Defending body temperature against environmental thermal challenges is one of the most fundamental homeostatic functions governed by the nervous system. Here we show a novel somatosensory pathway, which essentially constitutes the afferent arm of the thermoregulatory reflex triggered by cutaneous sensation of environmental temperature changes. Using rat in vivo electrophysiological and anatomical approaches, we revealed that lateral parabrachial neurons play a pivotal role in this pathway by glutamatergically transmitting cutaneous thermosensory signals received from spinal somatosensory neurons directly to the thermoregulatory command center, preoptic area. This feedforward pathway mediates not only sympathetic and shivering thermogenic responses but also metabolic and cardiac responses to skin cooling challenges. Notably, this 'thermoregulatory afferent' pathway exists in parallel with the spinothalamocortical somatosensory pathway mediating temperature perception. These findings make an important contribution to our understanding of both the somatosensory system and thermal homeostasis-two mechanisms fundamental to the nervous system and to our survival.Even during rapid changes in environmental temperature, the body temperature of homeothermic animals, including humans, is maintained within the narrow range necessary for optimal cellular and molecular functions. How the nervous system functions to defend body temperature against environmental thermal challenges remains a fundamental question in physiology 1,2 . The preoptic area (POA) is the thermoregulatory center providing command signals descending to peripheral effectors 1,3-6 . To evoke behavioral, autonomic, somatic and hormonal responses counteracting changes in environmental temperature before they impact body core temperature, thermoregulatory command neurons in the POA need to receive feedforward signaling of environmental temperature information from skin thermoreceptors through the spinal and trigeminal dorsal horns 3,5-8 . However, the neural substrate for the ascending thermoregulatory feedforward pathway, especially the essential central mechanism linking the second order somatosensory neurons in the dorsal horn to the POA has yet to be identified.The best-known central pathway for somatosensory signaling of cutaneous thermal sensation is the spinothalamocortical pathway, in which signals from skin thermoreceptors are transmitted through a direct projection from the dorsal horn to the thalamus and then relayed to the primary somatosensory cortex 9,10 . Although the spinothalamocortical pathway is responsible for perception and discrimination of cutaneous temperature 9,10 , it is unknown whether this pathway contributes to homeostatic responses against changes in environmental
SUMMARY Thermogenesis, the production of heat energy, is the specific, neurally-regulated, metabolic function of brown adipose tissue (BAT) and contributes to the maintenance of body temperature during cold exposure and to the elevated core temperature during several behavioral states, including wakefulness, the acute phase response (fever), and stress. BAT energy expenditure requires metabolic fuel availability and contributes to energy balance. This review summarizes the functional organization and neurochemical influences within the CNS networks governing the level of BAT sympathetic nerve activity to produce the thermoregulatory and metabolically-driven alterations in BAT thermogenesis and energy expenditure that contribute to overall energy homeostasis.
The thermogenic activity of interscapular brown adipose tissue (IBAT) in response to physiologic stimuli, such as cold exposure, is controlled by its sympathetic innervation. To determine which brain regions might be involved in the regulation of cold-evoked increases in sympathetic outflow to IBAT, the present study compared central nervous system (CNS) areas activated by cold exposure with brain regions anatomically linked to the sympathetic innervation of IBAT. Immunocytochemical localization of Fos was examined in the brains of rats exposed to 4 degrees C for 4 hours. In a separate group of rats, the neural circuit involved in IBAT control, including the location of sympathetic preganglionic neurons in the spinal cord, was characterized with pseudorabies virus, a retrograde transynaptic tracer. Central noradrenergic and serotonergic groups related to the sympathetic outflow to IBAT also were identified. Localization of viral antigens at different survival times (66-96 hours) revealed infection in circumscribed CNS populations, but only a subset of the regions comprising this circuitry showed cold-evoked Fos expression. The raphe pallidus and the ventromedial parvicellular subdivision of the paraventricular hypothalamic nucleus (PVH), both infected at early survival times, were the main areas containing sympathetic premotor neurons activated by cold exposure. Major cold-sensitive areas projecting to spinal interneurons or to regions containing sympathetic premotor neurons, which became infected at intermediate intervals, included lateral hypothalamic, perifornical, and retrochiasmatic areas, anterior and posterior PVH, ventrolateral periaqueductal gray, and Barrington's nucleus. Areas infected later, most likely related to reception of cold-related signals, comprised the lateral preoptic area, parastrial nucleus, dorsomedial hypothalamic nucleus, lateral parabrachial nucleus, and nucleus of the solitary tract. These interconnected areas, identified by combining functional and retrograde anatomic approaches, likely constitute the central circuitry responsible for the increase in sympathetic outflow to IBAT during cold-evoked thermogenesis.
