Feeding and body temperature in the rat: diencephalic localization of changes produced by excess calcium ions

Calcium: taste, intake, and appetite

This review summarizes research on sensory and behavioral aspects of calcium homeostasis. These are fragmented fields, with essentially independent lines of research involving gustatory electrophysiology in amphibians, ethological studies in wild birds, nutritional studies in poultry, and experimental behavioral studies focused primarily on characterizing the specificity of the appetite in rats. Recently, investigators have begun to examine potential physiological mechanisms underlying calcium intake and appetite. These include changes in the taste perception of calcium, signals related to blood calcium concentrations, and actions of the primary hormones of calcium homeostasis: parathyroid hormone, calcitonin, and 1,25-dihydroxyvitamin D. Other influences on calcium intake include reproductive and adrenal hormones and learning. The possibility that a calcium appetite exists in humans is discussed. The broad range of observations documenting the existence of a behavioral limb of calcium homeostasis provides a strong foundation for future genetic and physiological analyses of this behavior.

Neuropeptide Y perfused in the preoptic area of rats shifts extracellular efflux of dopamine, norepinephrine, and serotonin during hypothermia and feeding

This study examined the localized action of neuropeptide Y (NPY) on monoamine transmitter activity in the hypothalamus of the unrestrained rat as this peptide induced hypothermia, spontaneous feeding or both responses simultaneously. A guide tube was implanted in the anterior hypothalamic pre-optic area (AH/POA) of Sprague-Dawley rats. Then either control CSF vehicle or NPY in a dose of either 100 ng/microliter or 250 ng/microliter was perfused by push-pull cannulae in this structure in the fully sated, normothermic rat. Successive perfusions were carried out at a rate of 20 microliters/min for 6.0 min with an interval of 6.0 min elapsing between each. Samples of perfusate were assayed by HPLC for their levels of dopamine (DA), norepinephrine (NE), serotonin (5-HT) and their respective metabolites. Whereas control CSF was without effect on body temperature (Tb) or feeding, repeated perfusions of NPY over 3.0 hr caused dose-dependent eating from 4 to 39 g of food, hypothermia of 0.9 to 2.3 degrees C or both responses concurrently. As the rats consumed 11-39 g of food, the efflux of NE, MHPG, DOPAC and 5-HT was enhanced significantly, whereas during the fall in Tb the efflux of NE, DOPAC and 5-HIAA from the AH/POA increased. When the Tb of the rat declined simultaneously with eating behavior, the levels in perfusate of DOPAC and HVA increased significantly while MHPG declined. During perfusion of the AH/POA with NPY the turnover of NE declined while DA and 5-HT turnover increased during hypothermia alone or when accompanied by feeding. These results demonstrate that the sustained elevation in NPY within the AH/POA causes a selective alteration in the activity of the neurotransmitters implicated in thermoregulation, satiety and hunger. These findings suggest that both DA and NE comprise intermediary factors facilitating the action of NPY on neurons involved in thermoregulatory and ingestive processes. The local activity of NPY on hypothalamic neurons apparently shifts the functional balance of serotonergic and catecholaminergic neurons now thought to play a primary role in the control of energy metabolism and caloric intake.

Low doses of neurotensin in the preoptic area produce hyperthermia. Comparison with other brain sites and with neurotensin-induced analgesia

