2 h) hypoglycemia was studied in rats. Insulin hypoglycemia significantly induced Fos expression in the paraventricular nucleus of the hypothalamus, locus coeruleus, dorsal motor nucleus of the vagus (DMN), and nucleus tractus solitarii (NTS), as well as in the gastric/duodenal myenteric/submucosal plexuses. A substantial number of insulin hypoglycemia-activated DMN and NTS neurons were choline acetyltransferase and tyrosine hydroxylase positive, respectively, whereas the activated enteric neurons included NADPH- and vasoactive intestinal peptide neurons. The numbers of Fos-positive cells in each above-named brain nucleus or in the gastric/duodenal myenteric plexus of insulin-treated rats were negatively correlated with serum glucose levels and significantly increased when glucose levels were lower than 80 mg/dl. Acute bilateral cervical vagotomy did not influence insulin hypoglycemia-induced Fos induction in the brain vagal-regulatory nuclei but completely and partially prevented this response in the gastric and duodenal enteric plexuses, respectively. These results revealed that brain-gut neurons regulating vagal outflow to the stomach/duodenum are sensitively responsive to insulin hypoglycemia.     

Peripheral ghrelin participates in the glucostatic signaling mediated by the ventromedial and lateral hypothalamus neurons

Employing immunohistochemistry techniques, we examined the c-fos expression in different hypothalamic areas, when plasma glucose levels were modified by the administration of insulin and 2-deoxyglucose (2-DG) respectively. Subsequently, the hypoglycemia produced by an injection of insulin significantly increased feeding concomitant to higher c-fos expression in the arcuate nucleus (ARC), paraventricular nucleus (PVN), dorsomedial hypothalamus (DMH) and lateral hypothalamus (LH), while no statistical changes in the ventromedial hypothalamus (VMH) were found. Also, the glucopenia induced by 2-DG administration produced similar stimulatory effects on appetite and the neuronal activity affecting all the hypothalamic areas studied, including the VMH. The peripheral blockade of the orexigenic hormone ghrelin with a specific antibody (AGA) significantly decreased food intake as induced from acute hypoglycemia and glucopenia. Curiously, the conjoint AGA and insulin or 2-DG administration produced a differential effect on the hypothalamic neurons analyzed, by increasing the number of c-fos positive neurons in the ARC, PVN and DMH, but not in the VMH and LH. This outcome suggests an interactive effect of the glucostatic pathways involving these two areas with the ghrelin signaling.     

Inactivation of the DMH selectively inhibits the ACTH and corticosterone responses to hypoglycemia

We have previously reported that repeated bouts of insulin-induced hypoglycemia (IIH) in the rat result in blunted activation of the paraventricular, arcuate, and dorsomedial hypothalamic (DMH) nuclei. Because DMH activation has been implicated in the sympathoadrenal and hypothalamic-pituitary-adrenal (HPA) responses to stressors, we hypothesized that its blunted activation may play a role in the impaired counterregulatory response that is also observed with repeated bouts of IIH. In the present study, we evaluated the role of normal DMH activation in the counterregulatory response to a single bout of IIH. Local infusion of lidocaine (n = 8) to inactivate the DMH during a 2-h bout of IIH resulted in a significant overall decrease of the ACTH response and a delay of onset of the corticosterone response compared with vehicle-infused controls (n = 9). We observed suppression of the ACTH response at time (t) = 90 and 120 min (50 +/- 12 and 63 +/- 6%, respectively, of control levels) and early suppression of the corticosterone response at t = 30 min (59 +/- 13% of the control level). The epinephrine, norepinephrine, and glucagon responses were not altered by DMH inactivation. Our finding suggests that DMH inactivation may play a specific role in decreasing the HPA axis response after repeated bouts of IIH.     

Hepatic Branch Vagus Nerve Plays a Critical Role in the Recovery of Post-Ischemic Glucose Intolerance and Mediates a Neuroprotective Effect by Hypothalamic Orexin-A

