Project description:Hibernating mammals undergo a dramatic drop in temperature and blood flow during torpor and must suppress hemostasis to avoid stasis blood clotting. In addition, cold storage of most mammalian platelets induces cold storage lesions, resulting in rapid clearance following transfusion. 13-lined ground squirrels (Ictidomys tridecemlineatus) provide a model to study hemostasis and cold storage of platelets during hibernation because, even with a body temperature of 4-8C, their platelets are resistant to cold storage lesions. We quantified and systematically compared proteomes of platelets collected from ground squirrels at summer (activity), fall (entrance), and winter (topor) to elucidate how molecular-level changes in platelets may support hemostatic adaptations in torpor. Platelets were isolated from squirrel blood collected in June, October, and January. Platelet lysates from each animal were digested with trypsin prior to 11-plex tandem mass tag (TMT) labeling, followed by LC-MS/MS analysis for relative protein quantification. We found over 700 platelet proteins with significant changes over the course of entrance, torpor, and activity – including systems of proteins regulating translation, platelet degranulation, metabolism, complement, and coagulation cascades. We also noted species specific differences in hemostatic, secretory, and inflammatory regulators in ground squirrel platelets relative to human platelets. In addition to providing the first ever proteomic characterization of platelets from hibernating animals, our results support a model whereby systematic changes in metabolic, hemostatic, and other proteins support physiological adaptations in torpor. In addition, our results could translate into better methods to cold store human platelets, increasing their supply and quality for transfusions.

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:The ADAR RNA editing enzymes deaminate adenosine bases to inosines in cellular RNAs, recoding open reading frames. Human ADAR1 mutations cause Aicardi-Goutieres Syndrome (AGS) and Adar1 mutant mice showing an aberrant interferon response and death by embryonic day E12.5 model the human disease. Searches have not identified key ADAR1 RNA editing sites recoding immune/haematopoietic proteins but editing is widespread in Alu sequences. We show that Adar1 embryonic lethality is rescued in Adar1; Mavs double mutant mice in which general antiviral responses to cytoplasmic dsRNA are prevented. We propose that inosine bases are epigenetic marks identifying cellular RNA as innate immune ÒselfÓ. Consistent with this idea we show that an editing-active cytoplasmic ADAR is required to prevent aberrant immune responses in Adar1 mutant mouse embryo fibroblasts. No dramatic increase in repetitive transcripts is observed. AGS mutations in ADAR1 affect editing by the interferon-inducible cytoplasmic ADAR1 isoform. RNA-seq expression profiling in Adar1 and Adar1/Mavs knockout mice embryos.

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:RNA editing by adenosine deamination is well-positioned to diversify proteomes, but it is infrequently used for this purpose. Recent reports have suggested that squid may be an exception. We show that extensive recoding by RNA editing is an invention of the behaviorally sophisticated coleoid cephalopods, with tens of thousands of evolutionarily conserved sites. Editing is enriched in the nervous system and targets excitability and neuronal morphology. Many edited codons are translated into protein and in some cases cause functional changes. The genomic sequence flanking these sites is highly conserved to maintain the structures required for editing, suggesting that the process confers a selective advantage. Due to the large number of sites, the surrounding conservation greatly reduces the number of mutations and genomic polymorphisms that accumulate in protein coding regions. This trade-off between genome evolution and transcriptome plasticity highlights the importance of RNA recoding as a novel strategy for neural complexity.

Project description:We hypothesised that induction of a torpor-like state would confer a radioprotective effect given the evidence that hibernation extends survival times in irradiated squirrels compared to active controls. To test this hypothesis, a torpor-like state was induced in zebrafish using melatonin treatment and cold temperature, and radiation exposure was administered twice over the course of 10 days. The protective effects of induced-torpor were assessed via RNA sequencing of mRNA extracted from the GIT. A systems level analysis was performed on the transcriptomic data to characterise the cellular phenotypes in radiation, torpor, and torpor+radiation groups. The results revealed that melatonin and cold temperature successfully induced a torpor-like state in zebrafish as shown by decreased metabolism and activity levels. Low dose radiation caused DNA damage and oxidative stress triggering a stress response, including steroidal signalling and changes to metabolism, damage to the central nervous system and cell cycle arrest. This stress response was attenuated in the torpor+radiation group by an increase in biosynthesis, proliferation, cell survival signals and expression of genes involved in protection against the adverse effects of radiation, particularly in neurons, suggesting a radioprotective effect conferred by a torpor state. This proof-of-concept model provides compelling initial evidence for utilizing an induced torpor-like state as a potential countermeasure for radiation exposure.