High amounts of neurotensin (NT) are found in the preoptic area of the hypothalamus, an area known to be involved in the regulation of body temperature. It is generally believed that NT is a peptide that produces hypothermia, and several sites in the brain have been proposed to mediate NT-induced hypothermia, including the preoptic area. However, the doses of NT used in these experiments were always very high (microgram order) whereas, according to Goedert, the total brain content of NT in the rat does not exceed 10 ng. We therefore reinvestigated the effects of microinjections of NT in the brain, using high (5 micrograms) and low (50 and 5 ng) doses, into the preoptic area and other brain sites (cerebral ventricles, posterior hypothalamus, and nucleus accumbens), and we also studied, as a comparison, the effects of high and low doses of NT on pain sensitivity in the same sites. The results show that the preoptic area has unique properties in the regulation of body temperature: low doses of NT in the preoptic area produce a hyperthermic response, whereas high doses produce hypothermia. In comparison, NT produces hypothermia in the posterior hypothalamus whatever the dose, and NT has analgesic effects in the preoptic area only at high doses. Besides, NT has no thermic effect, but does have an analgesic effect, in the nucleus accumbens. The selectivity of the actions of high doses of NT, as well as the mechanism of action of NT (possibly an endogenous neuroleptic), are discussed.

Norepinephrine, dopamine, and 5-HT release from perfused hypothalamus of the rat during feeding induced by neuropeptide Y

In the unrestrained rat, the hyperphagic-like ingestion of food evoked by the sustained elevation of neuropeptide-Y (NPY) in the hypothalamus was correlated with the release and turnover of monoaminergic transmitters in this structure. A single guide tube was implanted stereotaxically in the perifornical region of the hypothalamus for localized push-pull perfusion of an artificial CSF vehicle or NPY1-36 in a concentration of 10, 50, or 100 ng/1.0 microliters. After the rat was fully satiated, a site reactive to NPY was perfused repeatedly at a rate of 20 microliters/min for 6.0 min with an interval of 6.0-12 min elapsing between each perfusion. Samples of perfusate were analyzed by HPLC with coulometric detection for DA, HVA, DOPAC, NE, MHPG, 5-HT, and 5-HIAA. Although control perfusions were without effect on feeding or monoamine activity, NPY evoked mean cumulative intakes of food of 14 +/- 2.4, 25.6 +/- 3.0 and 26.5 +/- 3.2 g in response to 10, 50, or 100 ng/microliter concentrations of NPY, respectively, over the 4.0-5.0 hr test interval. HPLC analyses showed that during feeding the release of both NE and DA was enhanced significantly. The turnover of both catecholamines likewise increased significantly as reflected by the elevated levels of MHPG, DOPAC and HVA. However, neither the basal efflux of 5-HT nor its turnover, as reflected by the output of 5-HIAA, was affected during feeding induced by NPY perfused in the hypothalamus. These results suggest that a sustained elevation of NPY in the hypothalamus causes a perturbation in the basal activity of NE and DA which are both implicated in the neuronal mechanism regulating normal eating behavior. Thus, these catecholamine neurotransmitters are envisaged to comprise an intermediary step in the functional role played by NPY in the hypothalamus in integrating the control of energy metabolism and caloric intake.

Behavioral effects of diltiazem injected into the paraventricular nucleus of the hypothalamus

The calcium channel inhibitor diltiazem is widely used as a medication for cardiovascular diseases. Some side effects have been reported after its administration, including changes in activity (apathy or hyperactivity) and feeding behavior (anorexia). Previous experiments have found that local administration of various peptides into the paraventricular nucleus of the hypothalamus can have profound effects on these two behaviors. In the present study, effects of local infusions of diltiazem into the paraventricular nucleus on locomotor activity and food intake have been tested. A marked hyperactivity, greater than the hyperactivity caused by intraperitoneal injection of amphetamine was produced. Feeding behavior was not affected one hour after the infusions but intraventricular diltiazem infusions decreased feeding behavior. It is concluded that the paraventricular nucleus of the hypothalamus has an important role in the regulation of locomotor activity and that diltiazem can act at this level to produce behavioral changes.

