Hibernation confers resistance to intestinal ischemia-reperfusion injury

The damaging effects of intestinal ischemia-reperfusion (I/R) on the gut and remote organs can be attenuated by subjecting the intestine to a prior, less severe I/R insult, a process known as preconditioning. Because intestines of hibernating ground squirrels experience repeated cycles of hypoperfusion and reperfusion, we examined whether hibernation serves as a model for natural preconditioning against I/R-induced injury. We induced intestinal I/R in either the entire gut or in isolated intestinal loops using rats, summer ground squirrels, and hibernating squirrels during natural interbout arousals (IBA; body temperature 37-39 degrees C). In both models, I/R induced less mucosal damage in IBA squirrels than in summer squirrels or rats. Superior mesenteric artery I/R increased MPO activity in the gut mucosa and lung of rats and summer squirrels and the liver of rats but had no effect in IBA squirrels. I/R in isolated loops increased luminal albumin levels, suggesting increased gut permeability in rats and summer squirrels but not IBA squirrels. The results suggest that the hibernation phenotype is associated with natural protection against intestinal I/R injury.     

Ubiquitin conjugate dynamics in the gut and liver of hibernating ground squirrels

Protein synthesis is severely depressed in hibernating mammals. In the absence of significant protein synthesis, the continued turnover of proteins as a function of normal cellular activity would result in the net depletion of protein pools. We measured levels of ubiquitylated proteins in the gut of thirteen-lined ground squirrels ( Spermophilus tridecemlineatus) and liver of golden-mantled ground squirrels ( Spermophilus lateralis). In both tissues, ubiquitin conjugate concentrations increased during entrance into torpor and were elevated 2-3 fold by late torpor compared with levels in active animals. The data are consistent with a depression of proteolysis with a resultant high level of ubiquitylated proteins during the natural hypothermia of torpor. The periodic returns to euthermy during the hibernation season allow for degradation of these conjugated proteins and may serve to restore protein pools.     

Natural resistance to liver cold ischemia-reperfusion injury associated with the hibernation phenotype

The success of liver grafts is currently limited by the length of time organs are cold preserved before transplant. Novel insights to improve viability of cold-stored organs may emerge from studies with animals that naturally experience low body temperatures (T(b)) for extended periods. In this study, we tested whether livers from hibernating ground squirrels tolerate cold ischemia-warm reperfusion (cold I/R) for longer times and with better quality than livers from rats or summer squirrels. Hibernators were used when torpid (T(b) < 10 degrees C) or aroused (T(b) = 37 degrees C). Livers were stored at 4 degrees C in University of Wisconsin solution for 0-72 h and then reperfused with 37 degrees C buffer in vitro. Lactate dehydrogenase (LDH) release after 60 min was increased 37-fold in rat livers after 72 h cold I/R but only 10-fold in summer livers and approximately three- to sixfold in torpid and aroused hibernator livers, despite twofold higher total LDH content in livers from hibernators compared with rats or summer squirrels. Reperfusion for up to 240 min had the least effect on LDH release in livers from hibernators and the greatest effect in rats. Compared with rats or summer squirrels, livers from hibernators after 72 h cold I/R showed better maintenance of mitochondrial respiration, bile production, and sinusoidal lining cell viability, as well as lower vascular resistance and Kupffer cell phagocytosis. These results demonstrate that the hibernation phenotype in ground squirrels confers superior resistance to liver cold I/R injury compared with rats and summer squirrels. Because hibernation-induced protection is not dependent on animals being in the torpid state, the mechanisms responsible for this effect may provide new strategies for liver preservation in humans.     

