Xiao Ming Chen

Efferent projection from the preoptic area for the control of non-shivering thermogenesis in rats

1 To investigate the characteristics of efferent projections from the preoptic area for the control of non‐shivering thermogenesis, we tested the effects of thermal or chemical stimulation, and transections of the preoptic area on the activity of interscapular brown adipose tissue in cold‐acclimated and non‐acclimated anaesthetized rats. 2 Electrical stimulation of the ventromedial hypothalamic nucleus (VMH) elicited non‐shivering thermogenesis in the brown adipose tissue (BAT); warming the preoptic area to 41.5 °C completely suppressed the thermogenic response. 3 Injections of d,l‐homocysteic acid (DLH; 0.5 mm, 0.3 μl) into the preoptic area also significantly attenuated BAT thermogenesis, whereas injections of control vehicle had no effect. 4 Transections of the whole hypothalamus in the coronal plane at the level of the paraventricular nucleus induced rapid and large rises in BAT and rectal temperatures. This response was not blocked by pretreatment with indomethacin. The high rectal and BAT temperatures were sustained more than 1 h, till the end of the experiment. Bilateral knife cuts that included the medial forebrain bundle but not the paraventricular nuclei elicited similar rises in BAT and rectal temperatures. Medial knife cuts had no effect. 5 These results suggest that warm‐sensitive neurones in the preoptic area contribute a larger efferent signal for non‐shivering thermogenesis than do cold‐sensitive neurones, and that the preoptic area contributes a tonic inhibitory input to loci involved with non‐shivering thermogenesis. This efferent inhibitory signal passes via lateral, but not medial, hypothalamic pathways.

Neuronal networks controlling thermoregulatory effectors

Publisher Summary This chapter summarizes the present knowledge about neuronal networks controlling thermoregulation, mainly knowledge about the efferent pathways from the hypothalamus. The body temperature of a homeothermic animal is regulated by multiple behavioral and autonomic effector responses, and the thermoreceptors responsible for these responses are distributed throughout the body. They are present in not only the skin and the hypothalamus but also in other brain areas and deep in the bodycore. The rostra1 ventrolateral medulla of a cat contains neurons projecting to the spinal cord and presumably sending signals to the sympathetic. Direct recording of sympathetic nerve activities in humans has revealed that skin sympathetic nerves contain vasoconstrictor and sudomotor fibers and that cutaneous sympathetic nerve activity is not correlated with the changes in blood pressure. Animals with preoptic and anterior hypothalamic lesions thermoregulate behaviorally, as well as control animals do, even though they show severe deficits in autonomic regulation. The only part of the neocortex or limbic system that has been systematically investigated in regard to behavioral thermoregulation is the sulcal prefrontal cortex in the rat.

Effect of midbrain stimulations on thermoregulatory vasomotor responses in rats.

1 Efferent projections eliciting vasodilatation when the preoptic area is warmed were investigated by monitoring tail vasomotor responses of ketamine‐anaesthetized rats when brain areas were stimulated electrically (0.2 mA, 200 μs, 0 Hz) or with the excitatory amino acid D,L‐homocysteic acid (1 mM, 0.3 μM). 2 Both stimulations elicited vasodilatation when applied within a region extending from the most caudal part of the lateral hypothalamus to the ventrolateral periaqueductal grey matter (PAG) and the reticular formation ventrolateral to the PAG. 3 Vasodilatation elicited by preoptic warming was suppressed when either stimulation was applied within the rostral part of the ventral tegmental area (VTA). 4 Sustained vasodilatation was elicited by knife cuts caudal to the VTA, and vasodilatation elicited by preoptic warming was suppressed by cuts either rostral to the VTA or in the region including the PAG and the reticular formation ventrolateral to it. 5 These results, together with the results of earlier physiological and histological studies, suggest that warm‐sensitive neurones in the preoptic area send excitatory signals to vasodilatative neurones in the caudal part of the lateral hypothalamus, ventrolateral PAG and reticular formation, and send inhibitory signals to vasoconstrictive neurones in the rostral part of the VTA.

The caudal periaqueductal gray participates in the activation of brown adipose tissue in rats

To investigate the involvement of the periaqueductal gray (PAG) in the control of non-shivering thermogenesis, we tested the effects of electrical or chemical stimulation of the PAG on thermogenesis of brown adipose tissue (BAT) in urethane anesthetized rats. Electrical stimulation (0.1 mA, 33 Hz, 0.5 ms) or application of D,L-homocysteic acid (0.5 mM, 0.3 micro l) into the lateral region of the caudal PAG (cPAG) elicited BAT thermogenesis, measured as a rise in the local temperature of interscapular BAT. These results suggest that neurons in the cPAG send excitatory efferent signals for BAT thermogenesis.

Involvement of the suprachiasmatic nucleus in body temperature modulation by food deprivation in rats

Recently we found that food-deprived rats kept under a light-dark cycle showed a progressive reduction in body temperature during the light phase on each subsequent day while body temperature in the dark phase did not differ from baseline values. In this study, we investigated the effect of lesioning the hypothalamic suprachiasmatic nucleus (SCN) on body temperature modulation by food deprivation. In the SCN-lesioned rats in which daily rhythms of body temperature and activity were abolished, body temperature was unchanged by food deprivation. We also examined the effect of food deprivation on the daily changes in Fos expression in the SCN. Under normal fed conditions the number of SCN cells expressing Fos is high during the day and low at night. Food deprivation attenuated the amplitude of this daily change in Fos expression in the SCN. This tendency was prominent in the dorsal part of the SCN, while the ventral part showed no effect of food deprivation. These findings suggest that the SCN plays some role in body temperature modulation due to food deprivation.

New apparatus for studying behavioral thermoregulation in rats

The operant system described here contains a box that can be convectively heated or cooled. A rat moves freely in the box. Its location is monitored photoelectrically while its deep body temperature is monitored by a telemetry system. In heat-escape experiments, hot air (40 degrees C) flows through the box. When the rat enters a reward zone the air source is switched and cold air (0 degrees C) flows through the box for a given period (30 s). Conversely, in cold-escape experiments cold air flows through the box and when the rat enters the reward zone the air source is switched to a warm one. Experiments show that rats quickly learn to stay near the reward zone and move in and out of it periodically. This system is based on behavior more natural than the frequently used lever-pressing response, and has many advantages for use in studies involving behavioral thermoregulation.

Involvement of the raphé pallidus in the suppressive effect of preoptic warming on non-shivering thermogenesis in rats

Thermogenesis in the brown adipose tissue (BAT) is activated by the stimulation of the ventromedial hypothalamic nucleus (VMH). Local warming of the preoptic area (PO) suppresses this response. Injection of the GABA(A) receptor antagonist bicuculline into the caudal periaqueductal gray (cPAG), where excitatory neurons for BAT thermogenesis are located, did not influence the suppressive effect of PO warming. On the other hand, after bicuculline injection into the raphé pallidus, where excitatory neurons for BAT thermogenesis are also located, VMH stimulation produced BAT thermogenesis even during PO warming. The present results suggest that the inhibitory signal from the PO reaches the raphé pallidus and not the cPAG for the control of BAT thermogenesis.