Brown adipose tissue thermogenic responses of rats induced by central stimulation: effect of age and cold acclimation

Neuregulin4-ErbB4 signalling pathway is driven by electroacupuncture stimulation to remodel brown adipose tissue innervation

AIM

To show that electroacupuncture stimulation (ES) remodels sympathetic innervation in brown adipose tissue (BAT) via the bone morphogenic protein 8B (BMP8B)-neuregulin 4 (NRG4)-ErbB4 axis, with somatotopic dependence.

MATERIALS AND METHODS

We established a high-fat diet (HFD) model with C57BL/6J mice to measure the thermogenesis and metabolism of BAT. In addition, the sympathetic nerve activity (SNA) was measured with the electrophysiological technique, and the immunostaining of c-Fos was used to detect the central nervous system sources of sympathetic outflows. Finally, the key role of the BMP8B-NRG4-ErbB4 axis was verified by peripheral specific antagonism of ErbB4.

RESULTS

ES at the forelimb and abdomen regions significantly up-regulate SNA, whereas ES at the hindlimb region has a limited regulatory effect on SNA but still partially restores HFD-induced BAT dysfunction. Mechanistically, ES at the forelimb and abdomen regions driving catecholaminergic signals in brown adipocytes depends on neural activities projected from the ventromedial nucleus of the hypothalamus (VMH) to the spinal cord intermediolateral column (IML). Notably, the peripheral suppression of ErbB4 in BAT inhibits the thermogenesis and metabolic function of BAT, as well as significantly hindering the SNA activation and metabolic benefits induced by ES.

CONCLUSION

These results suggest that ES appears to be an effective approach for remodeling sympathetic innervation in BAT, which is closely related to neuronal activity in the VMH and the NRG4-ErbB4 signaling pathway.

Local response to cold in rat tail after spinal cord transection

Subjects with severe chronic spinal cord injury (SCI) are prone to hypothermia when they are exposed to relatively low environmental temperatures that are normally well tolerated by healthy individuals. This impaired thermoregulation is presumably due to disconnection of territories below the SCI from supraspinal thermoregulatory centers. However, it is not known how these territories respond to low temperatures. Using a complete transection at T11 in rats, we examined the responses of the tail to cold (6–9°C) by measuring changes in tail blood flow and skin temperature weekly for 8 wk after SCI. Despite no significant change in baseline mean flow or temperature in the tail, the transection effectively removed the sympathetically mediated supraspinal control of the tail vasculature, since the amplitude of the pulse flow was markedly increased and the natural variations of the mean flow were almost abolished. As expected, the cold challenge before SCI caused a marked drop in mean flow, pulse amplitude, and temperature of the tail. Surprisingly, the drops in mean blood flow and temperature were observed after SCI, although the decrease in flow was slower and the pulse amplitude was not reduced. The results suggest that the cutaneous vasculature of the tail is sensitive to cold and will constrict, despite disconnection from supraspinal centers. This local effect is slow but may be sufficient to maintain some level of thermoregulation to cold. Without this vascular reaction, the effects of SCI on temperature regulation to cold would probably be much worse.

Effects of acute heat exposure on prosencephalic c-Fos expression in normohydrated, water-deprived and salt-loaded rats

In the present study, the distribution pattern of c-Fos protein immunoreactivity (Fos-IR) in prosencephalic areas of the brain involved in thermoregulatory and osmoregulatory responses was investigated, in rats exposed or not exposed to a hyperthermic environment, under three different conditions: normohydration, dehydration induced by water deprivation and hyperosmolarity induced by an acute intragastric salt load. Normohydrated, water-deprived or salt-loaded male Wistar rats (270+/-30 g) were submitted or not to acute heat exposure (33 degrees C for 45 min). A separate group of animals was submitted to the same experimental protocol and had blood samples collected before and after the heating period to measure serum osmolarity and sodium. The brains were processed for c-Fos immunohistochemistry using the avidin-biotin peroxidase method. After analyzing Fos-IR in the brains of animals in the present study, three different types of prosencephalic areas were identified: (1) those that respond to hydrational and to heat conditions, with an interaction between these two factors (PaMP and SON); (2) those that respond to hydrational and to heat conditions, but with no interaction between these factors (MnPO, LSV and OVLT); and (3) those that respond only to hydrational status (SFO and PaLM).