Orexin-A (a neuropeptide in the hypothalamus) plays an important role in many physiological functions, including the regulation of glucose metabolism. We have previously found that the development of post-ischemic glucose intolerance is one of the triggers of ischemic neuronal damage, which is suppressed by hypothalamic orexin-A. Other reports have shown that the communication system between brain and peripheral tissues through the autonomic nervous system (sympathetic, parasympathetic and vagus nerve) is important for maintaining glucose and energy metabolism. The aim of this study was to determine the involvement of the hepatic vagus nerve on hypothalamic orexin-A-mediated suppression of post-ischemic glucose intolerance development and ischemic neuronal damage. Male ddY mice were subjected to middle cerebral artery occlusion (MCAO) for 2 h. Intrahypothalamic orexin-A (5 pmol/mouse) administration significantly suppressed the development of post-ischemic glucose intolerance and neuronal damage on day 1 and 3, respectively after MCAO. MCAO-induced decrease of hepatic insulin receptors and increase of hepatic gluconeogenic enzymes on day 1 after was reversed to control levels by orexin-A. This effect was reversed by intramedullary administration of the orexin-1 receptor antagonist, SB334867, or hepatic vagotomy. In the medulla oblongata, orexin-A induced the co-localization of cholin acetyltransferase (cholinergic neuronal marker used for the vagus nerve) with orexin-1 receptor and c-Fos (activated neural cells marker). These results suggest that the hepatic branch vagus nerve projecting from the medulla oblongata plays an important role in the recovery of post-ischemic glucose intolerance and mediates a neuroprotective effect by hypothalamic orexin-A.     

Blood amino acids concentration during insulin induced hypoglycemia in rats: the role of alanine and glutamine in glucose recovery

Summary. Our purpose was to determine the blood amino acid concentration during insulin induced hypoglycemia (IIH) and examine if the administration of alanine or glutamine could help glycemia recovery in fasted rats. IIH was obtained by an intraperitoneal injection of regular insulin (1.0 U/kg). The blood levels of the majority of amino acids, including alanine and glutamine were decreased (P < 0.05) during IIH and this change correlates well with the duration than the intensity of hypoglycemia. On the other hand, the oral and intraperitoneal administration of alanine (100 mg/kg) or glutamine (100 mg/kg) accelerates glucose recovery. This effect was partly at least consequence of the increased capacity of the livers from IIH group to produce glucose from alanine and glutamine. It was concluded that the blood amino acids availability during IIH, particularly alanine and glutamine, play a pivotal role in recovery from hypoglycemia.     

Orexin-A通路对胃运动的调控研究

目的:探讨下丘脑外侧核(LHA)-伏隔核(NAcc)orexin-A神经和功能通路构成及该通路对胃运动的影响及潜在机制。方法:将健康成年雄性Wistar大鼠随机分为逆行追踪组和胃运动组:逆行追踪组大鼠采用逆行追踪技术结合免疫荧光组织化学染色法,观察下丘脑外侧核-伏隔核间是否存在orexin-A神经通路;胃运动组大鼠通过在体胃运动研究,观察伏隔核内微量注射不同浓度orexin-A对大鼠胃运动幅度和频率的影响,以及电刺激下丘脑外侧核后,大鼠胃运动的变化及机制。结果:荧光逆行追踪结合荧光免疫组织化学染色结果显示:下丘脑外侧核内有荧光金和orexin-A双重标记的神经元。胃运动研究结果显示:伏隔核内微量注射orexin-A,大鼠胃运动幅度和频率显著增加,并呈现显著剂量依赖关系(P0.05),伏隔核预先微量注射SB-334867,可反转该效应(P0.05)。电刺激下丘脑外侧核,大鼠胃运动幅度和频率显著增强(P0.05)。同样,伏隔核内微量注射SB-334867,再电刺激下丘脑外侧核,电刺激导致的胃运动增强效应显著减弱(P0.05)。结论:下丘脑外侧核-伏隔核存在orexin-A神经和功能通路,该通路可能通过orexin-A受体介导参与胃动力和能量代谢调控。     

地特胰岛素与NPH胰岛素治疗口服降糖药控制不佳的2型糖尿病临床比较研究

目的：观察口服降糖药控制不佳的2型糖尿病患者分别加用地特胰岛素和NPH胰岛素治疗24周的有效性和安全性。方法：63例口服降糖药物控制不佳（HbAlc〉7％）的2型糖尿病患者随机加用地特胰岛素或鱼精蛋白锌（NPH）胰岛素作为基础胰岛素,每日1次治疗24周,比较两组治疗前后糖化血红蛋白、体重、血脂的变化及低血糖的发生率。结果：两组的糖化血红蛋白、空腹血糖与基线比较均有显著下降,治疗后组间无差异。与NPH胰岛素组比较地特胰岛素组体重增加明显减少,差异有统计学意义。地特胰岛素组治疗期间全部低血糖次数较NPH胰岛素组减少54．69％（P〈0．01）。结论：地特胰岛素与NPH胰岛素相比,在有效控制血糖的同时可降低低血糖发生风险,而且有减少体重增加的优势。     