Rostral hypothalamus: a new neuroanatomical site of neurochemically-induced emesis in the cat

The localized effect of noradrenergic agonists administered directly in the anterior hypothalamic preoptic area (AH/POA) in inducing emesis in the cat was investigated. Of the noradrenergic agonists tested, which included norepinephrine, clonidine, phenylephrine and methoxamine, only clonidine in doses of 5.0-50.0 micrograms was found to evoke emesis consistently when micro-injected in a volume of 1.0 microliter into AH/POA of the unrestrained cat. The emetic response to clonidine was short-lasting, generally dose-dependent in terms of latency and frequency, and occurred in bouts of one to three episodes. The sequence of the vomiting response, beginning with licking and retching, functionally resembled a normal pattern of an emetic response. The clonidine-induced emesis was not antagonized by the following antagonists micro-injected in AH/POA just prior to clonidine: alpha-adrenergic blocking agents, yohimbine, RX 781094 and phentolamine; the antimuscarinic drug, atropine; the serotonin antagonist, methysergide; the opioid antagonist, naloxone; and the dopamine antagonist, chlorpromazine. Therefore, it would appear that clonidine-induced emesis is not mediated by alpha noradrenergic, serotonergic, dopaminergic, muscarinic and opiate receptor systems within the AH/POA of the cat. Finally, the obtained results show that apart from the area postrema and a circumscribed zone of the brain-stem reticular formation, the hypothalamus is now implicated as a neuroanatomical site in the central nervous system mechanism underlying neurochemically-induced emesis.

Changes in body temperature after administration of acetylcholine, histamine, morphine, prostaglandins and related agents: II

This survey continues a second series of compilations of data regarding changes in body temperature induced by drugs and related agents. The information listed includes the species used, the route of administration and dose of drug, the environmental temperature at which experiments were performed, the number of tests, the direction and magnitude of change in body temperature and remarks on the presence of special conditions, such as age or brain lesions. Also indicated is the influence of other drugs, such as antagonists, on the response to the primary agent. Most of the papers were published since 1979, but data from many earlier papers are also tabulated.

Central actions of calcitonin on body temperature and intestinal motility in rats: evidence for different mediations

The effects of intracerebroventricular (i.c.v.) administration of calcitonin and PGE2 on intestinal motility and body temperature were examined in conscious rats chronically fitted with intraparietal electrodes in the small intestine, a cannula in a cerebral lateral ventricle and a subcutaneous thermistor probe. Both calcitonin and PGE2 restored the fasted pattern of intestinal motility in fed rats and induced an increase in body temperature. Indomethacin, an inhibitor of the cyclooxygenase with calcium antagonistic properties, and TMB-8, an intracellular calcium antagonist, blocked the effects of calcitonin on intestinal motility and body temperature. Piroxicam, an inhibitor of the cyclooxygenase which does not affect calcium uptake blocked the thermic but not the intestinal effects of calcitonin. TMB-8 but not indomethacin or piroxicam partially blocked the effects of PGE2 on both intestinal motility and body temperature. It is concluded that the central hyperthermic effect of calcitonin is mediated through the formation and the release of prostaglandins whereas the central action of calcitonin on digestive motility results from intracerebral effects on calcium fluxes.

Changes in Ca2+ ion activity within unrestrained rat's hippocampus perfused with alcohol or acetaldehyde

