ライフサイエンスコーパス: energy homeostasis

1 ephalin, consistent with an anorexic role in energy homeostasis.

2 he MC3R and MC4R in diseases of dysregulated energy homeostasis.

3 gy and response to neuropeptides involved in energy homeostasis.

4 link between intracellular Ca(2+) levels and energy homeostasis.

5 tiple metabolic pathways to warrant systemic energy homeostasis.

6 key role in regulating food consumption and energy homeostasis.

7 halamic glucose detection and the control of energy homeostasis.

8 e brain to adjust iBAT activity and maintain energy homeostasis.

9 e represents a critical component in healthy energy homeostasis.

10 targets has helped explain how AMPK restores energy homeostasis.

11 ssion and might be important for maintaining energy homeostasis.

12 es indispensable for maintenance of cellular energy homeostasis.

13 re play essential roles in the regulation of energy homeostasis.

14 mic MANF influences food intake and systemic energy homeostasis.

15 the brain's hypothalamus where it regulates energy homeostasis.

16 om the solitary nucleus which is involved in energy homeostasis.

17 ontrol of feeding-related traits involved in energy homeostasis.

18 he body, plays a critical role in regulating energy homeostasis.

19 d carbohydrate metabolic pathways as well as energy homeostasis.

20 enzyme responsible for maintaining cellular energy homeostasis.

21 patic glycogen stores and whole-body glucose/energy homeostasis.

22 ate that endothelial Lrp1 regulates systemic energy homeostasis.

23 role of endothelium in maintaining systemic energy homeostasis.

24 ine kinase whose activity maintains cellular energy homeostasis.

25 een eating behaviour, autonomic function and energy homeostasis.

26 uronal circuits that control food intake and energy homeostasis.

27 astrocytes is required to centrally regulate energy homeostasis.

28 ondrial biogenesis and autophagy to maintain energy homeostasis.

29 nsmission, pancreatic beta-cell function and energy homeostasis.

30 y cyclin D1 may couple cell proliferation to energy homeostasis.

31 mone that critically impacts food intake and energy homeostasis.

32 mus play a pivotal role in the regulation of energy homeostasis.

33 ant pathophysiological mediator in sleep and energy homeostasis.

34 top-down neural pathway that is crucial for energy homeostasis.

35 metabolic signals such as glucose to control energy homeostasis.

36 es an ancestral mechanism governing systemic energy homeostasis.

37 entral circuits and mechanisms that modulate energy homeostasis.

38 involved in maintaining systemic glucose and energy homeostasis.

39 in function in vivo and the role of MRAP2 in energy homeostasis.

40 insulin secretion, essential for maintaining energy homeostasis.

41 om the stomach and regulates food intake and energy homeostasis.

42 nrecognized and influential positive role in energy homeostasis.

43 al delivery) for controlling an imbalance in energy homeostasis.

44 on and release of FGF-21 to control systemic energy homeostasis.

45 a new pathway through which MRAP2 regulates energy homeostasis.

46 d of ways the gut microbiota influences host energy homeostasis.

47 ing the importance of SF-1 in the control of energy homeostasis.

48 rtant role in the hypothalamic regulation of energy homeostasis.

49 is and, ultimately, for maintaining systemic energy homeostasis.

50 ase (AMPK) is a molecular sensor to maintain energy homeostasis.

51 ocortin-4 receptor circuitry and its role in energy homeostasis.

52 inhibition in the brain improves glucose and energy homeostasis.

53 long time periods, such as those involved in energy homeostasis.

54 viability, stress response, metabolism, and energy homeostasis.

55 cular importance for an organism to maintain energy homeostasis.

56 l nucleus of the hypothalamus that regulates energy homeostasis.

57 tudies indicate that AHR is also involved in energy homeostasis.

58 on lipid droplets' biology and their role in energy homeostasis.

59 its well established function in regulating energy homeostasis.

60 of appetite, food intake and maintenance of energy homeostasis.

61 stible dietary components, have key roles in energy homeostasis.