Brown adipose tissue: function and physiological significance

The function of brown adipose tissue is to transfer energy from food into heat; physiologically, both the heat produced and the resulting decrease in metabolic efficiency can be of significance. Both the acute activity of the tissue, i.e., the heat production, and the recruitment process in the tissue (that results in a higher thermogenic capacity) are under the control of norepinephrine released from sympathetic nerves. In thermoregulatory thermogenesis, brown adipose tissue is essential for classical nonshivering thermogenesis (this phenomenon does not exist in the absence of functional brown adipose tissue), as well as for the cold acclimation-recruited norepinephrine-induced thermogenesis. Heat production from brown adipose tissue is activated whenever the organism is in need of extra heat, e.g., postnatally, during entry into a febrile state, and during arousal from hibernation, and the rate of thermogenesis is centrally controlled via a pathway initiated in the hypothalamus. Feeding as such also results in activation of brown adipose tissue; a series of diets, apparently all characterized by being low in protein, result in a leptin-dependent recruitment of the tissue; this metaboloregulatory thermogenesis is also under hypothalamic control. When the tissue is active, high amounts of lipids and glucose are combusted in the tissue. The development of brown adipose tissue with its characteristic protein, uncoupling protein-1 (UCP1), was probably determinative for the evolutionary success of mammals, as its thermogenesis enhances neonatal survival and allows for active life even in cold surroundings.

Activation of brown adipose tissue thermogenesis increases slow wave sleep in rat

Considering the thermoregulatory role of slow wave sleep (SWS), we wondered whether the sole increase of brown adipose tissue (BAT) thermogenesis could enhance this sleep state. We tested this hypothesis by administering to rats an agonist (BRL 37,344) of the beta-3 adrenoceptor subtype that is massively localized in BAT cell membrane and that is known to activate BAT thermogenesis. Sleep was electrographically characterized. The temperature of interscapular BAT (Tibat) and cortex (Tco) were also assessed. Tibat significantly increased 2-3 h after BRL injection (but not Tco), concomitantly with SWS (+56-57%). At the maximum of Tibat, a significant positive correlation was found between their changes and those of SWS. We demonstrated for the first time that sleep (and especially SWS) can be affected by the specific activation of BAT.

Neuronal circuitries involved in thermoregulation

The body temperature of homeothermic animals is regulated by systems that utilize multiple behavioral and autonomic effector responses. In the last few years, new approaches have brought us new information and new ideas about neuronal interconnections in the thermoregulatory network. Studies utilizing chemical stimulation of the preoptic area revealed both heat loss and production responses are controlled by warm-sensitive neurons. These neurons send excitatory efferent signals for the heat loss and inhibitory efferent signals for the heat production. The warm-sensitive neurons are separated and work independently to control these two opposing responses. Recent electrophysiological analysis have identified some neurons sending axons directly to the spinal cord for thermoregulatory effector control. Included are midbrain reticulospinal neurons for shivering and premotor neurons in the medulla oblongata for skin vasomotor control. As for the afferent side of the thermoregulatory network, the vagus nerve is recently paid much attention, which would convey signals for peripheral infection to the brain and be responsible for the induction of fever. The vagus nerve may also participate in thermoregulation in afebrile conditions, because some substances such as cholecyctokinin and leptin activate the vagus nerve. Although the functional role for this response is still obscure, the vagus may transfer nutritional and/or metabolic signals to the brain, affecting metabolism and body temperature.