Blood Plasma Phospholipids and Cholesterol during Hibernation of the Long-Tailed Ground Squirrel

Seasonal changes in the levels of phospholipids, diglycerides, cholesterol, and total protein in the blood plasma were investigated during hibernation of the long-tailed ground squirrel Spermophilus undulatus. During the winter period, the levels of phosphatidylcholine, phosphatidylinositol, phosphatidylethanolamine, lysophosphatidylcholine, and sphingomyelin phospholipids (per 1 mg of plasma protein) were increased in both torpid and active ground squirrels by 70–80, 50, 600–700, 70, and 150–200%, respectively; the level of phosphatidylserine did not change in comparison to the summer period. The plasma phospholipid composition differed between hibernating and active summer animals: in winter, the phosphatidylcholine mol % decreased by 20%, phosphatidylinositol and phosphatidylethanolamine increased by 3–4 times, and the phosphatidylserine mol % decreased by 50%, while sphingomyelin and lysophosphatidylcholine did not change in comparison to summer animals. In hibernating ground squirrels, the plasma cholesterol levels increased by two times, the diglyceride content diminished by 60%, and the level of protein (in milligrams per 1 mL plasma) increased by 20%. The simultaneous increase in the levels of cholesterol and total phospholipids, as well as the pronounced specific changes in the levels of individual phospholipids in the blood plasma of hibernating ground squirrels, indicate the involvement of plasma lipoprotein lipids in the molecular mechanisms of adaptation to natural hypobiosis in mammals and a possible role of these mechanisms in systemic reactions to damaging factors.     

Seasonal Changes in Microsomal Fraction Enriched with Na,K-ATPase from Kidneys of the Ground Squirrel <Emphasis Type="Italic">Spermophilus undulatus</Emphasis>

The Na,K-ATPase activity in microsomal fraction isolated from kidneys of winter hibernating ground squirrels was found to be 1.8–2.0-fold lower than that in active animals in summer. This is partially connected with a decrease in Na,K-ATPase protein content in these preparations (by 25%). Using antibodies to different isoforms of Na,K-ATPase α-subunit and analysis of enzyme inhibition by ouabain, it was found that the decrease in Na,K-ATPase activity during hibernation is not connected with change in isoenzyme composition. Seasonal changes of Na,K-ATPase a-subunit phosphory- lation level by endogenous protein kinases were not found. Proteins which could be potential regulators of Na,K-ATPase activity were not found among phosphorylated proteins of the microsomes. Analysis of the composition and properties of the lipid phase of microsomes showed that the total level of unsaturation of fatty acids and the lipid/protein ratio are not changed significantly during hibernation, whereas the cholesterol content in preparations from kidneys of hibernating ground squirrels is approximately twice higher than that in preparations from kidneys of active animals. However, using spin and fluorescent probes it was shown that this difference in cholesterol content does not affect the integral membrane micro-viscosity of microsomes. Using the cross-linking agent cupric phenanthroline, it was shown that Na,K-ATPase in mem- branes of microsomes from kidneys of hibernating ground squirrels is present in more aggregated state in comparison with membranes of microsomes from kidneys of active animals. We suggest that the decrease in Na,K-ATPase activity in kidneys of ground squirrels during hibernation is mainly connected with the aggregation of proteins in plasma membrane.     

Isolation of a Hibernation Inducing Trigger(s) From the Plasma of Hibernating Woodchucks

Plasma from hibernating woodchucks was desalted utilizing a hollow fiber device having a M. W. cut-off of 5, 000. This preparation was fractionated by isoelectric focusing (IEF) in a pH gradient extending from 3. 5 to 10. 0 resulting in protein components having isoelectric points (pis) of 4. 5, 5. 2, 5. 5, 6. 3, and 7. O. Fraction I (comprised of proteins having pis of 4. 5 and 5. 2) induced hibernation within 2 to 6 days in 8 out of 10 summer-active ground squirrels. Fraction II (pI 5. 5) and Fraction III (pi 6. 3 and 7. 0) failed to induce any summer hibernation in 10 animal test groups at identical sample concentrations. Polyacrylamide gel electrophoresis of Fraction I indicated that albumin was a major constituent of this still heterogeneous preparation.

Thus, in order to more clearly define the plasma locus of this hibernation inducing trigger(s) (HIT) molecule, whole plasma and/or Fraction I was fractionated by 3 distinct resolving techniques. These included sub-fractionation of Fraction I by isoelectric focusing utilizing a narrower pH gradient extending from 3. 5 to 6. 0, isotachophoresis of whole plasma and affinity chromatography of Fraction I and whole plasma. A total of 40 summer-active ground squirrels were injected and assayed for HIT activity with fractionated preparations derived by the three previously cited separation techniques. A total of 18 of these summer-active ground squirrels hibernated. However, a much more impressive figure is that 16 out of 21 animals hibernated when Injected with resolved hibernating plasma fractions in which albumin was the predominant plasma protein. A total of 8 control animals were injected with vehicle and none of these hibernated.     