Project description:We hypothesised that induction of a torpor-like state would confer a radioprotective effect given the evidence that hibernation extends survival times in irradiated squirrels compared to active controls. To test this hypothesis, a torpor-like state was induced in zebrafish using melatonin treatment and cold temperatures, and radiation exposure was administered twice over the course of 10 days. The protective effects of induced-torpor were assessed via RNA sequencing of mRNA extracted from the liver. A systems-level analysis was performed on the transcriptomic data to characterise the cellular phenotypes in radiation (28.5-rad), temperature+melatonin (18.5-mel), temperature+radiation (18.5-rad), and temperature+melatonin+radiation (18.5-mel-rad) groups compared with a control group (28.5-Ctrl). The results revealed that the torpor group experiences a reduction in metabolic genes, and increased pro-survival, antiapoptotic and DNA repair genes. The radiation group had changes to lipid metabolism and absorptions, a wound healing response and an immune response. While the induced torpor group showed a response to stress including changes to metabolism and perturbation of the circadian rhythm, it also maintained the pro-survival, anti-apoptotic and DNA repair genes seen in the torpor group suggesting a conferred radio-protective effect.

Project description:The ADAR RNA editing enzymes deaminate adenosine bases to inosines in cellular RNAs, recoding open reading frames. Human ADAR1 mutations cause Aicardi-Goutieres Syndrome (AGS) and Adar1 mutant mice showing an aberrant interferon response and death by embryonic day E12.5 model the human disease. Searches have not identified key ADAR1 RNA editing sites recoding immune/haematopoietic proteins but editing is widespread in Alu sequences. We show that Adar1 embryonic lethality is rescued in Adar1; Mavs double mutant mice in which general antiviral responses to cytoplasmic dsRNA are prevented. We propose that inosine bases are epigenetic marks identifying cellular RNA as innate immune ÒselfÓ. Consistent with this idea we show that an editing-active cytoplasmic ADAR is required to prevent aberrant immune responses in Adar1 mutant mouse embryo fibroblasts. No dramatic increase in repetitive transcripts is observed. AGS mutations in ADAR1 affect editing by the interferon-inducible cytoplasmic ADAR1 isoform.

Project description:Hibernation enables many species of the mammalian kingdom to overcome periods of harsh environmental conditions. During this physically inactive state metabolic rate and body temperature are drastically downregulated, thereby reducing energy requirements (torpor) also over shorter time periods. Since blood cells reflect the organism's current condition, it was suggested that transcriptomic alterations in blood cells mirror the torpor-associated physiological state. Transcriptomics on blood cells of torpid and non-torpid Djungarian hamsters and QIAGEN Ingenuity Pathway Analysis (IPA) revealed key target molecules (TMIPA), which were subjected to a comparative literature analysis on transcriptomic alterations during torpor/hibernation in other mammals. Gene expression similarities were identified in 148 TMIPA during torpor nadir among various organs and phylogenetically different mammalian species. Based on TMIPA, IPA network analyses corresponded with described inhibitions of basic cellular mechanisms and immune system-associated processes in torpid mammals. Moreover, protection against damage of heart, kidney, and liver was deduced from this gene expression pattern in blood cells. This study shows that blood cell transcriptomics can reflect the general physiological state during torpor nadir. Furthermore, the understanding of molecular processes for torpor initiation and organ preservation may have beneficial implications for humans in extremely challenging environments, such as in medical intensive care units and in space.

Project description:Torpor is an energy-conserving state in which animals dramatically decrease their metabolic rate and body temperature to survive harsh environmental conditions. Here, we report the noninvasive, precise, and safe induction of a torpor-like hypothermic and hypometabolic state in rodents by remote transcranial ultrasound stimulation at the hypothalamus preoptic area (POA). We achieve a long-lasting (> 24 hours) torpor-like state in mice via closed-loop feedback control of ultrasound stimulation with automated detection of body temperature. Ultrasound-induced hypothermia and hypometabolism (UIH) is triggered by activation of POA neurons, involves the dorsomedial hypothalamus as a downstream brain region and subsequent inhibition of thermogenic brown adipose tissue. Single-nucleus RNA-sequencing of POA neurons reveals TRPM2 as an ultrasound-sensitive ion channel, the knockdown of which suppresses UIH. We also demonstrate that UIH is feasible in a non-torpid animal, the rat. Our findings establish UIH as a promising technology for the noninvasive and safe induction of a torpor-like state. To investigate the mechanism of ultrasound-induced neuronal activation, we applied ultrasound stimulation in hypothalamic preoptic area region and performed single-nuclei RNA sequencing in the ultrasound stimulated neurons (US+) and neurons without ultrasound stimulation (US-). In our sn-RNAseq analysis, we examined the association between the expression of neuronal activation markers (or IEGs) and ion channels, as well as neuron types.