CNS origins of the sympathetic nervous system outflow to brown adipose tissue

Brown adipose tissue (BAT) plays a critical role in cold- and diet-induced thermogenesis. Although BAT is densely innervated by the sympathetic nervous system (SNS), little is known about the central nervous system (CNS) origins of this innervation. The purpose of the present experiment was to determine the neuroanatomic chain of functionally connected neurons from the CNS to BAT. A transneuronal viral tract tracer, Bartha's K strain of the pseudorabies virus (PRV), was injected into the interscapular BAT of Siberian hamsters. The animals were killed 4 and 6 days postinjection, and the infected neurons were visualized by immunocytochemistry. PRV-infected neurons were found in the spinal cord, brain stem, midbrain, and forebrain. The intensity of labeled neurons in the forebrain varied from heavy infections in the medial preoptic area and paraventricular hypothalamic nucleus to few infections in the ventromedial hypothalamic nucleus, with moderate infections in the suprachiasmatic and lateral hypothalamic nuclei. These results define the SNS outflow from the brain to BAT for the first time in any species.

Thermoresponsiveness of posterior hypothalamic (PH) neurons of rats to scrotal and abdominal thermal stimulation

The thermoresponsiveness of posterior hypothalamic (PH) neurons to localized, incremental thermal heating and cooling between 10-40 degrees C of the abdomen or scrotum was determined in urethane anesthetized, male Sprague-Dawley rats whose core temperature was maintained at 37 degrees C during testing. PH extracellular neuronal activity was recorded along with changes in gastrocnemius muscle EMG activity and temperature (Tms, indicative of shivering thermogenesis) and intrascapular brown adipose tissue temperature (TIBATs, indicative of non-shivering thermogenesis). Seventy-five PH neurons were recorded following both scrotal and abdominal trials of thermal stimulation. Nine percent of PH neurons were classified as warm responsive neurons (WRNs), 20% as cold responsive (CRNs), and 71% as temperature nonresponsive neurons (TNRNs), based on their thermal coefficients (TCs). Mean TC for warm PH neurons was significantly increased with scrotal warming between 30-40 degrees C from the mean TC of the same PH WRNs following abdominal warming. Similarly, the thermal coefficient was increased (i.e., was more negative) for cold responsive PH neurons to scrotal cooling (20-10 degrees C) as opposed to the TC of the same PH CRNs for abdominal cooling. No shivering thermogenesis (no change in temperature or EMG activity from gastrocnemius muscle) or non-shivering thermogenesis (no significant increase in IBAT temperatures) occurred with scrotal or abdominal cooling in these 21 degrees C acclimatized rats. The results indicate that a small population of PH neurons are thermoresponsive to localized physiological changes in temperature of the scrotum and abdomen with greater thermoresponsiveness shown of both warm and cold PH neurons to scrotal vs. abdominal thermal stimulation.

Difference in brown adipose tissue effector response and associated thermoresponsiveness of ventromedial hypothalamic (VMH) neurons of 21 degrees C vs. 4 degrees C acclimatized rats to scrotal thermal stimulation

The present study was designed (1) to determine if scrotal thermal stimulation would activate brown adipose tissue (BAT) thermogenesis, indicated by increases in interscapular BAT temperature (TIBAT) of cold acclimatized (CA, kept at 4 degrees C for 4 weeks) and room temperature acclimatized rats (RA, kept at 21 degrees C for 4 weeks) and (2) to compare the thermoresponsiveness of VMH neurons of both groups to scrotal heating and cooling. VMH extracellular activity was recorded in male RA and CA Sprague-Dawley rats when scrotal temperatures (Tsc) were changed between 5-40 degrees C via localized thermode (3 mm2) along with measurements of TscS and TIBATS. The CA-group showed significant increases in TIBATS during scrotal cooling compared to respective TIBATS of the RA-group. The ratio of VMH warm responsive (WRN), cold responsive (CRN) and temperature non-responsive (TNRN) neurons in the CA-group changed compared to that in the RA-group as a greater percentage of CRNs occurred in the CA-group. Also, the thermoresponsiveness of individual VMH CRNs of the CA rats was significantly increased compared to VMH CRNs of the RA-group. The results indicated that localized scrotal cooling of CA-rats (not RA-rats) can activate BAT thermogenesis. Furthermore, VMH CRNs increased their thermoresponsiveness with chronic cold exposure which may be an important neuronal adaptive response for the subsequent enhanced BAT thermogenic effector response seen in that group.