Membrane lipids and morphology of brain cortex synaptosomes isolated from hibernating Yakutian ground squirrel

Synaptosomes were isolated from Yakutian ground squirrel brain cortex of summer and winter hibernating animals in active and torpor states. Synaptosomal membrane cholesterol and phospholipids were determined. The seasonal changes of synaptosomal lipid composition were found. Synaptosomes isolated from hibernating Yakutian ground squirrel brain cortex maintained the cholesterol sphingomyelin, phosphatidylethanolamine, lysophosphatidylcholine, cardiolipin, phosphatidylinositol and phosphatidylserine contents 2.5, 1.8, 2.6, 1.8, 1.6, and 1.3 times less, respectively, and the content of phosphatidylcholine twice as much as the one in summer season. The synaptosomal membrane lipid composition of summer animals was shown to be markedly different from that as hibernating ground squirrels and non-hibernating rodents. It is believed that phenotypic changes of synaptosomal membrane lipid composition in summer Yakutian ground squirrel are the important preparation step for hibernation. The phosphatidylethanolamine content was increased in torpor state compared with winter-active state and the molar ratio of cholesterol/phospholipids in synaptosomal membrane of winter torpor ground squirrels was lower than that in active winter and summer animals. These events were supposed to lead to increase of the synaptosomal membrane fluidity during torpor. Synaptosomes isolated from torpor animals have larger sizes and contain a greater number of synaptic vesicles on the synaptosomal profile area. The synaptosomal membrane lipid composition and synaptosome morphology were involved in phenotypic adaptation of Yakutian ground squirrel to hibernation.     

Isolation of a hibernation inducing trigger(s) from the plasma of hibernating woodchucks

Plasma from hibernating woodchucks was desalted utilizing a hollow fiber device having a M. W. cut-off of 5,000. This preparation was fractionated by isoelectric focusing (IEF) in a pH gradient extending from 3.5 to 10.0 resulting in protein components having isoelectric points (pIs) of 4.5, 5.2, 5.5, 6.3, and 7.0. Fraction I (comprised of proteins having pIs of 4.5 and 5.2) induced hibernation within 2 to 6 days in 8 out of 10 summer-active ground squirrels. Fraction II (pI 5.5) and Fraction III (pI 6.3 and 7.0) failed to induce any summer hibernation in 10 animal test groups at identical sample concentrations. Polyacrylamide gel electrophoresis of Fraction I indicated that albumin was a major constituent of this still heterogeneous preparation. Thus, in order to more clearly define the plasma locus of this hibernation inducing trigger(s) (HIT) molecule, whole plasma and/or Fraction I was fractionated by 3 distinct resolving techniques. These included sub-fractionation of Fraction I by isoelectric focusing utilizing a narrower pH gradient extending from 3.5 to 6.0, isotachophoresis of whole plasma and affinity chromatography of Fraction I and whole plasma. A total of 40 summer-active ground squirrels were injected and assayed for HIT activity with fractionated preparations derived by the three previously cited separation techniques. A total of 18 of these summer-active ground squirrels hibernated. However, a much more impressive figure is that 16 out of 21 animals hibernated when injected with resolved hibernating plasma fractions in which albumin was the predominant plasma protein. A total of 8 control animals were injected with vehicle and none of these hibernated.     

Hibernation reduces pancreatic amylase levels in ground squirrels

Pancreatic enzyme levels in mammals are influenced by food intake and dietary composition. In this study, we examined the activity and expression of pancreatic amylase in a hibernating mammal, a natural model for long-term fasting. Pancreatic tissues were obtained from summer-active 13-lined ground squirrels and hibernating squirrels that had not eaten for at least 6 weeks. Amylase specific activity was reduced by approximately 50% in the torpid hibernators compared with summer squirrels, and immunoblot analysis revealed that amylase protein expression was reduced by approximately 40% in the hibernators. Similar reductions in amylase specific activity were observed in interbout euthermic hibernators. These results support a strong influence of food intake on pancreatic enzyme expression in hibernating mammals. The maintenance of basal levels of this key digestive enzyme at approximately 50% of summer values despite the extended winter fast likely facilitates the rapid resumption of digestive function after terminal arousal in the spring.     