62 synthesized by several organs and regulates energy homeostasis.

63 xis is of great importance in the control of energy homeostasis.

64 g to food availability is a key question for energy homeostasis.

65 de and a family of metabolites that regulate energy homeostasis.

66 ochondrial oxidative capacity and whole-body energy homeostasis.

67 major energy sensor that maintains cellular energy homeostasis.

68 progression and in metabolic regulation and energy homeostasis.

69 s vitamin D to the regulation of glucose and energy homeostasis.

70 memory, mood, anxiety, pain sensitivity, and energy homeostasis.

71 e that plays a prominent role in feeding and energy homeostasis.

72 of the brain that mediate ERalpha-dependent energy homeostasis.

73 ormally associated with feeding behavior and energy homeostasis.

74 an glucose storage cache and is critical for energy homeostasis.

75 has a fundamental role in the regulation of energy homeostasis.

76 its potentially substantial contributions to energy homeostasis.

77 trigger responses in key signals involved in energy homeostasis.

78 of autonomic neural circuits responsible for energy homeostasis.

79 , which further supports the role of mTOR in energy homeostasis.

80 factor that functions as a key regulator of energy homeostasis.

81 es for adipocyte-derived 5-HT in controlling energy homeostasis.

82 iotropic physiologic functions, including in energy homeostasis.

83 Cr) plays a vital role in neuron and myocyte energy homeostasis.

84 trols beige APC proliferation and whole-body energy homeostasis.

85 etals-and, more generally, micronutrients-to energy homeostasis.

86 sistant fever, and for improving glucose and energy homeostasis.

87 e CHRNA2 pathway in beige fat biogenesis and energy homeostasis.

88 to treat diseases of positive- and negative-energy homeostasis.

89 s boost mitochondrial respiration to restore energy homeostasis.

90 ed along the cytoskeleton to ensure cellular energy homeostasis.

91 mical reactions that must be fine-tuned with energy homeostasis.

92 e nucleotide polymorphisms (SNPs) related to energy homeostasis.

93 eige-fat biogenesis and improving whole-body energy homeostasis.

94 sm and further investigating MARC's roles in energy homeostasis.

95 nflammation, redox balance and metabolic and energy homeostasis.

96 pothalamic melanocortin circuits involved in energy homeostasis.

97 role of lactate metabolism in the control of energy homeostasis.

98 kinase (AMPK) is a key regulator of cellular energy homeostasis.

99 isruption of Semaphorin 3 signaling perturbs energy homeostasis.

100 ergy metabolite for adipocyte and whole-body energy homeostasis.

101 lates aerobic glycolytic genes and maintains energy homeostasis.

102 modulates circadian misalignment effects on energy homeostasis.

103 ic neurons in CNS control of food intake and energy homeostasis.

104 nase 1 (SnRK1 or KIN10/SnRK1.1), involved in energy homeostasis.

105 tic/neural interactions regulating sleep and energy homeostasis.

106 nal adipose tissue severely affects systemic energy homeostasis.

107 status is fundamental to the maintenance of energy homeostasis.

108 n important role in BAT and in regulation of energy homeostasis.

109 g hypoxia and starvation to promote cellular energy homeostasis.

110 also indicated a role in regulating systemic energy homeostasis.

111 ts that mediate several important aspects of energy homeostasis.

112 role in regulating whole-body metabolism and energy homeostasis (1).

113 ry previously found that DDX5 is involved in energy homeostasis, a process that is altered in many ca

114 , the physiological mechanisms that maintain energy homeostasis already control foraging intensity in

115 ases, such as disturbed cellular calcium and energy homeostasis and accumulation of toxic metabolites

116 iota and the eCB system in the regulation of energy homeostasis and adipose tissue inflammation and m

117 transcription factors mainly responsible for energy homeostasis and bile acid metabolism in the liver

118 rmogenesis, suggesting an additional role in energy homeostasis and body weight regulation.

