Sue Ritter

Immunotoxic destruction of distinct catecholamine subgroups produces selective impairment of glucoregulatory responses and neuronal activation.

The toxin‐antibody complex anti‐dβh‐saporin (DSAP) selectively destroys dβh‐containing catecholamine neurons. To test the role of specific catecholamine neurons in glucoregulatory feeding and adrenal medullary secretion, we injected DSAP, unconjugated saporin (SAP), or saline bilaterally into the paraventricular nucleus of the hypothalamus (PVH) or spinal cord (T2–T4) and subsequently tested rats for 2‐deoxy‐D‐glucose (2DG)‐induced feeding and blood glucose responses. Injections of DSAP into the PVH abolished 2DG‐induced feeding, but not hyperglycemia. 2DG‐induced Fos expression was profoundly reduced or abolished in the PVH, but not in the adrenal medulla. The PVH DSAP injections caused a nearly complete loss of tyrosine hydroxylase immunoreactive (TH‐ir) neurons in the area of A1/C1 overlap and severe reduction of A2, C2, C3 (primarily the periventricular portion), and A6 cell groups. Spinal cord DSAP blocked 2DG‐induced hyperglycemia but not feeding. 2DG‐induced Fos‐ir was abolished in the adrenal medulla but not in the PVH. Spinal cord DSAP caused a nearly complete loss of TH‐ir in cell groups A5, A7, subcoeruleus, and retrofacial C1 and a partial destruction of C3 (primarily the ventral portion) and A6. Saline and SAP control injections did not cause deficits in 2DG‐induced feeding, hyperglycemia, or Fos expression and did not damage catecholamine neurons. DSAP eliminated dβh immunoreactivity but did not cause significant nonspecific damage at injection sites. The results demonstrate that hindbrain catecholamine neurons are essential components of the circuitry for glucoprivic control of feeding and adrenal medullary secretion and indicate that these responses are mediated by different subpopulations of catecholamine neurons. J. Comp. Neurol. 432:197–216, 2001.

Localization of hindbrain glucoreceptive sites controlling food intake and blood glucose.

Feeding and blood glucose responses to local injection of nanoliter volumes of 5-thio-D-glucose (5TG), a potent antimetabolic glucose analogue, were studied at 142 hindbrain and 61 hypothalamic cannula sites. A site was considered positive if 5TG elicited at least 1.5 g more food intake or a hyperglycemic response at least 25 mg/dl greater than the respective responses elicited by vehicle injection in the same rat. Of 61 hypothalamic cannula sites tested, none were positive for blood glucose and only one was positive for feeding. Increasing the 5TG dose to 48 ug did not produce additional positive results at hypothalamic sites. In contrast, 66 hindbrain sites were positive for feeding and 49 were positive for blood glucose, with 33 of these being positive for both responses. The distribution of positive sites for feeding and hyperglycemia overlapped almost completely. Positive sites were concentrated in two distinct zones: one in the ventrolateral and one in the dorsomedial medulla. In both locations, the glucoreceptive areas extended approximately from the level of the area postrema (AP) to the pontomedullary junction. Glucoreceptive zones were co-distributed with epinephrine cell groups C1-C3, suggesting that epinephrine neurons may be important components of the neural circuitry for glucoregulation. Localization of glucoreceptive sites will facilitate positive identification of glucoreceptor cells and the direct analysis of the neural mechanisms through which they influence food intake and metabolic responses.