The "hibernation induction trigger": specificity and validity of bioassay using the 13-lined ground squirrel

Even though the existence of the blood-borne "hibernation induction trigger" has been reported in the 13-lined ground squirrel, transfusion of plasma from hibernating rodents with other hibernating species as the recipients failed to induce the occurrence of summer hibernation. In order to verify whether the response to the "trigger" substance is species specific, the present study was carried out to compare the effect of plasma from hibernating Richardson's ground squirrels on the incidence of summer hibernation in both juvenile Richardson's and adult 13-lined ground squirrels. In two series of experiments, 13-lined ground squirrels entered hibernation quite readily independent of the treatment. The rate of occurrence of hibernation ranged from 78% after sham injection to 86% after warm saline, fresh summer active plasma, and fresh hibernating plasma, respectively. There were no differences in the number of hibernation bouts and the number of days in hibernation after each treatment. In contrast, none of the juvenile Richardson's ground squirrels entered hibernation after any of the treatments up to the end of the 8-week observation period. These results not only argue against the existence of blood-borne "trigger" substance, at least in the Richardson's ground squirrel, but also caution against the use of the 13-lined ground squirrel as a standard test animal for the bioassay of the "trigger" substance.     

Phospholipids of liver cell nuclei during hibernation of Yakutian ground squirrel

In hibernating Yakutian ground squirrels S. undulatus, the content of total phospholipids in the nuclei of liver increased by 40% compared to that in animals in summer. In torpid state, the amount of sphingomyelin increased almost 8 times; phosphatidylserine, 7 times; and cardiolipin, 4 times. In active “winter” ground squirrels, the amount of sphingomyelin, phosphatidylserine, and cardiolipin decreased compared to the hibernating individuals but remained high compared to the “summer” ones. The torpor state did not affect the amount of lysophosphatidylcholine and phosphatidylinositol.     

Impaired Skeletal Muscle Regeneration in the Absence of Fibrosis during Hibernation in 13-Lined Ground Squirrels

Skeletal muscle atrophy can occur as a consequence of immobilization and/or starvation in the majority of vertebrates studied. In contrast, hibernating mammals are protected against the loss of muscle mass despite long periods of inactivity and lack of food intake. Resident muscle-specific stem cells (satellite cells) are known to be activated by muscle injury and their activation contributes to the regeneration of muscle, but whether satellite cells play a role in hibernation is unknown. In the hibernating 13-lined ground squirrel we show that muscles ablated of satellite cells were still protected against atrophy, demonstrating that satellite cells are not involved in the maintenance of skeletal muscle during hibernation. Additionally, hibernating skeletal muscle showed extremely slow regeneration in response to injury, due to repression of satellite cell activation and myoblast differentiation caused by a fine-tuned interplay of p21, myostatin, MAPK, and Wnt signaling pathways. Interestingly, despite long periods of inflammation and lack of efficient regeneration, injured skeletal muscle from hibernating animals did not develop fibrosis and was capable of complete recovery when animals emerged naturally from hibernation. We propose that hibernating squirrels represent a new model system that permits evaluation of impaired skeletal muscle remodeling in the absence of formation of tissue fibrosis.     