Effects of intracerebroventricular administration of the NPY-Y1 receptor antagonist, 1229U91, on hyperphagic and glycemic responses to acute and chronic intermediate insulin-induced hypoglycemia in female rats

Neuropeptide Y (NPY) Y1 receptors are implicated in CNS regulation of food intake, but their role in hypoglycemic hyperphagia remains unclear. The present studies utilized a pharmacological approach to investigate the hypothesis that NPY acts via Y1 receptor-dependent mechanisms to regulate feeding and blood glucose profiles during intermediate insulin-induced hypoglycemia. Groups of ovariectomized, estradiol benzoate-treated female rats were injected subcutaneously with one or four doses of neutral protamine Hagedorn insulin (NPH), on as many days, or with diluent alone. Before final treatments on day four, the animals were pretreated by intracerebroventricular (icv) delivery of the NPY Y1 receptor antagonist, 1229U91, or the vehicle, artificial cerebrospinal fluid (acsf). Food intake during acute hypoglycemia was significantly diminished between t_o and + 2 h in animals pretreated with the Y1 receptor antagonist versus vehicle. Administration of 1229U91 prior to the fourth of four NPH doses suppressed hypoglycemic hyperphagia over a relatively longer interval, e.g. 4 h, after t_o relative to the acute insulin group. Blood glucose levels after a single NPH injection were similar in acsf- and antagonist-pretreated rats at + 2, + 4, and + 6 h, but were lower at + 9 h in the latter group. Pretreatment with 1229U91 did not modify glucose profiles between + 2 and + 9 h after multiple dosing with NPH, but prevented recovery from hypoglycemia at + 12 h. The present results show that central NPY Y1 receptor antagonism inhibits hypoglycemic hyperphagia, and that this suppressive effect on feeding was of greater duration during recurring hypoglycemia. The data also show that Y1 receptor blockade decreases glycemic responses to both single and serial NPH dosing, albeit at different post-injection time points. The current studies support the view that NPY Y1 receptors function within central neural pathways that govern feeding and glycemic responses to intermediate-acting insulin, and that Y1 receptor-mediated stimulation of food intake may habituate in a positive manner to repetitive insulin-induced hypoglycemia. Further research is needed to evaluate the impact of chronic insulin-induced hypoglycemia on neuropeptide Y neurotransmission and Y1 receptor expression within regulatory circuitries that control food intake and glucostasis.     

Neurotensin Co-Expressed in Orexin-Producing Neurons in the Lateral Hypothalamus Plays an Important Role in Regulation of Sleep/Wakefulness States

Both orexin and neurotensin are expressed in the lateral hypothalamic area (LHA) and have been implicated in the regulation of feeding, motor activity and the reward system. A double label immunofluorescence and in situ hybridization studies showed that neurotensin colocalizes with orexin in neurons of the LHA. Pharmacological studies suggested that neurotensin excites orexin-producing neurons (orexin neurons) through activation of neurotensin receptor-2 (NTSR-2) and non-selective cation channels. In situ hybridization study showed that most orexin neurons express neurotensin receptor-2 mRNA but not neurotensin receptor-1 (Ntsr-1) mRNA. Immunohistochemical studies showed that neurotensin-immunoreactive fibers make appositions to orexin neurons. A neurotensin receptor antagonist decreased Fos expression in orexin neurons and wakefulness time in wild type mice when administered intraperitoneally. However, the antagonist did not evoke any effect on these parameters in orexin neuron-ablated mice. These observations suggest the importance of neurotensin in maintaining activity of orexin neurons. The evidence presented here expands our understanding of the regulatory mechanism of orexin neurons.     

Prior hypoglycemia enhances glucose responsiveness in some ventromedial hypothalamic glucosensing neurons

Antecedent insulin-induced hypoglycemia (IIH) reduces adrenomedullary responses (AMR) to subsequent bouts of hypoglycemia. The ventromedial hypothalamus [VMH: arcuate (ARC) + ventromedial nuclei] contains glucosensing neurons, which are thought to be mediators of these AMR. Since type 1 diabetes mellitus often begins in childhood, we used juvenile (4- to 5-wk-old) rats to demonstrate that a single bout of IIH (5 U/kg sc) reduced plasma glucose by 24% and peak epinephrine by 59% 1 day later. This dampened AMR was associated with 46% higher mRNA for VMH glucokinase, a key mediator of neuronal glucosensing. Compared with neurons from saline-injected rats, ventromedial nucleus glucose-excited neurons from insulin-injected rats demonstrated a leftward shift in their glucose responsiveness (EC50 = 0.45 and 0.10 mmol/l for saline and insulin, respectively, P = 0.05) and a 31% higher maximal activation by glucose (P = 0.05), although this maximum occurred at a higher glucose concentration (saline, 0.7 vs. insulin, 1.5 mmol/l). Although EC50 values did not differ, ARC glucose-excited neurons had 19% higher maximal activation, which occurred at a lower glucose concentration in insulin- than saline-injected rats (saline, 2.5 vs. insulin, 1.5 mmol/l). In addition, ARC glucose-inhibited neurons from insulin-injected rats were maximally inhibited at a fivefold lower glucose concentration (saline, 2.5 vs. insulin, 0.5 mmol/l), although this inhibition declined at >0.5 mmol/l glucose. These data suggest that the increased VMH glucokinase after IIH may contribute to the increased responsiveness of VMH glucosensing neurons to glucose and the associated blunting of the AMR.     