The thermoresponsiveness of ventromedial hypothalamic (VMH) neurons following repeated scrotal thermal stimulation of rats maintained at normothermic or acutely hypothermic core temperatures

Neurons within the central nervous system, including those within the ventromedial hypothalamic (VMH) nucleus, alter their neuronal activity in response to scrotal thermal stimulation. This study set out to establish if the thermoresponsiveness of VMH neurons becomes modified to repeated trials of scrotal thermal stimulation. VMH extracellular activity was recorded with a glass micropipette filled with 0.5 M sodium acetate in urethane-anaesthetized male Sprague-Dawley rats following 20 min scrotal heating (scrotal packs, 2 x 2 cm, filled with 40 degrees C hot water) and scrotal cooling (scrotal packs filled with ice). In study A, VMH neurons were tested to 2 trials of scrotal heating and cooling with colonic temperatures (T(c)s) servo-controlled at 37 degrees C during both trials. In study B, VMH neurons were tested for 3 trials of scrotal thermal stimulation, with T(c)s servo-controlled at 37, 35 and 33 degrees C during the 3 trials. In study A, 42 VMH neurons were isolated. Based on their thermal coefficients (TCs) to the 1st trial of scrotal heating and cooling, 12 VMH neurons were classified as warm-responsive neurons (WRNs), 10 as cold-responsive neurons (CRNs) and 20 were temperature-non-responsive neurons (TNRNs). Of the neurons recorded long enough to test their thermoresponsiveness to 2nd trial of scrotal thermal stimulation (9 out of 12 WRNs, 7 out of 10 CRNs and 18 out of 20 TNRNs), the mean TCs of each type of VMH neuron did not significantly change between the 2 trials. In study B, 65 VMH neurons were isolated and 11 out of 22 WRNs, 7 out of 13 CRNs and 15 out of 30 TNRNs had their thermoresponsiveness tested to 3 trials of scrotal heating and cooling, with T(c)s kept at 37, 35 and 33 degrees C, respectively, for these trials. The mean TCs for VMH WRNs, CRNs and TNRNs again did not change between the 3 trials of scrotal thermal stimulation. However, mean basal firing rates did increase significantly of all recorded VMH neurons between the 1st and 3rd trials of scrotal heating and cooling as T(c)s were acutely lowered from 37 to 33 degrees C. Results demonstrated that VMH thermoresponsive neurons retain their responsiveness to repeated trials of scrotal heating and cooling of animals maintained at normothermic (37 degrees C) or acutely hypothermic (35 and 33 degrees C) temperatures.

Specific thermal responsiveness of ventromedial hypothalamic neurons to localized scrotal heating and cooling in rats