In the freely moving rat, the kinetics of Ca2+ ion activity were determined at circumscribed sites in the hippocampus, which was perfused with ethanol, tertiary-butyl alcohol or acetaldehyde. Initially, a region in CA1 or other cell field of the dorsal hippocampus was prelabelled by microinjection of 45Ca2+ through a permanently implanted guide tube. Then the tip of a concentric push-pull cannula assembly was lowered through the guide tube to the labelled site, and an isotonic artificial cerebrospinal fluid was repeatedly perfused at a rate of 25 microliter/min. Each perfusion was timed for 5.0 min with a 5.0 min interval between each. Once the washout curve of 45Ca2+ activity had begun to approach its asymptote, ordinarily in the midpoint of a series of perfusions, an isotonic solution of ethanol (188-942 mM), tertiary-butyl alcohol (12-580 mM) or acetaldehyde (10-98 mM) was added to the fourth perfusate. Thereafter, the hippocampal site was again perfused with the normal cerebrospinal fluid for the remainder of the experiment. Although the lowest concentration of ethanol exerted no effect on 45Ca2+ ion activity, an intermediate concentration caused mixed effects in either enhancing or suppressing the efflux into the perfusate of this cation. The highest concentration of ethanol produced in most experiments an initial suppression in Ca2+ ion efflux which was followed frequently by an elevation in the release of 45Ca2+. Similar changes in Ca2+ ion activity were produced by tertiary-butyl alcohol, but the magnitude of its effect was generally less than that of ethanol, suggesting that its effect on brain tissue differs from that of ethanol. Acetaldehyde evoked an intense and concentration-dependent enhancement of Ca2+ ion efflux from the perfused tissue at all of the sites in the hippocampus examined. These results suggest that in the unrestrained rat ethanol could unbind Ca2+ ions from hippocampal membranes or retard their uptake into cells of the hippocampus. The dual excitatory and inhibitory effect of ethanol on Ca2+ ion activity corresponds to the electrophysiological effects of this alcohol and could alter neurotransmitter release from neurons in this subcortical structure. The mechanism of action of acetaldehyde is envisaged to be due to its affinity to membrane sulfhydryl groups which alters protein conformation and thus interferes with both Ca2+ channels and Ca2+ binding properties.

Calmodulin-induced feeding in the satiated cat: evidence for involvement of calcium and norepinephrine in the brain

The central effect of the Ca++ binding protein, calmodulin (CaM) on spontaneous feeding as well as on core temperature was examined in the satiated cat in which chronically indwelling cannulae were permanently implanted for intracerebroventricular (ICV) infusion. When CaM was injected ICV in doses of 2.5-10.0 micrograms, the intake of food was significantly enhanced in the satiated cat without any notable change in the animal's core temperature. Ca++ ions infused similarly in a solution of 6.25-25.0 mM also augmented the spontaneous ingestion of food, which was accompanied by a concentration-related decline in core temperature. When infused separately, neither CaM in a low dose (1.25 micrograms) nor Ca++ ions (3.0 mM) given ICV altered the intake of food of the satiated cat. However, the simultaneous infusion of CaM and Ca in these concentrations enhanced significantly the amount of food consumed by as much as 60 g. When the same concentration of Ca++ ions was infused ICV simultaneously with 5.0 micrograms troponin C, a Ca++ binding protein of an identical molecular weight, the intake of food was unaltered. Further, the spontaneous feeding induced by CaM could be attenuated either by the central chelation of Ca++ ions by 1.0-1.5 mM EGTA or by 30 micrograms calcineurin, a specific CaM inhibitor, when either was given ICV. Pre-treatment of the cat with ICV phentolamine (50 micrograms) also reduced the CaM-induced feeding response significantly, whereas the similar pre-treatment with ICV propranolol (50 micrograms) or naloxone (100 micrograms) failed to affect CaM-induced feeding behavior.(ABSTRACT TRUNCATED AT 250 WORDS)

Calmodulin infused intracerebroventricularly enhances food intake in the cat

In the fasted cat, calmodulin (CaM) infused into the cerebral ventricle produces an increase in the normal intake of food in a dose-dependent manner. The enhancement of feeding by CaM seems to be functionally specific since the response was: (1) abolished by the simultaneous intraventricular infusion of calcineurin, a specific CaM antagonist; (2) not mimicked by another calcium binding protein, troponin C; and (3) independent of the CaM's lack of effect on body temperature and water intake. This finding opens up the dual possibility that this Ca2+ binding protein may affect receptors other than intracellularly and that CaM is involved in specific functions controlled by the brain.

Is alcohol induced poikilothermia mediated by 5-HT and catecholamine receptors or by ionic set-point mechanism in the brain?