Hypoglycemia induced changes in cholinergic receptor expression in the cerebellum of diabetic rats

Glucose homeostasis in humans is an important factor for the functioning of nervous system. Hypoglycemia and hyperglycemia is found to be associated with central and peripheral nerve system dysfunction. Changes in acetylcholine receptors have been implicated in the pathophysiology of many major diseases of the central nervous system (CNS). In the present study we showed the effects of insulin induced hypoglycemia and streptozotocin induced diabetes on the cerebellar cholinergic receptors, GLUT3 and muscle cholinergic activity. Results showed enhanced binding parameters and gene expression of Muscarinic M1, M3 receptor subtypes in cerebellum of diabetic (D) and hypoglycemic group (D + IIH and C + IIH). α7nAchR gene expression showed a significant upregulation in diabetic group and showed further upregulated expression in both D + IIH and C + IIH group. AchE expression significantly upregulated in hypoglycemic and diabetic group. ChAT showed downregulation and GLUT3 expression showed a significant upregulation in D + IIH and C + IIH and diabetic group. AchE activity enhanced in the muscle of hypoglycemic and diabetic rats. Our studies demonstrated a functional disturbance in the neuronal glucose transporter GLUT3 in the cerebellum during insulin induced hypoglycemia in diabetic rats. Altered expression of muscarinic M1, M3 and α7nAchR and increased muscle AchE activity in hypoglycemic rats in cerebellum is suggested to cause cognitive and motor dysfunction. Hypoglycemia induced changes in ChAT and AchE gene expression is suggested to cause impaired acetycholine metabolism in the cerebellum. Cerebellar dysfunction is associated with seizure generation, motor deficits and memory impairment. The results shows that cerebellar cholinergic neurotransmission is impaired during hyperglycemia and hypoglycemia and the hypoglycemia is causing more prominent imbalance in cholinergic neurotransmission which is suggested to be a cause of cerebellar dysfunction associated with hypoglycemia.     

Lactate is a critical "sensed" variable in caudal hindbrain monitoring of CNS metabolic stasis

Caudal hindbrain "sensing" of glucoprivation activates central neural mechanisms that enhance systemic glucose availability, but the critical molecular variable(s) linked to detection of local metabolic insufficiency remains unclear. Central neurons and glia are metabolically coupled via intercellular trafficking of the glycolytic product lactate as a substrate for neuronal oxidative respiration. Using complementary in vivo models for experimental manipulation of lactate availability within the caudal hindbrain, we investigated the hypothesis that lactate insufficiency may be monitored by local metabolically "sensitive" neurons as an indicator of central nervous system energy imbalance. The data show that caudal fourth ventricular (CV4) administration of the monocarboxylate transporter inhibitor alpha-cyano-4-hydroxycinnamate (4CIN) resulted in dose-dependent increases in blood glucose in euglycemic animals, whereas the degree and duration of hypoglycemia elicited by insulin administration were exacerbated by exogenous L-lactate delivery to the CV4. Immunocytochemical processing of the hindbrain for the inducible c-fos gene product Fos revealed that 4CIN enhanced Fos immunoreactivity in the dorsal vagal complex (DVC), e.g., the nucleus of the solitary tract and dorsal vagal motor nucleus, and adjacent area postrema, sites where cells characterized by unique sensitivity to diminished glucose and/or glycolytic intermediate/end product levels reside, and in the medial vestibular nucleus (MV), and that CV4 L-lactate infusion increased Fos labeling within the DVC and MV after insulin-induced hypoglycemia. Together, these results support the view that lactate is a critical monitored metabolic variable in caudal hindbrain detection of energy imbalance resulting from glucoprivation and that diminished uptake and/or oxidative catabolism of this fuel activates neural mechanisms that increase systemic glucose availability.