1. The specificity of thermoresponsive ventromedial hypothalamic (VMH) neurons to localized, incremental scrotal thermal cooling and heating of urethane-anaesthetized male Sprague-Dawley rats (maintained at 37 degrees C colonically) was investigated. 2. Ventromedial hypothalamic extracellular neuronal activity and surface (scalp) electroencephalogram (EEG) activity from the parietal region were recorded. Intrascapular brown adipose tissue (TIBAT), surface tail (Tt) and scrotal (Tsc) temperatures, where thermal stimulation was evoked, were also monitored. 3. One hundred and twenty-five VMH neurons were recorded, with forty (32%) VMH neurons classified as warm-responsive neurons (WRNs), twenty-three (18%) as coldresponsive neurons (CRNs) and sixty-two (50%) as thermal non-responsive neurons (TNRNs) based on their thermal coefficients. Of VMH WRNs, 60% (i.e. 24) were classified as having biphasic neuronal activity responses, as were 60% (i.e. 14 of 23) of the CRNs. Forty per cent of WRNs and CRNs were classified as having monophasic changes in neuronal activity. 4. Scrotal heating or cooling from 5 to 40 degrees C resulted in specific firing rate changes of VMH WRNs and CRNs without any associated change in EEG activity (i.e. no significant change in EEG frequency or amplitude from initial baseline EEG activity when Tsc was 20 degrees C). EEG desynchronization (increased EEG frequency, decreased amplitude) was only observed when scrotal temperatures were at 45 degrees C or after each tail pinch (noxious stimulation) but not with scrotal brushing (mechanical stimulation). 5. With core temperature maintained at 37 degrees C, localized, scrotal heating and cooling of rats did not induce IBAT temperature changes indicative of brown adipose tissue activation, but delayed changes in tail temperature, indicative of vasoactive effector responses, did occur.

A functional medial preoptic nucleus (MPO) is required for scrotal thermal stimuli to alter the neuronal activity of thermoresponsive ventromedial hypothalamic (VMH) neurons

Thermoresponsiveness of ventromedial hypothalamic (VMH) neurons to scrotal thermal stimulation was determined before and after microinjection of lidocaine into the medial preoptic nucleus (MPO). Male, urethane anesthetized Sprague-Dawley rats, maintained colonically at 37 degrees C had VMH extracellular neuronal activity recorded following 3 cycles of scrotal thermal stimulation (localized, incremental heating and cooling, between 10 and 40 degrees C). Based on their thermal coefficients (TC), warm (WRN), cold (CRN) thermoresponsive and temperature non-responsive (TNRN) VMH neurons had their neuronal activity recorded following each cycle of scrotal thermal stimulation before and after MPO injections of sterile saline (300 nl volume) or 2% buffered lidocaine (200 ng). Thermoresponsiveness of all warm and cold VMH neurons to scrotal thermal stimulation was blocked by prior lidocaine administration into the MPO, effects that were reversed approximately 60 min after. However, MPO lidocaine administration caused no significant change in the thermal coefficients of VMH TNRNs to scrotal thermal stimulation. Results infer that a functional MPO is required for thermal afferent signals arising from the scrotum to reach thermoresponsive VMH neurons.

Activation of shivering and non-shivering thermogenesis by electrical stimulation of the lateral and medial preoptic areas

Experiments were conducted to determine if the area of stimulation within the preoptic area and/or the magnitude of the electrical stimulus applied to the preoptic region would selectively alter the evoked thermogenic responses of normothermic and hypothermic rats. Urethane anesthetized male, Long-Evans rats kept at 37 degrees C, and later cooled to 34 degrees C, were given unilateral electrical stimulation (0.5 ms pulses of 200 microA at 50 Hz for 30 and 300 s) into either the medial preoptic area (MPO) or the lateral preoptic area (LPO). Temperature changes of intrascapular brown adipose tissue, TIBATs; of gastrocnemius muscle, Tms, tail, Tts and colonic Tcs via thermistor probes were recorded before and after stimulation along with differential, multi-unit EMG activity of the gastrocnemius muscle via implanted stainless steel electrodes. The group kept at 37 degrees C and given MPO electrical stimulations evoked graded increases in TIBATs above core dependent on the duration of the electrical stimulus but shivering did not occur and Tms did not rise. When kept at 34 degrees C the MPO-stimulated group showed greater increases in TIBATs than respective responses seen when the same stimuli were applied at 37 degrees C. The group maintained at 37 degrees C and given LPO stimuli over 300 s increased Tms as shivering occurred, yet no change in TIBATs were observed. When cooled to 34 degrees C LPO stimulation (30 or 300 s duration) showed greater shivering activity. Interesting, LPO stimulation of animals maintained at 34 degrees C also caused TIBAT to increase.(ABSTRACT TRUNCATED AT 250 WORDS)

