Project description:Torpor and hibernation are extreme physiological adaptations of homeotherms associated with pro-longevity effects. Yet the underlying mechanisms of how torpor affects aging, and whether hypothermic and hypometabolic states can be induced to slow aging and increase health span, remain unknown. We demonstrate that the activity of a spatially defined neuronal population in the avMLPA, which has previously been identified as a torpor-regulating brain region, is sufficient to induce a torpor like state (TLS) in mice. Prolonged induction of TLS slows epigenetic aging across multiple tissues and improves health span. We isolate the effects of decreased metabolic rate, long-term caloric restriction, and decreased core body temperature (Tb) on blood epigenetic aging and find that the decelerating effect of torpor-like states on aging is mediated by decreased Tb. Taken together, our findings provide novel mechanistic insight into the decelerating effects of torpor and hibernation on aging and support the growing body of evidence that Tb is an important mediator of aging processes.

Project description:Torpor and hibernation are extreme physiological adaptations of homeotherms associated with pro-longevity effects. Yet the underlying mechanisms of how torpor affects aging, and whether hypothermic and hypometabolic states can be induced to slow aging and increase health span, remain unknown. We demonstrate that the activity of a spatially defined neuronal population in the avMLPA, which has previously been identified as a torpor-regulating brain region, is sufficient to induce a torpor like state (TLS) in mice. Prolonged induction of TLS slows epigenetic aging across multiple tissues and improves health span. We isolate the effects of decreased metabolic rate, long-term caloric restriction, and decreased core body temperature (Tb) on blood epigenetic aging and find that the decelerating effect of torpor-like states on aging is mediated by decreased Tb. Taken together, our findings provide novel mechanistic insight into the decelerating effects of torpor and hibernation on aging and support the growing body of evidence that Tb is an important mediator of aging processes.

Project description:Differential gene expression in a wide range of tissues including brown adipose tissue (BAT), liver, heart, hypothalamus, and skeletal muscle in hibernating arctic ground squirrels during multiple stages in torpor-arousal cycles compared to non-hibernating (post-reproductive) animals with illumina beadarray technology. Arctic Ground Squirrels were sampled at four stages of hibernation: early arousal denoted as EA (1-2 hrs after Tb cross 30¡C, n=4), late arousal denoted as LA (7-8 hrs after Tb cross 30¡C, n=4), early torpor denoted as ET (10-20% of torpid episode, n=4) and late torpor denoted as LT (80-90% of torpid episode, n=5), where Tb is the body temperature and the length of torpid episode is estimated from the previous torpor bout. Post-reproductive animals denoted as PR (n=7) were used as non-hibernating control. Five tissue types: brown adipose tissue (BAT), liver, heart, hypothalamus, and skeletal muscle were hybridized on two customized 700-gene beadarray platforms: 1A and 2A on 96-sample Illumina ArrayMatrix. The data of a pilot study involving brown adipose tissue (BAT), liver, and skeletal muscle on 16-sample Illumina BeadChip denoted as 16chip are also included in this series.

Project description:Homeotherms maintain a stable internal body temperature despite changing environments. During energy deficiency, some species can cease to defend their body temperature and enter a hypothermic and hypometabolic state known as torpor. Despite recent advances in our understanding of thermoregulation, the precise neurons that coordinate these profound thermoregulatory and metabolic changes remain largely unknown. Here, we demonstrate that estrogen-sensitive neurons in the medial preoptic area (MPA) are key drivers of hypothermia and hypometabolism in mice. We find that selectively activating estrogen-sensitive MPA neurons was sufficient to drive a coordinated depression of metabolic rate and body temperature similar to torpor, as measured by body temperature, physical activity, indirect calorimetry, heart rate, and brain activity. Inducing torpor with a prolonged fast revealed larger and more variable calcium transients from estrogen-sensitive MPA neurons during bouts of hypothermia. Finally, selective ablation of estrogen-sensitive MPA neurons demonstrated that these neurons are required for the full expression of fasting-induced torpor. Together, these findings suggest a role for estrogen-sensitive MPA neurons in directing the thermoregulatory and metabolic responses to energy deficiency.

Project description:Mammalian hibernators survive prolonged periods of cold and resource scarcity by temporarily modulating normal physiological functions, but the mechanisms underlying these adaptations are poorly understood. The hibernation cycle of thirteen-lined ground squirrels lasts for 5–7 months and comprises weeks of hypometabolic, hypothermic torpor interspersed with 24–48-hour periods of an active-like interbout arousal (IBA) state. We show that ground squirrels, who endure the entire hibernation season without food, have negligible hunger drive during IBAs. We further demonstrate that squirrels exhibit reversible inhibition of the hypothalamic feeding center, such that hypothalamic arcuate nucleus neurons have reduced sensitivity to the orexigenic and anorexigenic effects of ghrelin and leptin, respectively. However, hypothalamic infusion of thyroid hormone during an IBA is sufficient to rescue hibernation anorexia. Our results reveal that thyroid hormone deficiency underlies hibernation anorexia and demonstrate the functional flexibility of the hypothalamic feeding center.