119 eptor is a critical coordinator of mammalian energy homeostasis and body weight.

120 that KOR signaling is a pivotal regulator of energy homeostasis and can affect body weight during die

121 eric protein that plays an important role in energy homeostasis and cardioprotection.

122 roteasome system plays a role in maintaining energy homeostasis and cell survival during energy starv

123 ubiquitin-independent process in maintaining energy homeostasis and cell viability under starvation c

124 in diverse physiological functions, such as energy homeostasis and cognition.

125 e peptide 1 (GLP-1) is a strong moderator of energy homeostasis and communication between the periphe

126 rmone with a number of functions to maintain energy homeostasis and contribute to motivated behavior,

127 and reduced PTCD1 activity disrupts neuronal energy homeostasis and dampens spontaneous transmission.

128 an organ-specific manner to maintain cardiac energy homeostasis and determines cardiac physiological

129 plays a key role during fasting to maintain energy homeostasis and euglycemia via metabolic processe

130 ritical neural substrate for GLP-1 impact on energy homeostasis and expands the current map of brain

131 MC4R is a critical regulator of energy homeostasis and food intake in the hypothalamus.

132 of action of celastrol in the regulation of energy homeostasis and highlight the need for careful co

133 n microglial activation in the modulation of energy homeostasis and identify CX3CR1 signalling as a p

134 ge, but as an important central regulator in energy homeostasis and immunity.

135 or these metabolites in maintaining cellular energy homeostasis and in controlling signal transductio

136 p53 function in the regulation of adipocyte energy homeostasis and indicate that the dysregulation o

137 communities and can perturb host metabolism, energy homeostasis and inflammatory pathways, which lead

138 elanocortin-4 receptor (MC4R) is involved in energy homeostasis and is an important drug target for s

139 otein 2 (MRAP2) is an important regulator of energy homeostasis and its loss causes severe obesity in

140 irect anatomical and functional link between energy homeostasis and locomotor control systems.

141 IL-1beta/TNF-induced necrosis from impaired energy homeostasis and lysosomal permeabilization and in

142 ificant long-term effects on somatic growth, energy homeostasis and metabolic function in offspring.

143 arily conserved protein kinase implicated in energy homeostasis and metabolic regulation across eukar

144 pose tissue (BAT) are involved in whole-body energy homeostasis and metabolic regulation.

145 Control of energy homeostasis and metabolism is achieved by integra

146 re (HF) is characterized by perturbations in energy homeostasis and metabolism.

147 Energy homeostasis and oncogenic signaling are critical

148 movements are tightly controlled to maintain energy homeostasis and prevent oxidative stress.

149 determine whether SLC13A5 regulates hepatic energy homeostasis and proliferation of hepatoma cells.

150 s crucial for the control of wakefulness and energy homeostasis and promotes, in OX-1R-expressing cel

151 lateral hypothalamic area (LHA) to maintain energy homeostasis and regulate food intake behavior.

152 activity, thus playing an important role in energy homeostasis and regulation of appetite.

153 data show that p32 plays a critical role in energy homeostasis and represents a potential novel targ

154 of AMPK, failed to activate AMPK and sustain energy homeostasis and resulted in apoptosis.

155 mechanistic insights into how UGN influences energy homeostasis and suggests that UGN action in the b

156 orm of thermogenic cell that is required for energy homeostasis and survival.

157 roglia metabolism adapts to changes in brain energy homeostasis and that metabolic reprogramming regu

158 The intestinal microbiome can regulate host energy homeostasis and the development of metabolic dise

159 al pathways as key factors in the control of energy homeostasis and the resistance to DIO.

160 ck mechanism that controls crosstalk between energy homeostasis and the vitamin D pathway.

161 results indicate that plasma uridine governs energy homeostasis and thermoregulation in a mechanism i

162 ds in lipid droplets (LDs) are essential for energy homeostasis and tightly coupled to cellular metab

163 metabolic dysfunction suggests a failure of energy homeostasis and/or oxidative stress, specifically

164 lipids that participate in innate immunity, energy homeostasis, and brain development/function.

