Regulation of Akt during hibernation in Richardson's ground squirrels

Akt (or protein kinase B) plays a central role in coordinating growth, survival and anti-apoptotic responses in cells and we hypothesized that changes in Akt activity and properties would aid the reprioritization of metabolic functions that occurs during mammalian hibernation. Akt was analyzed in skeletal muscle and liver of Richardson's ground squirrels, Spermophilus richardsonii, comparing the enzyme from euthermic and hibernating states. Akt activity, measured with a synthetic peptide substrate, decreased by 60–65% in both organs during hibernation. Western blotting showed that total Akt protein did not change in hibernation but active, phosphorylated Akt (Ser 473) was reduced by 40% in muscle compared with euthermic controls and was almost undetectable in liver. Kinetic analysis of muscle Akt showed that S_0.5 values for Akt peptide were 28% lower during hibernation, compared with the euthermic enzyme, whereas S_0.5 ATP increased by 330%. Assay at 10 °C also elevated S_0.5 ATP of euthermic Akt by 350%. Changes in ATP affinity would limit Akt function in the hibernator since the muscle adenylate pool size is also strongly suppressed during cold torpor. Other parameters of euthermic and hibernator Akt were the same including activation energy calculated from Arrhenius plots and sensitivity to urea denaturation. DEAE Sephadex chromatography of muscle extracts revealed three peaks of Akt activity in euthermia but only two during hibernation suggesting isozymes are differentially dephosphorylated during torpor. Altered enzyme properties and suppression of Akt activity would contribute to the coordinated suppression of energy-expensive anabolic and growth processes that is needed to maintain viability during over weeks of winter torpor.     

Cytosolic phospholipase A2 regulation in the hibernating thirteen-lined ground squirrel

Cytosolic calcium-dependent phospholipase A₂ (cPLA₂) has multiple roles including production of arachidonic acid (a key player in cellular signaling pathways) and membrane remodeling. Additionally, since catabolism of arachidonic acid generates free radicals, the enzyme is also implicated in ischemic injury to mammalian organs. Regulation of cPLA₂ could be important in the suppression and prioritization of cellular pathways in animals that undergo reversible transitions into hypometabolic states. The present study examines the responses and regulation of cPLA₂ in skeletal muscle and liver of hibernating thirteen-lined ground squirrels, Spermophilus tridecemlineatus. cPLA₂ activity decreased significantly by 43% in liver during hibernation, compared with euthermic controls, and K_m values for arachidonoyl thio-PC substrate fell in both organs during hibernation to 61% in liver and 28% in muscle of the corresponding euthermic value. To determine whether these responses were due to a change in the phosphorylation state of the enzyme, Western blotting was employed using antibodies recognizing phospho-Ser⁵⁰⁵ on α-cPLA₂. The amount of phosphorylated α-cPLA₂ in hibernator liver was just 38% of the value in euthermic liver. Furthermore, incubation of liver extracts under conditions that enhanced protein phosphatase action caused a greater reduction in the detectable amount of phospho-Ser⁵⁰⁵ enzyme content in euthermic, versus hibernator, extracts. The data are consistent with a suppression of cPLA₂ function during torpor via enzyme dephosphorylation, an action that may contribute to the well-developed ischemia tolerance and lack of oxidative damage found in hibernating species over cycles of torpor and arousal.     