Project description:The advent of endothermy more than a hundred million years ago is thought to have been a defining feature of mammalian and avian evolution, achieved through continuous fine-tuned homeostatic regulation of core body temperature and metabolism. However, when challenged by food deprivation or harsh environmental conditions, many mammalian species initiate adaptive energy-conserving survival strategies, including torpor and hibernation, during which their core body temperature decreases far below its homeostatic setpoint. How homeothermic mammals initiate and regulate these extraordinary hypothermic states remains largely unknown. Here, we discover that entry into mouse torpor, a fasting-induced state with greatly decreased metabolic rate and body temperature as low as 20°C, is regulated by a population of neurons in the preoptic area of the hypothalamus. We show that re-stimulation of neurons activated during a previous bout of torpor is sufficient to initiate torpor, even in animals that are not calorically restricted. We localize these torpor-regulating neurons to the anteroventral medial and lateral preoptic area and molecularly identify a population of glutamatergic Adcyap1+ neurons whose activity accurately determines when calorically-restricted animals naturally initiate and exit torpor, and whose inhibition disrupts the natural process of torpor entry, maintenance and arousal. Taken together, we discover a specific hypothalamic neuronal subpopulation in the mouse brain that serves as a core regulator of torpor. This work forms the basis for future explorations of mechanisms and circuitry regulating extreme hypothermic and hypometabolic states, enabling genetic access to monitor, initiate, manipulate and study these ancient adaptations of homeotherm biology.

Project description:Thirteen-lined ground squirrels (Ictidomys tridecemlineatus) hibernate for several months each winter without access to water, but the mechanisms that maintain fluid homeostasis during hibernation are poorly understood. In torpor, when body temperature (TB) reaches 4°C, squirrels decrease metabolism, slow heart rate, and reduce plasma levels of the antidiuretic hormones arginine vasopressin (AVP) and oxytocin (OXT). Squirrels spontaneously undergo interbout arousal (IBA) every 2 weeks, temporarily recovering an active-like metabolism and a TB of 37°C for up to 48 h. Despite the low levels of AVP and OXT during torpor, profound increases in blood pressure and heart rate during the torpor-IBA transition are not associated with massive fluid loss, suggesting the existence of a mechanism that protects against diuresis at a low TB. Here, we demonstrate that the antidiuretic hormone release pathway is activated by hypothalamic supraoptic nucleus (SON) neurons early in the torpor-arousal transition. SON neuron activity, dense-core vesicle release from the posterior pituitary, and plasma hormone levels all begin to increase before TB reaches 10°C. In vivo fiber photometry of SON neurons from hibernating squirrels, together with RNA sequencing and c-FOS immunohistochemistry, confirms that SON is electrically, transcriptionally, and translationally active to monitor blood osmolality throughout the dynamic torpor-arousal transition. Our work emphasizes the importance of the antidiuretic pathway during the torpor-arousal transition and reveals that the neurophysiological mechanism that coordinates the hormonal response to retain fluid is active at an extremely low TB, which is prohibitive for these processes in non-hibernators.

Project description:Comparative transcriptomics of the garden dormouse hypothalamus during early torpor, late torpor and interbout arousal of hibernation

Project description:Mammalian hibernators display phenotypes similar to physiological conditions in non-hibernating species under conditions of calorie restriction and fasting, hypoxia, hypothermia, ischemia-reperfusion, and sleep. However, whether or how similarities are also reflected on molecular and genetic levels is unclear. We identified molecular signatures of torpor and arousal in hibernation using a new custom-designed cDNA microarray for the arctic ground squirrel (Urocitellus parryii,) and compared them to molecular signatures of selected phenotypes in mouse. Our results show that differential gene expression related to metabolism during torpor is closely related to that during calorie restriction and hypoxia. PPARM-NM-1 is crucial for metabolic remodeling in hibernation. Genes related to the sleep-wake cycle and temperature response genes induced by hypothermia follow the same expression changes as in torpor-arousal cycle. Increased fatty acid metabolism might contribute to the protection against ischemia-reperfusion injury during hibernation. Further, by comparing with thousands of pharmacological signatures, we identified drugs that may induce similar expression patterns in human cell lines as during hibernation. Arctic ground squirrels sampled during winter hibernation were compared with the animals sampled during summer. Liver was hybridized on a custom 9,600 probes nylon membrane microarray platform. Four squirrels in early torpor, five in late torpor, four in early arousal, four in late arousal, and seven in summer active were studied in experiments.

Project description:During the winter, hibernating mammals undergo extreme changes in physiology which allow them to survive without access to food. These animals enter a state of torpor, which is characterized by a decreased metabolism, near-freezing body temperatures, and a dramatically reduced heart rate. The neurochemical basis of this regulation is largely unknown. Based on prior evidence suggesting that the peptide-rich hypothalamus plays critical roles in hibernation, we hypothesized that changes in specific cell-cell signaling peptides (neuropeptides and peptide hormones) underlie physiological changes during torpor/arousal cycles. To test this hypothesis, we used a mass spectrometry-based peptidomics approach to examine seasonal changes of endogenous peptides that occur in the hypothalamus and pituitary of a model hibernating mammal, the thirteen-lined ground squirrel (Ictidomys tridecemlineatus). In the pituitary, we observed changes in a number of distinct peptide hormones as animals prepare for torpor in October, exit torpor in March, and progress from Spring (March) to Fall (August). In the hypothalamus, we observed an overall increase in neuropeptides in October (pre-torpor), a decrease as the animal enters torpor, and an increase in a subset of neuropeptides during normothermic interbout arousals. Notable changes were observed for feeding regulatory peptides from NPY and proSAAS prohormones, opioid peptides from PENK, PDYN, and POMC prohormones, and a number of peptides without well-established functions. In contrast to transcriptome and antibody-based measurements, our mass spectrometry-based approach allowed the identification and measurement of the final processed forms of these peptides after extensive post-translational modifications. Overall, our study provides critical insight into changes in endogenous peptides in the hypothalamus and pituitary during mammalian hibernation that were not available from transcriptome measurements. Understanding the molecular basis underlying the hibernation phenotype may pave the way for future efforts to employ hibernation-like strategies for organ preservation, combating obesity, and treatments for stroke.