165 an important role in xenobiotic metabolism, energy homeostasis, and cell proliferation.

166 c stress is pivotal for maintaining systemic energy homeostasis, and dysregulation of this metabolic

167 its profound effects on oxygen utilization, energy homeostasis, and glucose metabolism in mammalian

168 gut-derived GLP-1's effects on food intake, energy homeostasis, and glycemic control.

169 lanocortin neurons known to regulate stress, energy homeostasis, and immune functions are reported to

170 , insulin acts as a growth factor, regulates energy homeostasis, and is involved in learning and memo

171 ificant long-term effects on somatic growth, energy homeostasis, and metabolic function in offspring.

172 major nutrient-sensing mechanism involved in energy homeostasis, and protein translation.

173 MENTATION1-RELATED KINASE1 involved in sugar/energy homeostasis, and the posttranslational regulation

174 They are critical for lipid metabolism and energy homeostasis, and their dysfunction has been linke

175 e that the effects of FTO-associated SNPs on energy homeostasis are due in part to the effects of the

176 ayers that maintain neuronal coordination of energy homeostasis are identified.

177 ral connections with neurons, their roles in energy homeostasis are less known.

178 that other GPCRs involved in the control of energy homeostasis are likely to be regulated by MRAP2.

179 While the neural circuits controlling energy homeostasis are well-characterized, the signals c

180 potential for ambient temperature to affect energy homeostasis as well as adrenergic stress, both of

181 essential roles in fatty acid catabolism and energy homeostasis as well as cell differentiation, infl

182 tant role in disrupting feeding behavior and energy homeostasis as well as in the pathogenesis of obe

183 that proliferating cells require to maintain energy homeostasis as well as to build plasma membranes

184 f the key hypothalamic neurons in control of energy homeostasis assigns noradrenalin an important rol

185 ng adropin, a peptide hormone encoded by the energy homeostasis-associated (ENHO) gene, to biological

186 tide adropin encoded by the clock-controlled energy homeostasis-associated gene is implicated in the

187 oratory settings, neural systems involved in energy homeostasis bias foraging to maximize energy effi

188 point to links between sleep regulation and energy homeostasis, but mechanisms underlying these conn

189 nic stress causes dysregulations of mood and energy homeostasis, but the neurocircuitry underlying th

190 LDs are important in the maintenance of energy homeostasis, but the signaling mechanisms that st

191 and 4 receptors (MC3R and MC4R) can regulate energy homeostasis, but their respective roles especiall

192 ficant roles in the regulation of whole-body energy homeostasis, but they have not evolved to cope wi

193 several beneficial effects on metabolism and energy homeostasis by controlling size, enzymatic activi

194 plays a unique role in regulating whole-body energy homeostasis by dissipating energy through thermog

195 at Crtc and its binding partner CREB enhance energy homeostasis by stimulating the expression of shor

196 vated protein kinase (AMPK), which regulates energy homeostasis by suppressing anabolic and activatin

197 Here, we show that the control of energy homeostasis by the anorexigenic proopiomelanocort

198 astrointestinal system communicate to govern energy homeostasis, combined with emerging insights on t

199 Maintenance of energy homeostasis depends on the highly regulated stora

200 To maintain energy homeostasis during cold exposure, the increased e

201 within lysosomes, allowing cells to maintain energy homeostasis during nutrient depletion.

202 ng self-cannibalization to maintain cellular energy homeostasis during nutrient deprivation.

203 anscription is tightly regulated to maintain energy homeostasis during periods of feeding or fasting,

204 essential physiological functions including energy homeostasis, embryonic and postembryonic developm

205 The distinct role in whole-body energy homeostasis establishes the PKCdelta signalosome

206 ANCE STATEMENT Evolutionary pressure driving energy homeostasis favored detection and comparison of c

207 Energy homeostasis, food intake, and body weight are reg

208 The melanocortin receptors 3 and 4 control energy homeostasis, food-intake behavior, and correlated

209 nes with functions related to metabolite and energy homeostasis, glucose and insulin signaling and be

210 nd exposure to different nutrition influence energy homeostasis in a rat model.