In adult male Sprague-Dawley rats, stainless steel guide cannulae were implanted stereotaxically in either the lateral or third cerebral ventricle. Postoperatively, each animal was maintained at an ambient temperature of 22 degrees C. Just prior to the intragastric gavage of 4.0 g/kg ethyl alcohol (20% solution) individual animals were fitted with a colonic thermistor probe. Then, control CSF, a monoaminergic receptor antagonist, or a Ca++ ion chelating agent, EGTA, was infused into either the lateral or third ventricle (ICV) in a volume of 10.0 microliter. Phentolamine (20.0 micrograms), butaclamol (10.0 micrograms), or methysergide (20.0 micrograms) injected ICV all failed to prevent the thermolytic action of alcohol. The fall of 1.5 to 2.0 degrees C in the rat's colonic temperature, ordinarily caused by alcohol, was the same as that without the antagonists and lasted 3.0 to 4.0 hrs. EGTA infused into the rat's lateral cerebral ventricle also did not interfere with alcohol's poikilothermic action. However, EGTA infused into the third cerebral ventricle completely blocked alcohol's effect in lowering the body temperature of the rat. These results suggest that: (1) alcohol's profound effects on body temperature are not mediated by 5-HT, norepinephrine or dopamine pathways which are thought to underlie the mechanisms in the hypothalamus for thermoregulation; and (2) the temperature set-point mechanism, controlled by the ratio of diencephalic Na+ to Ca++ ions, is incapacitated by alcohol. Restoration of the ratio in the diencephalon by the direct, local chelation of Ca++ ions that eliminates alcohol's deleterious effects on body temperature.

Radiation and brain calcium: a review and critique

Serious controversy pervades the scientific study of radio-frequency (RF) radiation and its biological effects. The issues range broadly from international differences in safe exposure standards to questions pertaining to the neurological symptoms purportedly induced by electromagnetic radiation. In a more specialized vein, there is great concern in the discipline about the influence of different sources of radiation on the activity of calcium in the brain. A principal and very realistic reason for this concern stems from the pivotal importance of calcium ions in the normal functioning of the brain in all of its myriad complexity. The purpose of the review is to critically evaluate from an unbiased and "non-involved" viewpoint the major findings on the possible interaction between calcium ions and various radiation sources. Background information is also considered as it relates even indirectly to hypothetical mechanisms that might be used to explain any possible shift in Ca++ ion kinetics. Finally, an inclusive critique is presented which deals with the bench-top methods and strategy used in the conduct of calcium-radiation experiments.

Changes in body temperature after administration of antipyretics, LSD, delta 9-THC, CNS depressants and stimulants, hormones, inorganic ions, gases, 2,4-DNP and miscellaneous agents

This survey concludes a series of complications of data from the literature, primarily published since 1965, on thermoregulatory effects of antipyretics in afebrile as well as in febrile subjects, LSD and other hallucinogens, cannabinoids, general CNS depressants, CNS stimulants including xanthines, hormones, inorganic ions, gases and fumes, 2,4-dinitrophenol and miscellaneous agents including capsaicin, cardiac glycosides, chemotherapeutic agents, cinchona alkaloids, cyclic nucleotides, cycloheximide, 2-deoxy-D-glucose, dimethylsulfoxide, insecticides, local anesthetics, poly I:poly C, spermidine and spermine, sugars, toxins and transport inhibitors. The information listed includes the species used, route of administration and dose of drug, the environmental temperature at which the experiments were performed, the number of tests, the direction and magnitude of body temperature change and remarks on the presence of special conditions such as age or lesions, or on the influence of other drugs, such as antagonists, on the response to the primary agents.