Absence of lithium-induced taste aversion after area postrema lesion

Anatomical and physiological evidence indicates that the area postrema (AP) lacks a blood-brain barrier6, la and is thus permeable to blood-born substances which do not penetrate most other areas of the brain. The classical experiments of Borison (refs. 5, 7) demonstrated that the AP region contains chemoreceptors which stimulate vomiting in some species in response to certain drugs. This finding suggests that one function of the AP is to detect ingested toxins and trigger their expulsion from the gastrointestinal tract. In addition to producing vomiting, some toxic substances, which are encountered by animals in association with novel foods, may result in formation of learned responses known as conditioned taste aversions (CTAs)3A 1. These learned responses decrease the probability that animals will subsequently ingest particular foods which were previously associated with toxic effects. Berger et al. 4 were the first to demonstrate that the AP plays a critical role in the formation of CTA by some chemical substances. Taste aversions formed by scopolamine methyl nitrate (SMN), a neuroactive substance which does not cross the blood-brain barrier, were shown to be mediated by the AP. On the other hand, the CTA formed by D-amphetamine, a drug which readily penetrates the blood-brain barrier, does not require an intact AP. On the basis of these data, it appears that more than one mechanism may exist for the formation of CTAs. Moreover, these results provide evidence of an important role for the AP region in behavioral, as well as in gastrointestinal, functions. Lithium chloride (LiCI) is a compound which is widely used in CTA studles2,~2, t3. However, the mechanism by which LiCI induces CTAs ts not known. The

Subgroups of hindbrain catecholamine neurons are selectively activated by 2-deoxy-d-glucose induced metabolic challenge

Glucose is a major fuel for body energy metabolism and an essential metabolic fuel for the brain. Consequently, glucose deficit (glucoprivation) elicits a variety of physiological and behavioral responses crucial for survival. Previous work indicates an important role for brain catecholamine neurons in mediation of responses to glucoprivation. This experiment was conducted to identify the specific catecholamine neurons that are activated by glucoprivation. Activation of hindbrain catecholamine neurons by the antimetabolic glucose analogue, 2-deoxy-D-glucose (2DG; 50, 100, 200 or 400 mg/kg, s.c.) was evaluated using double label immunohistochemistry. Fos protein was used as the marker for neuronal activation and the enzymes tyrosine hydroxylase (TH) and phenethanolamine-N-methyl transferase (PNMT) were used as the markers for norepinephrine (NE) and epinephrine (E) neurons. 2-Deoxy-D-glucose (200 and 400 mg/kg) produced selective activation of distinct hindbrain catecholamine cell groups. In the ventrolateral medulla, doubly labeled neurons were concentrated in the area of A1/C1 and were predominantly adrenergic in phenotype. In the dorsal medulla, doubly labeled neurons were limited to C2 and C3 cell groups. In the pons, some A6 neurons were Fos-positive. Neurons in rostral C1, ventral C3, A2, A5 and A7 did not express Fos-ir in response to 2DG. Our results identify specific subpopulations of catecholamine neurons that are selectively activated by 2DG. Previously demonstrated connections of these subpopulations are consistent with their participation in the feeding and hyperglycemic response to glucoprivation. Finally, the predominant and seemingly preferential activation of epinephrine neurons suggests that they may play a unique role in the brains response to glucose deficit.

2-Mercaptoacetate and 2-deoxy-D-glucose induce Fos-like immunoreactivity in rat brain.

2-Deoxy-D-glucose (2-DG) and 2-mercaptoacetate (MA) are antimetabolic drugs that selectively antagonize glucose and fatty acid utilization, respectively, and stimulate feeding. Fos immunohistochemistry was employed to identify brain neurons activated by these drugs and to assess the role of the vagus nerve in the drug effects. Remote intravenous infusions of both MA and 2-DG induced Fos-like immunoreactivity (Fos-li) in specific brain sites, but the pattern was different for the two drugs. Mercaptoacetate induced Fos-li in the nucleus of the solitary tract (NTS), the central subnucleus of the lateral parabrachial nucleus (1PBN), the central nucleus of the amygdala (CNA, lateral part) and the dorsal motor nucleus of the vagus (DMV). Induction of Fos-li in the brain by MA was totally abolished by vagotomy. 2-Deoxy-D-glucose also induced Fos-li in the NTS, CNA (lateral part) and DMV, as well as in the external 1PBN subnucleus, locus coeruleus, paraventricular and supraoptic hypothalamic nuclei, and in scattered cells throughout the diencephalon. Induction of Fos-li by 2-DG was not blocked by vagotomy. Results suggest that 2-DGs effects on Fos-li are mediated by a direct central action, whereas MAs effects are mediated by peripheral sensory neurons. Thus, availability of glucose and fatty acids influences the activity of specific brain sites by different neural mechanisms. The correlation of Fos-immunoreactive sites with sites where lesions have been shown to cause deficits in MA- and 2-DG-induced feeding indicates that c-fos expression defines in part the central pathways involved in the metabolic control of feeding.(ABSTRACT TRUNCATED AT 250 WORDS)

Hindbrain catecholamine neurons control multiple glucoregulatory responses.

