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

Chen, Xiaoming; Hosono, Takayoshi; Yoda, Teruhiko; Fukuda, Yutaka; Kanosue, Kazuyuki

doi:10.1111/j.1469-7793.1998.883bd.x

Cited by 140 publications

(101 citation statements)

References 29 publications

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“…In addition, another pathway through the dorsomedial hypothalamic nucleus was also proposed to transmit POA-derived pyrogenic PGE 2 signals . Other reports showed that warming of the POA abolished BAT thermogenesis evoked by stimulation of a hypothalamic region (Chen et al, 1998) and that this inhibitory effect by POA warming was antagonized by bicuculline injection into the raphe pallidus nucleus (Taniguchi et al, 2003). These findings suggest that the pyrogenic and heat-gain signals from the POA are conveyed to rostral medullary raphe regions and activate VGLUT3-expressing neurons therein.…”

Section: Discussionsupporting

confidence: 48%

“…Thus, PGE 2 is considered to act on the EP3 receptor of POA neurons and trigger fever. The POA is also known as one of the major central thermosensitive sites to monitor deep body temperature: cooling of this region causes nonshivering thermogenesis (Banet et al, 1978;Imai-Matsumura et al, 1984), possibly as a result of suppression of warmsensitive neurons (Chen et al, 1998).…”

Section: Discussionmentioning

confidence: 99%

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Identification of Sympathetic Premotor Neurons in Medullary Raphe Regions Mediating Fever and Other Thermoregulatory Functions

Nakamura

Matsumura

Hübschle

et al. 2004

Journal of Neuroscience

259

322

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Sympathetic premotor neurons directly control sympathetic preganglionic neurons (SPNs) in the intermediolateral cell column (IML) of the thoracic spinal cord, and many of these premotor neurons are localized in the medulla oblongata. The rostral ventrolateral medulla contains premotor neurons controlling the cardiovascular conditions, whereas rostral medullary raphe regions are a candidate source of sympathetic premotor neurons for thermoregulatory functions. Here, we show that these medullary raphe regions contain putative glutamatergic neurons and that these neurons directly control thermoregulatory SPNs. Neurons expressing vesicular glutamate transporter 3 (VGLUT3) were distributed in the rat medullary raphe regions, including the raphe magnus and rostral raphe pallidus nuclei, and mostly lacked serotonin immunoreactivity. These VGLUT3-positive neurons expressed Fos in response to cold exposure or to central administration of prostaglandin E 2 , a pyrogenic mediator. Transneuronal retrograde labeling after inoculation of pseudorabies virus into the interscapular brown adipose tissue (BAT) or the tail indicated that those VGLUT3-expressing medullary raphe neurons innervated these thermoregulatory effector organs multisynaptically through SPNs of specific thoracic segments, and microinjection of glutamate into the IML of the BAT-controlling segments produced BAT thermogenesis. An anterograde tracing study further showed a direct projection of those VGLUT3-expressing medullary raphe neurons to the dendrites of SPNs. Furthermore, intra-IML application of glutamate receptor antagonists blocked BAT thermogenesis triggered by disinhibition of the medullary raphe regions. The present results suggest that VGLUT3-expressing neurons in the medullary raphe regions constitute excitatory neurons that could be categorized as a novel group of sympathetic premotor neurons for thermoregulatory functions, including fever.

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Section: Discussionsupporting

confidence: 48%

Section: Discussionmentioning

confidence: 99%

Identification of Sympathetic Premotor Neurons in Medullary Raphe Regions Mediating Fever and Other Thermoregulatory Functions

Nakamura

Matsumura

Hübschle

et al. 2004

Journal of Neuroscience

259

322

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“…The currently accepted model of thermoregulation is that both heat production and heat loss are under tonic inhibitory control by warm-sensitive preoptic neurons (Zhang et al, 1995;Chen et al, 1998;Nagashima et al, 2000;Osaka, 2004;Rathner et al, 2008;Tanaka et al, 2009), with those regulating heat production projecting to the DMH and those regulating heat dissipation projecting directly to the medullary raphé (Nakamura and Morrison, 2007;Morrison et al, 2008;Rathner et al, 2008). No significant output from the preoptic region has been attributed to coldsensitive cells.…”