Control of thermoregulatory effectors by the autonomic nervous system is a critical component of rapid cold-defense responses, which are triggered by thermal information from the skin. However, the central autonomic mechanism driving thermoregulatory effector responses to skin thermal signals remains to be determined. Here, we examined the involvement of several autonomic brain regions in sympathetic thermogenic responses in brown adipose tissue (BAT) to skin cooling in urethane-chloralose-anesthetized rats by monitoring thermogenic [BAT sympathetic nerve activity (SNA) and BAT temperature], metabolic (expired CO(2)), and cardiovascular (arterial pressure and heart rate) parameters. Acute skin cooling, which did not reduce either rectal (core) or brain temperature, evoked increases in BAT SNA, BAT temperature, expired CO(2), and heart rate. Skin cooling-evoked thermogenic, metabolic, and heart rate responses were inhibited by bilateral microinjections of bicuculline (GABA(A) receptor antagonist) into the preoptic area (POA), by bilateral microinjections of muscimol (GABA(A) receptor agonist) into the dorsomedial hypothalamic nucleus (DMH), or by microinjection of muscimol, glycine, 8-OH-DPAT (5-HT(1A) receptor agonist), or kynurenate (nonselective antagonist for ionotropic excitatory amino acid receptors) into the rostral raphe pallidus nucleus (rRPa) but not by bilateral muscimol injections into the lateral/dorsolateral part or ventrolateral part of the caudal periaqueductal gray. These results implicate the POA, DMH, and rRPa in the central efferent pathways for thermogenic, metabolic, and cardiac responses to skin cooling, and suggest that these pathways can be modulated by serotonergic inputs to the medullary raphe.
Thermogenesis, the production of heat energy, is an essential component of the homeostatic repertoire to maintain body temperature in mammals and birds during the challenge of low environmental temperature and plays a key role in elevating body temperature during the febrile response to infection. The primary sources of neurally regulated metabolic heat production are mitochondrial oxidation in brown adipose tissue, increases in heart rate and shivering in skeletal muscle. Thermogenesis is regulated in each of these tissues by parallel networks in the central nervous system, which respond to feedforward afferent signals from cutaneous and core body thermoreceptors and to feedback signals from brain thermosensitive neurons to activate the appropriate sympathetic and somatic efferents. This review summarizes the research leading to a model of the feedforward reflex pathway through which environmental cold stimulates thermogenesis and discusses the influence on this thermoregulatory network of the pyrogenic mediator, prostaglandin E 2 , to increase body temperature. The cold thermal afferent circuit from cutaneous thermal receptors ascends via second-order thermosensory neurons in the dorsal horn of the spinal cord to activate neurons in the lateral parabrachial nucleus, which drive GABAergic interneurons in the preoptic area to inhibit warm-sensitive, inhibitory output neurons of the preoptic area. The resulting disinhibition of thermogenesis-promoting neurons in the dorsomedial hypothalamus and possibly of sympathetic and somatic premotor neurons in the rostral ventromedial medulla, including the raphe pallidus, activates excitatory inputs to spinal sympathetic and somatic motor circuits to drive thermogenesis. Thermogenesis, the production of heat energy, is an essential component of the homeostatic repertoire to maintain body temperature during the challenge of low environmental temperature. In mammals, alert consciousness and normally patterned motor activities only occur when the temperature of the central nervous system is approximately 36-39• C. A fall in cellular temperature reduces enzyme efficiency and diffusion capacity, reducing cellular energy availability and membrane ion fluxes. Below-normal brain temperatures are associated with reduced alertness and with behavioural and physiological disorganization, although without physical damage to the CNS or peripheral tissues. In hibernating mammals, for instance, reduction of body and brain temperature to approximately 5• C is associated with torpor and inactivity, but normal consciousness and behaviour resume with reversal of the hibernation process. Additionally, the heat generated during stimulated thermogenesis contributes to fever, a controlled elevation in body temperature that reduces pathogen viability and stimulates immune cell responses. Since energy consumption during thermogenesis can involve oxidation of lipid fuel molecules, regulation of thermogenesis in response to metabolic signals can also contribute to energy balance and regulation of bod...
Maintenance of a homeostatic body core temperature is a critical brain function accomplished by a central neural network. This orchestrates a complex behavioral and autonomic repertoire in response to environmental temperature challenges or declining energy homeostasis and in support of immune responses and many behavioral states. This review summarizes the anatomical, neurotransmitter, and functional relationships within the central neural network that controls the principal thermoeffectors: cutaneous vasoconstriction regulating heat loss and shivering and brown adipose tissue for heat production. The core thermoregulatory network regulating these thermoeffectors consists of parallel but distinct central efferent pathways that share a common peripheral thermal sensory input. Delineating the neural circuit mechanism underlying central thermoregulation provides a useful platform for exploring its functional organization, elucidating the molecular underpinnings of its neuronal interactions, and discovering novel therapeutic approaches to modulating body temperature and energy homeostasis.
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