Sympathetic nervous activity to brown adipose tissue increases in cold-tolerant mice

Brown adipose tissue (BAT) is thought to be responsible for increased heat production in cold-acclimated rodents. We measured sympathetic nerve activity (SNA) in interscapular BAT (IBAT) during cold stimulation in cold-acclimated C57BL/6J mice (ACCLI). Cold acclimation was achieved (cold tolerance was increased) by repeated exposure to cold stress every other week for 3 weeks. We compared SNA in these animals with SNA in mice that had no previous cold stress experience (naive). During the test, mice were anesthetized by urethane and isoflurane and were paralyzed with vecuronium bromide. Sympathetic nerve activity was recorded directly from one of the fine nerves to IBAT. The animal's body caudal to the pelvic area was covered with a plastic bag containing a slurry of ice water to decrease colonic temperature 7 degrees C below control level, which took approximately 20 min. Interscapular BAT-SNA increased during cold stress in both groups, but ACCLI mice had higher IBAT-SNA during cold stress than naive mice. These findings confirmed the hypothesis that during the acute cold exposure, cold-acclimated mice have greater sympathetic outflow to BAT adipocytes.

Metabolic adaptations to exercise in the cold. An update

Metabolic adaptations to exercise in a cold environment include the liberation of heat by vigorous physical activity, shivering and various forms of nonshivering thermogenesis. During a single exposure to cold the main metabolic fuel is glycogen; however, repeated bouts of exercise in the cold also result in an increase in fat metabolism. Potential contributors to fat loss induced by exercise in the cold include: the energy cost of synthesising lean tissue; cold-induced excretion of ketones; stimulation of resting metabolism; and the high energy cost of movement in a cold environment (walking over snow, the weight of heavy boots, hobbling by winter clothing, and decreased mechanical efficiency of dehydrated muscles). Biochemical explanations of fat mobilisation include increased secretion of catecholamines, increased sensitivity of peripheral catecholamine receptors and a decrease in circulating insulin levels. Such fat loss may be helpful in treating moderate obesity, although the response seems less well developed in women than in men. Metabolic changes must be taken into consideration in preparing winter athletes for competition. Glycogen depletion has a negative effect on the performance of endurance competitors, but this can be countered by a combination of diet, training and cold acclimation.

Intrascapular brown adipose tissue (IBAT) temperature and blood flow responses following ventromedial hypothalamic stimulation to sham and IBAT-denervated rats

Intrascapular brown adipose tissue temperature (TIBAT) and capillary blood flow along with colonic (Tc) and tail (Tt) temperatures as well as blood pressure and heart rate responses were measured simultaneously in groups of age-matched, anesthetised, sham control and IBAT-denervated Long-Evans rats following VMH electrical stimulation. Unilateral VMH electrical stimulation (0.5 ms pulses of 100 microA at 50 Hz for 30 s) evoked rises in TIBAT (above core) and IBAT blood flow in the Long-Evans sham control group, along with increases in blood pressure and heart rate. Rises in IBAT temperature and capillary blood flow were absent in the surgical denervated group following VMH electrical stimulation whereas the evoked pressor and tachycardic responses were left intact and were similar to those responses seen in the sham control group. The results indicate that acute bilateral sectioning of the IBAT intercostal nerves blocks the IBAT temperature and capillary blood flow increases evoked by VMH electrical stimulation.