Reduced brain glucose availability evokes an integrated constellation of responses that protect and restore the brains glucose supply. These include increased food intake, adrenal medullary secretion, corticosterone secretion and suppression of estrous cycles. Our research has focused on mechanisms and neural circuitry underlying these systemic glucoregulatory responses. Using microinjection techniques, we found that localized glucoprivation of hindbrain but not hypothalamic sites, elicited key glucoregulatory responses, indicating that glucoreceptor cells controlling these responses are located in the hindbrain. Selective destruction of hindbrain catecholamine neurons using the retrogradely transported immunotoxin, anti-dopamine beta-hydroxylase conjugated to saporin (DSAP), revealed that spinally-projecting epinephrine (E) or norepinephrine (NE) neurons are required for the adrenal medullary response to glucoprivation, while E/NE neurons with hypothalamic projections are required for feeding, corticosterone and reproductive responses. We also found that E/NE neurons are required for both consummatory and appetitive phases of glucoprivic feeding, suggesting that multilevel collateral projections of these neurons coordinate various components of the behavioral response. Epinephrine or NE neurons co-expressing neuropeptide Y (NPY) may be the neuronal phenotype required for glucoprivic feeding: they increase NPY mRNA expression in response to glucoprivation and are nearly eliminated by DSAP injections that abolish glucoprivic feeding. In contrast, lesion of arcuate nucleus NPY neurons, using the toxin, NPY-saporin, does not impair glucoprivic feeding or hyperglycemic responses. Thus, hindbrain E/NE neurons orchestrate multiple concurrent glucoregulatory responses. Specific catecholamine phenotypes may mediate the individual components of the overall response. Glucoreceptive control of these neurons resides within the hindbrain.

Absence of glucoprivic feeding after stress suggests impairment of noradrenergic neuron function

Feeding in response to 2-deoxy-D-glucose (2DG), a quantifiable behavior which appears to depend on noradrenergic (NE) neuron function, was used in these experiments to evaluate the functional capabilities of NE neurons after stress exposure. Depletion of hypothalamic NE after footshock or hypothermic stress was directly correlated with impairment of glucoprivic feeding. When NE depletion was prevented by prior exposure to chronic stress, no impairment of feeding was observed. After hypothermic stress, repletion of NE proceeded more rapidly in the telencephalon than in the hypothalamus and reappearance of a normal feeding response precisely paralleled the time course of repletion in the hypothalamus. Drinking in response to cell dehydration, a behavior not directly dependent on brain catecholamines, was not impaired after either footshock or hypothermic stress, despite similar NE depletions. Presence of a normal drinking response assured that deficits observed in the 2DG test were not due to nonspecific behavioral suppression resulting from stress. These data suggest that NE neuron function may be impaired or temporarily abolished after severe stress exposure. In addition, these results demonstrate that behavioral pathology need not be the result of massive neurotransmitter depletion but may result from relatively subtle alterations of specific neurotransmitter pools.

Induction of Fos-like immunoreactivity (Fos-li) and stimulation of feeding by 2, 5-anhydro-d-mannitol (2, 5-AM) require the vagus nerve