Modulation of apoptotic pathways in intestinal mucosa during hibernation

Mammalian hibernation is associated with several events that can affect programmed cell death (apoptosis) in nonhibernators, including marked changes in blood flow, extended fasting, and oxidative stress. However, the effect of hibernation on apoptosis is poorly understood. Here, we investigated apoptosis and expression of proteins involved in apoptotic pathways in intestinal mucosa of summer and hibernating ground squirrels. We used terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling (TUNEL) to identify possible apoptotic enterocytes in small intestine of summer squirrels and hibernating squirrels throughout the winter. Nuclear TUNEL staining increased as hibernation progressed, but the staining pattern was diffuse and not accompanied by chromatin condensation or apoptotic bodies. Electrophoresis of mucosal DNA revealed no ladders typical of apoptosis. Nuclear levels of proapoptotic p53 protein were fourfold less in hibernators compared with summer squirrels. A 12-fold increase in anti-apoptotic Bcl-x(L) compared with a 2-fold increase in proapoptotic Bax suggested a balance in favor of antiapoptotic signaling in hibernators. There was no change in Bcl-2 protein expression but phospho-Bcl-2 increased in mucosa of hibernators. Hibernation had minimal effects on expression of active caspase-8 or -9, whereas caspase-3-specific activity was lower in hibernators during an interbout arousal compared with summer squirrels. Expression of the prosurvival protein Akt increased 20-fold during hibernation, but phospho-Akt was not altered. These data provide evidence for enhanced expression of antiapoptotic proteins during hibernation that may promote enterocyte survival in a pro-oxidative, proapoptotic environment.     

Biosynthesis of dolichyl pyrophosphate N-acetylglucosaminyl intermediates in liver microsomes from hibernating ground squirrels (Citellus citellus L.)

Dolichyl pyrophosphate N-acetyl[14C]glucosamine was synthesized after incubation of liver microsomes from hibernating ground squirrels with UDP-N-acetyl[14C )glucosamine. The radioactivity of glycolipid formed by liver microsomes from hibernating ground squirrels was about 2-fold greater than by liver microsomes from active animals. Addition of exogenous dolichyl phosphate to the incubation mixture increased the formation of dolichyl pyrophosphate N-acetyl[14C]glucosamine by microsomes from both active and hibernating ground squirrels about 6 times. Liver microsomes from hibernating ground squirrels converted dolichyl pyrophosphate N-acetyl[14C]glucosamine into dolichyl pyrophosphate N,N'-diacetyl[14C]chitobiose in the presence of unlabelled UDP-N-acetylglucosamine. This conversion was maximal at 1.0 M concentration of unlabelled UDP-N-acetylglucosamine. The level of dolichyl phosphate assessed by the level of dolichyl pyrophosphate N-acetylglucosamine formation was nearly 2 times greater in liver microsomes from hibernating ground squirrels than from active animals.     

The effect of medium tonicity on the rate of respiration and oxidative phosphorylation in liver mitochondria of active and hibernating ground squirrels

The rate of respiration and ATP synthesis in liver mitochondria (M) isolated from hibernating ground squirrels and incubated in the medium with normal tonicity (250 mosm) was shown to be considerably lower than the rate of respiration and ATP synthesis in liver M from active animals. The increase of the medium tonicity to 600 mosm simulated the state of M from hibernating animals, resulting in a decrease of the respiration rate of M from active ground squirrels. On the contrary, the decrease of the tonicity to 60 mosm caused the activation of the respiration and increase of the ATP synthesis in M from hibernating ground squirrels. Bromophenacylbromide (BPhB), an inhibitor of phospholipase A2, prevented the activation of the respiration of M from hibernating animals incubated in the medium with low tonicity. BPhB had practically no effect on the respiration of M from both hibernating and active ground squirrels as well as on the swelling of M in hypotonic medium. It was concluded that the activation of the respiration and increase of the ATP synthesis rate in M from hibernating ground squirrels incubated in the medium with low tonicity is related to the activation of phospholipase A2. It was assumed that decrease of phospholipase A2 activity and change in the lipid composition of mitochondrial membrane may be one of the reasons for inhibition of the respiration rate in M from hibernating ground squirrels.     