Alterations in body temperature elicited by intrahypothalamic administration of tetrodotoxin, ouabain and A23187 ionophore in the conscious cat

Ouabain, tetrodotoxin, and calcium selective ionophore (A23187) were administered bilaterally into the hypothalamus of the unrestrained, fully conscious cat, while body temperature and other indicators of thermoregulatory responses were monitored continuously. Posterior hypothalamic microinjection of 2.0 to 10.0 ng or tissue perfusion with 1.1 X 10(-7) to 1.1 X 10(-8) M ouabain elicited dose dependent increases in body temperature accompanied by pinnae vasoconstriction, shivering and postural changes consistent with heat conservation. Tetrodotoxin, microinjected in doses of 0.5 and 5.0 ng or tissue perfusions with 7.8 X 10(-9) to 7.8 X 10(-7) M in the posterior hypothalamus elicited dose dependent falls in body temperature. However, tetrodotoxin microinjected into the anterior hypothalamic region elicited only increases in temperature. The calcium selective ionophore, A23187, at least at the concentrations used in this study, did not appear to produce any consistent effects on thermoregulation. These data support the hypothesis that the ionic milieu of the posterior hypothalamic region is essential in the maintenance of body temperature. Further, they suggest that increasing the [Ca++]/[Na+] acts in a manner similar to a depression in the firing frequency of a distinct population of cells, which may in turn determine in some way the "set-point" for body temperature. There is no evidence to support the concept that increasing the [Ca++]/[Na+] causes an increased release of the synaptic contents of the region.

Calcitonin: inhibitory effect on eating in rats

Subcutaneous and intracerebral injections of calcitonin inhibited feeding in rats. The anorectic activity of calcitonin was destroyed by exposing the hormone to heat, trypsin, or hydrogen peroxide. Calcitonin did not produce a conditioned taste aversion to saccharin, and maximum inhibition of feeding occurred 4.5 to 8.3 hours after subcutaneous administration. It is concluded that calcitonin inhibits feeding by acting directly on the central nervous system.

Cerebral ventricular infusion of excess calcium in the rat: effects on sleep states, behavior and cortical EEG

Sleep and behavior of the rat were recorded during cerebroventricular infusion of artificial cerebrospinal fluid (aCSF) containing regular or excess concentrations of calcium. Three different types of aCSF were used for control infusions. Depending on the ionic composition, paradoxical sleep (PS) was reduced by 6--52% during a 1-h aCSF infusion period, whereas the total amount of sleep was not altered. The depression of PS by aCSF could be prevented by increasing the concentration of Ca in the infusate by a factor of 2--5 (2.6--9.1 mM). Infusions of high concentrations of Ca (9.1--54.6 mM) caused feeding and wet-dog shakes. A slow-wave cortical EEG pattern prevailed during feeding elicited by either infusion of excess Ca or systemic administration of a small dose of pentobarbital. It is concluded (a) that the ionic composition of the CSF may selectively influence the occurrence of a sleep state, and (b) that Ca-induced feeding may be related to a covert sedative action of this cation.

Influence of EGTA on an exercise-induced elevation in the colonic temperature of the rat

The purpose of this study was to determine if an exercise-induced rise in body temperature could be affected by the chelation of Ca++ in the extracellular fluid surrounding the hypothalamus of the rat. Following the implantation of a guide tube above the hypothalamus, each animal was familiarized with exercising on a motor-driven treadmill. In random order, on separate days, a solution containing 3.6 mM EGTA, 26 mM Ca++ or an artificial cerebrospinal fluid (ACSF) solution was perfused through the guide tube while the animal was running. Colonic (Tc) and tail-skin (Tt) temperatures were monitored continuously. The perfusion of EGTA produced a significant increase in Tc when compared with the perfusion of the ACSF solution. The perfusion of excess Ca++ produced a significant decrease in Tc. These results suggest that Ca++ may play an important role in the mediation of heat dissipation during exercise.

Identification by microinjection of TRH-sensitive sites in the cat's brain stem that mediate respiratory, temperature and other autonomic changes

Cats were prepared with an array of stereotaxically implanted guide tubes, the tips of which rested just above selected structures in the brain stem. Thyrotropin-releasing hormone (TRH) was microinjected in a volume of 0.5 micronl at 347 individual sites scattered throughout the hypothalamus and mesencephalon Polypnea, hypothermia, vocalization, salivation, defecation and vasodilation were evoked by 10-20 ng of TRH injected only at loci in the mesencephalon, principally in the reticular substance. TRH failed to lower body temperature when it was infused at the same sites in the anterior hypothalamus at which norepinephrine produced its characteristic hypothermia. These results suggest that the TRH-induced hypothermia is a secondary effect of tachypnea which results from the action of the tripeptide on the mesencephalic respiratory-autonomic mechanism.