The antimetabolic fructose analogue, 2,5-anhydro-D-mannitol (2,5-AM), stimulates feeding. Selective hepatic branch vagotomy has been shown to block feeding induced by low 2,5-AM doses. However, hepatic vagal fibers are not the sole mediators of 2,5-AM-induced feeding, since hepatic branch vagotomy does not impair feeding induced by higher doses of 2,5-AM. To further evaluate the role of the vagus in the response to 2,5-AM, we examined the effect of total subdiaphragmatic vagotomy on feeding induced by a high 2,5-AM dose (500 mg/kg). In addition, we assessed the ability of 2,5-AM (300 and 500 mg/kg) to induce Fos-like immunoreactivity (Fos-li) in the brain in sham-operated (SHAM), hepatic branch vagotomized (HBV) and total subdiaphragmatic vagotomized (TSDV) rats. Both doses of 2,5-AM, but not control solutions, induced Fos-li in the area postrema (AP), nucleus of the solitary tract (NTS) and lateral parabrachial nucleus (1PBN). Very weak immunoreactivity was present in the central nucleus of the amygdala and none was observed in the locus coeruleus or paraventricular nucleus of the hypothalamus. The effect of the lower 2,5-AM dose on Fos-li was blocked by HBV. The high dose effect was blocked by TSDV but not by HBV. Feeding induced by the high dose of 2,5-AM was also blocked by TSDV. Results are consistent with the hypothesis that stimulation of feeding by 2,5-AM is dependent on the vagus nerve. Hepatic branch fibers may have the lowest threshold for activation, but fibers in other vagal branches independently mediate induction of c-fos and stimulate food intake at higher doses of the analogue.

SYMPATHOADRENAL RESPONSES TO GLUCOPRIVATION AND LIPOPRIVATION IN RATS

The effects of glucoprivation and lipoprivation on sympathoadrenal outflow were investigated in rats with permanent intra-atrial catheters. Glucoprivation was induced by infusion of a hypoglycemic dose of insulin (3 U/kg) or by infusion of the glucose antimetabolite, 2-deoxy-D-glucose (2-DG, 200 mg/kg). Lipoprivation was induced by infusion of sodium mercaptoacetate (MA, 600 mumol/kg), which blocks beta oxidation of fatty acids. Stress-free blood samples for measurement of blood glucose, plasma nonesterified fatty acids (NEFA), and epinephrine (E) and norepinephrine (NE) concentrations were collected remotely before and after drug injection. Glucoprivation and lipoprivation differed significantly in their effects on the sympathoadrenal system. Both 2-DG- and insulin-induced glucoprivation appeared to increase adrenomedullary secretion selectively, leading to dramatically increased plasma E levels. Although plasma NE levels also rose during glucoprivation, other evidence suggests that this effect may be secondary to the rise in E. In contrast, MA-induced lipoprivation increased the outflow of NE from the sympathetic nerve endings without a significant effect on plasma E concentrations. Plasma E levels rose only late in the test, as blood glucose levels began to fall. Results indicate that glucoprivation and lipoprivation are distinct metabolic signals, each capable of selectively activating one branch of the sympathoadrenomedullary system and thereby facilitating the mobilization of metabolic fuels appropriate for the specific metabolic challenge.

Glucoprivation increases expression of neuropeptide Y mRNA in hindbrain neurons that innervate the hypothalamus

The hypothalamus is jointly innervated by hindbrain and hypothalamic neuropeptide Y (NPY) cell bodies. While the specific roles of these distinct sources of innervation are not known, NPY neurotransmission within the hypothalamus appears to contribute to glucoregulatory feeding. Here we examine the involvement of hindbrain NPY neurons in glucoregulation using in situ hybridization to assess their responsiveness to glucoprivation. The hindbrain NPY innervation of the hypothalamus is derived from cell bodies that coexpress norepinephrine or epinephrine. Therefore, we quantified NPY mRNA hybridization signal in hindbrain catecholamine cell groups 90 min after subcutaneous administration of the glycolytic inhibitor 2‐deoxy‐d‐glucose (2DG, 250 mg/kg) to male rats. Catecholamine cell groups A1, A1/C1 and C2 (that provide the major NPY innervation of the hypothalamus) showed a basal level of NPY mRNA hybridization signal that was dramatically increased by 2DG. In C1 and C3, where basal NPY mRNA expression was close to or below our detection threshold, the hybridization signal was also significantly increased by 2DG. In cell groups A2, A5, A6 and A7, neither basal nor 2DG‐stimulated NPY mRNA expression was detected. Hypothalamic microinjection of the retrogradely transported catecholamine immunotoxin saporin conjugated to anti‐dopamine‐β‐hydroxylase destroyed hindbrain catecholamine/NPY neurons and abolished basal and 2DG‐stimulated increases in NPY expression in hindbrain cell groups. The responsiveness of hindbrain NPY neurons to glucose deficit suggests that these neurons participate in glucoprivic feeding or other glucoregulatory responses.