The intensity of oxidative phosphorylation and the function of the adenylate system in the liver mitochondria of active and hibernating susliks Citellus undulatus

The state of adenylate system and intensity of oxidative phosphorylation in liver mitochondria of active and hibernating ground squirrels were studied depending on the concentration of extramitochondrial Ca2+ ([Ca2+]ex). It was shown that at [Ca2+]ex.10(-7) M, the content of ATP as well as ATP/ADP ratio are slightly lower in the mitochondria of hibernating ground squirrels than in the mitochondria of active animals. The other parameters of the adenylate system under the same conditions differ insignificantly. [Ca2+]ex increase to 10(-6) M has little effect on the parameters of the adenylate system of active animals. On the contrary, the mitochondria of hibernating ground squirrels are strongly affected: the level of ATP is 1.5-fold and the ratio of ATP/ADP is almost 2-fold decreased. At both [Ca2+]ex the intensity of oxidative phosphorylation is essentially higher in the mitochondria of active ground squirrels. With increasing [Ca2+]ex the rate of ATP synthesis decreases, and in the mitochondria of hibernating animals the decrease is more pronounced than in the mitochondria of active animals. Thus, oxidative phosphorylation and adenylate system of mitochondria from hibernating ground squirrels are more sensitive to [Ca2+]ex increase than those of the mitochondria of active animals.     

Effect of ionizing radiation on the synthetic activity of blood system cells in ground squirrels in different physiological states of animals

The functional (synthetic) activity of blood lymphocytes and bone marrow haemopoietic cells in ground squirrels during the annual cycle as well as in hibernating and awaken animals in winter have been studied by fluorescent microspectrometry. The effect of ionizing radiation on animals in different functional states of the hibernation-arousal bout was investigated too. It was shown that the synthetic activity (parameter alpha) in blood lymphocytes was minimal in hibernating state in winter and maximal in active euthermic spring animals, then slightly decreased in June and more considerably decreased in the prehibernating autumn period. In awake animals in winter, the values of parameter alpha reached the same values as in summer. The changes of parameter alpha in bone marrow haemopoietic cells were essentially the same: the minimal values were observed in the prehibernation autumn period and in awake animals in winter the alpha values were slightly higher than in active euthermic animals in summer. The maximal synthetic activity in bone marrow haemopoietic cells in active euthermic spring animals is due mainly to cells in G1-G2 phases of the cell cycle. The decrease of the synthetic activity in summer is a result of the cell transition from G2 to mitosis and transition of a part of cells to G0 When investigating the hibernation-arousal bout in ground squirrels in winter, during arousal, we found two stages considerably differing in both the values of parameter alpha in bone marrow haemopoietic cells and the number of blood cells. The synthetic activity and the total number of blood and bone marrow cells in ground squirrels irradiated in the state of deep hibernation did not differ significantly from the state of non-irradiated hibernating animals. The negative effect of radiation appeared upon the arousal of these animals but it was expressed to a lesser degree in comparison with the animals irradiated in the active state. It was found that the acute irradiation of animals during arousal from hibernation in the second stage caused the most pronounced functional inactivation and cell death. The physiological state of ground squirrels subjected to ionizing irradiation at different phases of the hibernation-arousal bout plays a determining role in the changes of the qualitative and quantitative characteristics of blood system cells. Thus, the hypometabolic state of ground squirrels in hibernation is a factor of protection from the action of ionizing radiation on the organism and the immune system.     

The behavior of titin and the proteins of its family from skeletal muscles of ground squirrel (Citellus undulatus) during hibernation and rats under conditions of simulated microgravity

By the use of SDS PAGE, the behavior of titin and MyBP-C in fast (m. psoas) as well as titin and MyBP-X in slow (m. soleus) muscles of ground squirrels (Citellus undulatus) during hibernation was compared with the behavior of titin and MyBP-X in rat m. soleus under conditions of simulated microgravity. A decrease in the amount of titin 1 and MyBP-C relative to that of myosin heavy chains by approximately 30% and approximately 40%, correspondingly, in muscles of hibernating and arousing ground squirrels was revealed in comparison with active animals. No differences in the relative amount of MyBP-X in m. soleus of hibernating, arousing and active ground squirrels were found. Under conditions of simulated microgravity, a decrease in the amount of titin 1 by approximately 2 times and MyBP-X by approximately1.5 times relative to that of myosin heavy chains in rat m. soleus was observed. By the method of SDS PAGE modified by us, an almost twofold decrease in the amount of short isovariants of the titin N2A isoform relative to that of myosin heavy chains was shown in muscles of hibernating and arousing ground squirrels, whereas no changes were found in the amount of long titin isovariants. The conditions of simulated microgravity resulted in a twofold decrease in the relative amount of both short and long titin isovariants in rat m. soleus. The results indicate that hibernating ground squirrels have an evolutionarily determined adaptive mechanism of selective degradation of fast muscle fibers and preservation or increase of slow fibers, as the most economic and energetically advantageous, with proteins typical of them. The microgravitation of nonhibernating animals (rats) leads to a non-selective degradation of MyBP-X and titin isovariants, which contributes to considerable atrophy of soleus fibers.     