Brain calcium in the rabbit: site of action for the alteration of body temperature

Body temperature was recorded in the unanesthetized rabbit during push-pull perfusion of regions of the hypothalamus. Both the anterior and posterior hypothalamus were perfused with physiological solutions containing Ca++ in a concentration 2.0 or 5.0 times that of extracellular fluid. The animals were placed in an ambient temperature of 4.0 +/- 2.0degrees C for at least 1 hr before the perfusion and all experiments were carried out at this temperature. In the posterior hypothalamic area Ca++ produced a sharp fall in body temperature but did not cause body temperature to alter when it was perfused through the anterior hypothalamic area. These results indicate that the rabbit is similar to the cat and monkey since the effect of Ca++ on body temperature is localized to the posterior hypothalamic region.

Hypothalamic Na+ and Ca++ ions and temperature set-point: new mechanisms of action of a central or peripheral thermal challenge and intrahypothalamic 5-HT, NE, PGEi and pyrogen

The effects of changes in ambient and central temperature, amines, PGEu and pyrogen were investigated with respect to the mechanism of Na+-Ca++ ratio in the posterior hypothalamus of the unrestrained cat. Guide tubes were implanted bilaterally above the posterior hypothalamic area of 23 cats so as to accommodate push-pull cannulae. After a Na+ or Ca++ sensitive site was identified by perfusion at 50 mul/min of an artificial CSF containing 10.4 mM excess Ca++ ions or 13.6 mM excess Na+ ions, several types of experiments were undertaken with the results summarized as follows: if the cat was exposed to a cold or warm environmental temperature as the posterior hypothalamus was perfused with excess cation, the typical hypothermia was produced by Ca++ and hyperthermia by Na+ ions. However, if the cat was exposed to peripheral cooling or warming 30 min prior to the perfusion, the fall or rise produced by Ca++ or Na+ was attenuated or prevented. In other experiments, 1.0 muCi 45Ca++ was injected in the ion sensitive site in the posterior hypothalamus to label stores of the cation. Raising of ambient temperature caused a retention of 45Ca++ in this hypothalmic area, whereas a cold environmental temperature enhanced the efflux of 45Ca++ at the same perfusion site. The magnitude of change in 45Ca++ efflux depended upon the intensity of the thermal challenge. Similarly, warming of the anterior hypothalmic, preoptic area by means of implanted thermodes caused an immediate diminution in 45Ca++ efflux in the posterior hypothalamus, whereas cooling of this anterior region augmented the extrusion of 45Ca++ ions from the posterior area. When substances which produce a temperature change were applied to the same thermosensitive zone, the direction of shift in 45Ca++ flux in the posterior area corresponded to the signal for heat production or heat loss. That is, the microinjection of 5-HT, PGE1 or Salmonella typhosa into the anterior hypothalamus enhanced the efflux of 45Ca++ in the posterior hypothalamus as hyperthermia developed, whereas a similar microinjection of norepinephrine reduced the 45Ca++ output from the same sites. Finally, locally anesthetizing the cells of the anterior hypothalamus by the nerve blocker, procaine, prevented the cold and heat-induced 45Ca++ eflux and retention, respectively. These results suggest that if the Na+-Ca++ ratio in the posterior hypothalamus establishes and maintains the set-point for body temperature of 37 degrees -38 degrees C, the mechanism of lability of Ca++ through changes in binding characteristics, transport, or metabolism of the cation serves two purposes: (1) the active defense of the set-point temperature through gradations in ion shifts; and (2) the upward or downward change in set-point value, pathological or normal, triggered by virtue of impulses relayed from the anterior hypothalamus.