Posterior hypothalamic stimulation of anesthetized normothermic and hypothermic rats evokes shivering thermogenesis

Normothermic (37 degrees C), anesthetized Long Evans rats given unilateral electrical stimulation (0.5 ms monophasic pulses of 100-300 microA at 50 Hz for 30 s) of the posterior hypothalamus (PH) had graded, sustained increases in EMG electrical activity of the gastrocnemius muscle (i.e. shivering). In a current-related manner, gastrocnemius muscle temperatures (Tm) immediately increased following PH stimulation, surface temperatures (Tt) did not change and colonic (core, Tc) temperatures initially fell, then subsequently rose after the applied stimulus. A biphasic pressor response occurred after PH electrical stimulation associated with tachycardia. PH electrical stimulation (0.5 ms pulses at 50 Hz for 30 s of only 40 microA) induced shivering in anaesthetized, hypothermic Long Evans rats undergoing acute cold exposure. When these same hypothermic rats were cooled further to cause shivering, PH electrical stimulation (0.5 ms pulses at 50 Hz for 30 s of only 40 microA) induced further increases in the shivering response (increases EMG area of gastrocnemius muscle) from the shivering response before PH stimulation. Results indicate that electrical stimulation of the PH can evoke shivering in anesthetized normothermic rats. Stimulation of the PH with lower current intensity can induce or increase shivering of hypothermic rats previously exposed to the cold.

Brown adipose tissue temperature responses following electrical stimulation of ventromedial hypothalamic and lateral preoptic areas or after norepinephrine infusion to Long Evans or Sprague-Dawley rats

Thermoregulatory (brown adipose tissue temperature) experiments were conducted in age-matched anesthetized, male Sprague-Dawley and Long Evans rats kept at 37 degrees C given unilateral electrical stimulation of the ventromedial hypothalamic nucleus or the lateral preoptic area or after intravenous infusion of norepinephrine HCl (50 micrograms/kg total dose). Unilateral electrical stimulation (0.5 ms pulses of 250 microA at 50 Hz for 30 s) of the ventromedial nucleus or lateral preoptic area caused significant rises (greater than 0.6 degrees C) of intrascapular brown adipose tissue temperature in the Long Evans group only. Norepinephrine infusion (0.1 ml/min for 10 min), or intravenous bolus injection of propranolol HCl (2.5 mg/kg) caused significant yet similar increases (greater than 1.0 degrees C) and decreases (greater than -0.3 degrees C), respectively, of intrascapular brown adipose tissue temperature from pre-administration control temperatures in both Long Evans and Sprague-Dawley groups. The results demonstrate that intrascapular brown adipose tissue sensitivity towards exogenous norepinephrine or propranolol administration is similar between Sprague-Dawley and Long Evans rats acclimated to 21 degrees C as determined by increases in temperature in the intrascapular brown adipose tissue pad. However, intrascapular brown adipose tissue thermogenesis of 21 degrees C-acclimated Long Evans rats is also activated after CNS electrical stimulation of the ventromedial nucleus or lateral preoptic area, an activation not seen in Sprague-Dawley rats suggestive that the latter group has some inhibition of neural pathways that activate brown adipose tissue thermogenesis.

The effects of chronic ventromedial hypothalamic stimulation on weight gain in rats

The effects of chronic stimulation of the ventromedial hypothalamus and adjacent structures on body weight, food intake, and epididymal fat pad weight were examined in normophagic rats. Three hours of intermittent low level electrical stimulation were delivered three times per week for four weeks; body weight and food intake were monitored for an additional ten days after stimulation trials had ceased. Animals receiving ventromedial hypothalamic stimulation had the shallowest growth curves while stimulation of other structures produced a rate of growth that fell between that of the ventromedial hypothalamic and the implanted control group. This pattern persisted during the poststimulation phase. Food intake, while initially depressed in the stimulated groups, began to approach control levels by the third week of stimulation. Efficiency of food utilization (weight gain/consumption) was significantly reduced during the first week of stimulation in the ventromedial hypothalamic stimulated group. Fat pad weight was slightly decreased in this group as well. These findings suggest that chronic stimulation of the ventromedial hypothalamus causes a persistent shift in metabolic rate that results in a long-term inhibition of weight gain.