Seasonal liver protein differences in a hibernator revealed by quantitative proteomics using whole animal isotopic labeling

Hibernation is an energy-saving strategy used by diverse species of mammals to survive winter. It is characterized by cycles between multi-day periods of torpor with low body temperature (T(b)), and short periods of rapid, spontaneous rewarming. The ability to retain cellular integrity and function throughout torpor and rewarming is a key attribute of hibernation. Livers from winter hibernators are resistant to cellular damage induced by cold storage followed by warm reperfusion. Identifying proteins that differ between the summer-sensitive and winter-protected phenotypic states is one useful approach that may elucidate the molecular mechanisms that underlie this protection. Here we employ a novel quantitative proteomics screening strategy whereby a newly-weaned 13-lined ground squirrel was metabolically labeled by ingesting heavy-isotope substituted ((15)N) Spirulina. The liver protein extract from this animal provided a common reference for quantitative evaluation of protein differences by its addition to extracts from pooled samples of summer active (SA) or winter entrance (Ent) phase hibernating ground squirrels. We identified 61 significantly different proteins between the two groups and compared them to proteins identified previously in the same samples using 2D gels. Of the 20 proteins common to the two datasets, the direction and magnitude of their differences were perfectly concordant for 18, providing confidence that both sets of altered proteins reflect bona fide differences between the two physiological states. Furthermore, the 41 novel proteins recovered in this study included many new enzymes in pathways identified previously: specifically, additional enzymes belonging to the urea cycle, amino acid and carbohydrate degradation, and lipid biosynthetic pathways were decreased, whereas enzymes involved in ketone body synthesis, fatty acid utilization, protein synthesis and gluconeogenesis were increased in the samples from entrance hibernators compared to summer active animals, providing additional specific evidence for the importance of these pathways in the hibernating phenotype.     

Cytoskeletal Regulation Dominates Temperature-Sensitive Proteomic Changes of Hibernation in Forebrain of 13-Lined Ground Squirrels

13-lined ground squirrels, Ictidomys tridecemlineatus, are obligate hibernators that transition annually between summer homeothermy and winter heterothermy – wherein they exploit episodic torpor bouts. Despite cerebral ischemia during torpor and rapid reperfusion during arousal, hibernator brains resist damage and the animals emerge neurologically intact each spring. We hypothesized that protein changes in the brain underlie winter neuroprotection. To identify candidate proteins, we applied a sensitive 2D gel electrophoresis method to quantify protein differences among forebrain extracts prepared from ground squirrels in two summer, four winter and fall transition states. Proteins that differed among groups were identified using LC-MS/MS. Only 84 protein spots varied significantly among the defined states of hibernation. Protein changes in the forebrain proteome fell largely into two reciprocal patterns with a strong body temperature dependence. The importance of body temperature was tested in animals from the fall; these fall animals use torpor sporadically with body temperatures mirroring ambient temperatures between 4 and 21°C as they navigate the transition between summer homeothermy and winter heterothermy. Unlike cold-torpid fall ground squirrels, warm-torpid individuals strongly resembled the homeotherms, indicating that the changes observed in torpid hibernators are defined by body temperature, not torpor per se. Metabolic enzymes were largely unchanged despite varied metabolic activity across annual and torpor-arousal cycles. Instead, the majority of the observed changes were cytoskeletal proteins and their regulators. While cytoskeletal structural proteins tended to differ seasonally, i.e., between summer homeothermy and winter heterothermy, their regulatory proteins were more strongly affected by body temperature. Changes in the abundance of various isoforms of the microtubule assembly and disassembly regulatory proteins dihydropyrimidinase-related protein and stathmin suggested mechanisms for rapid cytoskeletal reorganization on return to euthermy during torpor-arousal cycles.