Section: Tail Sympathetic Nerve Fiber Recordingmentioning

confidence: 99%

Preoptic–Raphé Connections for Thermoregulatory Vasomotor Control

Tanaka¹,

McKinley²,

McAllen³

2011

J. Neurosci.

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Blood flow to glabrous skin such as the rat's tail determines heat dissipation from the body and is regulated by sympathetic vasoconstrictor nerves. Tail vasoconstrictor activity is tonically inhibited by neurons in two distinct preoptic regions, rostromedial (RMPO) and caudolateral (CLPO) regions, whose actions may be via direct projections to medullary raphé premotor neurons. In urethaneanesthetized rats, we sought single preoptic neurons that were antidromically activated from the medullary raphé and could subserve this function. Nine of 45 raphé-projecting preoptic neurons, predominantly in the CLPO, showed spontaneous activity under warm conditions and were inhibited by cooling the trunk skin (warm-responsive). Unexpectedly, 14 raphé-projecting preoptic neurons (mostly in the RMPO) were activated by skin cooling (cold-responsive), suggesting that an excitatory pathway from this region could contribute to tail vasoconstriction. Supporting this, neuronal disinhibition in the RMPO by microinjecting the GABA A receptor antagonist bicuculline (0.5 mM, 15 nl) caused a rapid increase in tail sympathetic nerve activity (SNA). Similar injections into the CLPO were without effect. Electrical stimulation of the RMPO also activated tail SNA, with a latency ϳ25 ms longer than to stimulation of the medullary raphé. Injection of the glutamate receptor antagonist kynurenate (50 mM, 120 nl) into the medullary raphé suppressed tail SNA responses to both RMPO bicuculline and skin cooling. These findings suggest that both inhibitory and excitatory descending drives regulate tail vasoconstriction in the cold and that warm-and cold-responsive raphé-projecting preoptic neurons may mediate these actions.

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“…Cooling of this area activates BAT ( 62,63 ), whereas warming suppresses its activity ( 64 ). The signal is mediated through the VMH and medulla oblongata and then passes through the spinal cord until it reaches the relevant IML neurons ( 65 ).…”

Section: Sympathetic Innervation Of Batmentioning

confidence: 99%

Sympathetic nervous system control of triglyceride metabolism: novel concepts derived from recent studies

Geerling

Boon

Kooijman

et al. 2014

Journal of Lipid Research

107

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Dyslipidemia is one of the classical risk factors for cardiovascular diseases (CVD) besides hypertension, type 2 diabetes, and smoking ( 1 ). Dyslipidemia is defi ned as an elevation of plasma LDL-cholesterol (LDL-C), triglycerides (TG), or both, with or without a lowering of HDLcholesterol (HDL-C) ( 2 ). Whereas elevated LDL-C is a well-established major predictor of CVD and has been the primary target for lipid-lowering strategies, evidence suggests that an elevated TG level is an independent risk factor for CVD development as well ( 3, 4 ). Plasma TG levels are considered elevated when they exceed 150 mg/dl, which is observed in 31% of the adult US population ( 5 ). Although hypertriglyceridemia can be caused by rare monogenic disorders, it is mostly caused by a complex interaction between environmental factors and subtle variations in genes involved in lipoprotein metabolism ( 5 ). Current treatments for hypertriglyceridemia are aimed at either increasing TG clearance (e.g., fi brates) ( 6 ) or at decreasing lipolysis in WAT (e.g., niacin) ( 7 ). In addition, reduction of VLDL-TG production lowers plasma TG levels (e.g., exendin-4) ( 8 ).In recent years, the autonomic nervous system, which consists of a sympathetic and a parasympathetic branch, emerged as an important regulator of metabolic homeostasis. Whereas the role of the sympathetic nervous system (SNS) in the regulation of glucose metabolism has been fi rmly established (for review, see Ref. 9 ), considerably fewer studies have focused on its role in TG metabolism. This review provides an update specifi cally on the role of Abstract Important players in triglyceride (TG) metabolism include the liver (production), white adipose tissue (WAT) (storage), heart and skeletal muscle (combustion to generate ATP), and brown adipose tissue (BAT) (combustion toward heat), the collective action of which determine plasma TG levels. Interestingly, recent evidence points to a prominent role of the hypothalamus in TG metabolism through innervating the liver, WAT, and BAT mainly via sympathetic branches of the autonomic nervous system. Here, we review the recent fi ndings in the area of sympathetic control of TG metabolism. Various neuronal populations, such as neuropeptide Y (NPY)-expressing neurons and melanocortin-expressing neurons, as well as peripherally produced hormones (i.e., GLP-1, leptin, and insulin), modulate sympathetic outfl ow from the hypothalamus toward target organs and thereby infl uence peripheral TG metabolism. We conclude that sympathetic stimulation in general increases lipolysis in WAT, enhances VLDL-TG production by the liver, and increases the activity of BAT with respect to lipolysis of TG, followed by combustion of fatty acids toward heat. Moreover, the increased knowledge about the involvement of the neuroendocrine system in TG metabolism presented in this review offers new therapeutic options to fi ght hypertriglyceridemia by specifi cally modulating sympathetic nervous system outfl ow toward liver, BAT, or WAT .-Geerling, J. J., M. R. B...

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

Cited by 140 publications

References 29 publications

Identification of Sympathetic Premotor Neurons in Medullary Raphe Regions Mediating Fever and Other Thermoregulatory Functions

Identification of Sympathetic Premotor Neurons in Medullary Raphe Regions Mediating Fever and Other Thermoregulatory Functions

Preoptic–Raphé Connections for Thermoregulatory Vasomotor Control

Sympathetic nervous system control of triglyceride metabolism: novel concepts derived from recent studies

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