Influence of mild cold on the components of 24 hour thermogenesis in rats

1. The influence of two weeks' acclimation to either 28 degrees C (thermal neutrality) or 21 degrees C (mild cold) on 24 h heat production and motor activity has been investigated in male Wistar rats. Food intake was controlled and provided as a single meal of approximately 170 kJ per day. Mathematical modelling was used to relate metabolic rate to measured movement and time of day. 2. For animals at thermal neutrality it was clear that metabolic rate increased during periods of substantial measured movement and returned to baseline during periods of minimal activity. Total heat production could therefore be divided into two components: underlying and movement-induced thermogenesis. 3. At 21 degrees C, a more complex model was needed. During periods of substantial activity, the relation between metabolic rate and movement was similar to that at 28 degrees C and total heat production could be divided into the same two components of underlying and movement-induced thermogenesis. However, during periods of prolonged inactivity, a different model was required, which included a component of extra metabolic activity, termed supplementary thermogenesis. By fitting this model to data at 28 and 21 degrees C, it was possible to partition 24 h heat production into the three possible sources of underlying, movement-induced and supplementary thermogenesis. 4. Total 24 h heat production was approximately 25% higher for rats at 21 compared with 28 degrees C (P less than 0.01) and underlying thermogenesis was approximately 20% higher for those in the mild cold (P less than 0.01). Measured movement was significantly reduced in the mild cold (P less than 0.05) although it was energetically less efficient since there was no difference in movement-induced thermogenesis, which accounted for 18 and 15% of total heat production at 28 and 21 degrees C respectively. Supplementary thermogenesis was observed only in the mild cold and it accounted for approximately 6% of 24 h heat production, while the peak value accounted for 20% of total heat production. Circadian variations in thermogenesis were also different at 28 compared with 21 degrees C. Possible mechanisms accounting for the components of underlying thermogenesis and supplementary thermogenesis are discussed.

Brown adipose tissue thermogenesis is activated by electrical and chemical (L-glutamate) stimulation of the ventromedial hypothalamic nucleus in cold-acclimated rats

Experiments were conducted to determine if both electrical and chemical stimulation of the ventromedial hypothalamic nucleus (VMH) could activate brown adipose tissue (BAT) thermogenesis. Age-matched, room-acclimated (21 degrees C) and cold-acclimated (4 degrees C for 3 weeks prior to testing) male Sprague-Dawley rats were given unilateral electrical or chemical stimulation to the VMH by way of a 'chemotrode apparatus'. The devised 'chemotrode' allowed both electrical stimulation (insulated piano wire stimulating electrode) and chemical stimulation (23 gauge stainless steel intracranial cannula of equal length) to be performed at the same VMH site using a common 19 gauge stainless steel outer guide tube. The first unilateral VMH electrical stimulation (0.5 ms pulse, 50 Hz and 120 microA for 30 s) caused no significant rise in interscapular brown adipose tissue temperature (TIBAT) colonic (Tc) or tail surface temperatures (Tt), compared to respective prestimulation control values in rats acclimated to 21 degrees C. In the 4 degrees C-acclimated group the first VMH electrical stimulation caused a significant rise in IBAT temperature. L-Glutamate administration to the same VMH site (60 nmol in 600 nl volume) also caused a significant increase in IBAT temperature in the 4 degrees C but not the 21 degrees C-acclimated rats. The rise in IBAT temperature following the L-glutamate injection to the 4 degrees C-acclimated group was similar to that found following the first electrical stimulation to this group. Interestingly, a second unilateral electrical stimulation of the VMH to 4 degrees C-acclimated rats could not evoke a similar increase in IBAT temperature suggesting that overall L-glutamate was acting in vivo as an excitotoxin.(ABSTRACT TRUNCATED AT 250 WORDS)