211 detector of the internal metabolic state or energy homeostasis in addition to its classical function

212 but is fundamentally important for lipid and energy homeostasis in animals.

213 Although GPR55 has been linked to energy homeostasis in different organs, its specific rol

214 otein kinase (AMPK) is a master regulator of energy homeostasis in eukaryotes.

215 otein kinase (AMPK) is a master regulator of energy homeostasis in eukaryotes.

216 Estrogens act with leptin to regulate energy homeostasis in females.

217 Mechanistically, RANK rewires energy homeostasis in human and murine lung cancer cells

218 es and is crucial for regulating satiety and energy homeostasis in humans and animals.

219 but also regulate reproductive processes and energy homeostasis in invertebrates.

220 neurons known to be involved in feeding and energy homeostasis in mammals show conserved distributio

221 damental mechanisms controlling the cellular energy homeostasis in microalgal cells but also for deve

222 ill an important gap in our understanding of energy homeostasis in pregnancy.

223 munication is critical to control organismal energy homeostasis in response to temporal changes in fe

224 lopmental programming and disrupts offspring energy homeostasis in rodents.

225 AMPK maintains energy homeostasis in the cell by promoting catabolic an

226 fatty acids and is essential for maintaining energy homeostasis in the human body.

227 critical to maintain cellular metabolism and energy homeostasis in Tregs.

228 ulation disrupts mitochondrial integrity and energy homeostasis in vivo.

229 is highly expressed in tissues that regulate energy homeostasis, including adipose tissue, liver, and

230 ll as regions of the mouse brain involved in energy homeostasis, including hypothalamus and brainstem

231 t AMPK inhibitor and a critical regulator of energy homeostasis, including lipid and glucose metaboli

232 misalignment has sex-specific influences on energy homeostasis independent of behavioral/environment

233 ich AMPK could potentially maintain cellular energy homeostasis independently of Thr172 phosphorylati

234 ling blocks the influence of maternal HFD on energy homeostasis, inflammation, and hypothalamic and l

235 Signals of energy homeostasis interact closely with neural circuits

236 We review how signals of energy homeostasis interact with these regions to influe

237 Altered brain energy homeostasis is a key adaptation occurring in the

238 Maintaining energy homeostasis is crucial for the survival and healt

239 Maintenance of energy homeostasis is essential for cell survival.

240 , yet the contribution of endogenous ACBP in energy homeostasis is unknown.

241 Energy homeostasis is vital to all living organisms.

242 a vital role in controlling food intake and energy homeostasis; its activity is modulated by neurope

243 ellular survival depends upon maintenance of energy homeostasis, largely by AMP-activated protein kin

244 that MRAP2 is an important modulator of the energy homeostasis machinery that operates through the r

245 tein kinase (AMPK) as a central regulator of energy homeostasis, many exciting insights into its stru

246 olecular networks, how pathways that control energy homeostasis may affect cell fate decisions is lar

247 -10-regulated genes are involved in monocyte energy homeostasis, migration, and trafficking and in CD

248 the Mfn1 gene (Mfn1LKO) and monitored their energy homeostasis, mitochondrial function, and suscepti

249 f metabolism, pancreatic beta-cell function, energy homeostasis, mood and behaviour in several specie

250 ceptor expression in brain areas involved in energy homeostasis, namely the hypothalamus and brainste

251 olymorphisms in genes of key hormones of the energy homeostasis network that have been shown to predi

252 composition and play a critical role in the energy homeostasis of all tissues.

253 lta in mice, in turn, resulted in an altered energy homeostasis of osteoblasts, impaired mineralizati

254 To maintain energy homeostasis, orexigenic (appetite-inducing) and a

255 inase (AMPK), a master regulator of cellular energy homeostasis, partly mediates this effect through

256 ur data show that AHR contributes to hepatic energy homeostasis, partly through the regulation of FGF

257 control of reproduction (Rfrp and Kiss1) and energy homeostasis (Pomc, Npy, and Somatostatin) are reg

258 lting in impaired function of these critical energy homeostasis-regulating neurons.

259 However, the primary mediators that affect energy homeostasis remain ill defined.

260 R stress pathways underlie ATM regulation of energy homeostasis remains unclear.

261 reased muscle PLIN5 expression on whole-body energy homeostasis remains unclear.

262 Maintaining energy homeostasis requires coordinating physiology and

263 Energy homeostasis requires precise measurement of the q

264 kin-29 sleep and energy homeostasis roles map to a set of sensory neurons

265 r computational model based on intracellular energy homeostasis successfully recapitulated the depend

266 involving several neuropeptides that control energy homeostasis, suggesting that variations in the ge

267 AMPK is a crucial regulator of energy homeostasis that acts downstream of its upstream

268 fatty acids is essential to maintain overall energy homeostasis, the choice of a given metabolic path

269 leus (ARC), such as growth, reproduction and energy homeostasis, the developmental pathways and regul

270 spite the consensus that the brain regulates energy homeostasis, the neural adaptations governing obe

271 ction has been linked to the deregulation of energy homeostasis, the precise mechanism is poorly unde

272 odulates lipid metabolism and the control of energy homeostasis; therefore, PPARdelta agonists are pr

273 sive to a number of neuropeptides related to energy homeostasis; they were excited by the anorectic p

274 ortant role of ARC glia in the regulation of energy homeostasis through its interaction with distinct

275 Intestine contributes to energy homeostasis through the absorption, metabolism, a

276 n 2 (MRAP2) was previously shown to regulate energy homeostasis through the modulation of the activit

277 NPY/AgRP neuron activity and maintenance of energy homeostasis, thus providing new insight into the

278 he role of SLC13A5 from facilitating hepatic energy homeostasis to influencing hepatoma cell prolifer

279 phagy is essential for cellular survival and energy homeostasis under nutrient deprivation.

280 thereby tailor protein synthesis to maintain energy homeostasis under stress conditions.

281 egulate the hepatic acute phase response and energy homeostasis under stress conditions.

282 changes central to mechanisms of growth and energy homeostasis universal to hyperphagia-associated c

283 Maintaining energy homeostasis upon environmental challenges, such a

284 determined the role of LepRb(POA) neurons in energy homeostasis using cre-dependent viral vectors to

285 through which beige fat controls whole-body energy homeostasis via Ca(2+) cycling.

286 Neuronal sNPF was found to promote energy homeostasis via gut enterocyte sNPF receptors, wh

287 IEX-1 is a novel physiological regulator of energy homeostasis via its action in WAT.

288 meostasis via the paraventricular nuclei and energy homeostasis via the arcuate nuclei.

289 um unfolded protein response or balancing of energy homeostasis via the SNF1-RELATED PROTEIN KINASE1

290 cuate nucleus, one key center for control of energy homeostasis, via specific adeno-associated virus

291 While energy homeostasis was generally maintained following HI

292 heral energy stores and control of long-term energy homeostasis was indicated.

293 ppaB signaling in the control of glucose and energy homeostasis, we genetically inhibited this pathwa

294 ssion of genes involved in the regulation of energy homeostasis were found to relate to fetal growth

295 e main cause of obesity is a perturbation in energy homeostasis, whereby energy intake exceeds energy

296 espite the emerging importance of SLC13A5 in energy homeostasis, whether perturbation of SLC13A5 affe

297 s a key regulator of cellular and whole-body energy homeostasis, which acts to restore energy homoeos

298 GnRHL1 coordinates glycoprotein turnover and energy homeostasis with growth and sexual maturation, in

299 is a protein kinase involved in maintaining energy homeostasis within cells.

300 ntral to melanocortin-mediated regulation of energy homeostasis within the PVN.