Suppression of MAPKAPK2 during mammalian hibernation

Metabolic signaling coordinates the transition by hibernating mammals from euthermia into profound torpor. Organ-specific responses by activated p38 mitogen activated protein kinase (MAPK) are known to contribute to this transition. Therefore, we hypothesized that the MAPK-activated protein kinase-2 (MAPKAPK2), a downstream target of p38 MAPK, would also be active in establishing the torpid state. Kinetic parameters of MAPKAPK2 from skeletal muscle of Richardson’s ground squirrels, Spermophilus richardsonii, were analyzed using a fluorescence assay. MAPKAPK2 activity was 27.4 ± 1.27 pmol/min/mg in muscle from euthermic squirrels and decreased by ∼63% during cold torpor, while total protein levels were unchanged (as assessed by immunoblotting). In vitro treatment of MAPKAPK2 via stimulation of endogenous phosphatases and addition of commercial alkaline phosphatase decreased enzyme activity to only ∼3–5% of its original value in muscle extracts from both euthermic and hibernating squirrels suggesting that posttranslational modification suppresses MAPKAPK2 during the transition from euthermic to torpid states. Enzyme S_0.5 and n_H values for ATP and peptide substrates changed significantly between euthermia and torpor, and also between assays at 22 versus 10 °C but, kinetic parameters were actually closely conserved when values for the euthermic enzyme at 22 °C were directly compared with the hibernator enzyme at 10 °C. Arrhenius plots showed significantly different activation energies of 40.8 ± 0.7 and 54.3 ± 2.7 kJ/mol for the muscle enzyme from euthermic versus torpid animals, respectively but MAPKAPK2 from the two physiological states showed no difference in sensitivity to urea denaturation. Overall, the results show that total activity of MAPKAPK2 is in fact reduced, despite previous findings of p38 MAPK activation, and kinetic parameters are altered when ground squirrels enter torpor but protein stability is not apparently changed. The data suggest that MAPKAPK2 suppression may have a significant role in the differential regulation of muscle target proteins when ground squirrels enter torpor.     

Suppression of MAPKAPK2 during mammalian hibernation

Metabolic signaling coordinates the transition by hibernating mammals from euthermia into profound torpor. Organ-specific responses by activated p38 mitogen activated protein kinase (MAPK) are known to contribute to this transition. Therefore, we hypothesized that the MAPK-activated protein kinase-2 (MAPKAPK2), a downstream target of p38 MAPK, would also be active in establishing the torpid state. Kinetic parameters of MAPKAPK2 from skeletal muscle of Richardson’s ground squirrels, Spermophilus richardsonii, were analyzed using a fluorescence assay. MAPKAPK2 activity was 27.4 ± 1.27 pmol/min/mg in muscle from euthermic squirrels and decreased by ∼63% during cold torpor, while total protein levels were unchanged (as assessed by immunoblotting). In vitro treatment of MAPKAPK2 via stimulation of endogenous phosphatases and addition of commercial alkaline phosphatase decreased enzyme activity to only ∼3–5% of its original value in muscle extracts from both euthermic and hibernating squirrels suggesting that posttranslational modification suppresses MAPKAPK2 during the transition from euthermic to torpid states. Enzyme S_0.5 and n_H values for ATP and peptide substrates changed significantly between euthermia and torpor, and also between assays at 22 versus 10 °C but, kinetic parameters were actually closely conserved when values for the euthermic enzyme at 22 °C were directly compared with the hibernator enzyme at 10 °C. Arrhenius plots showed significantly different activation energies of 40.8 ± 0.7 and 54.3 ± 2.7 kJ/mol for the muscle enzyme from euthermic versus torpid animals, respectively but MAPKAPK2 from the two physiological states showed no difference in sensitivity to urea denaturation. Overall, the results show that total activity of MAPKAPK2 is in fact reduced, despite previous findings of p38 MAPK activation, and kinetic parameters are altered when ground squirrels enter torpor but protein stability is not apparently changed. The data suggest that MAPKAPK2 suppression may have a significant role in the differential regulation of muscle target proteins when ground squirrels enter torpor.     

Regulation of the α-ketoglutarate dehydrogenasecomplex during hibernation in a small mammal,the Richardson's ground squirrel (Urocitellus richardsonii)

The citric acid cycle (CAC) is a central metabolic pathway that links carbohydrate, lipid, and amino acid metabolism in the mitochondria and, hence, is a crucial target for metabolic regulation. The α-ketoglutarate dehydrogenase complex (KGDC) is the rate-limiting step of the CAC, the three enzymes of the complex catalyzing the transformation of α-ketoglutarate to succinyl-CoA with the release of CO₂ and reduction of NAD to NADH. During hibernation, the metabolic rate of small mammals is suppressed, in part due to reduced body temperature but also active controls that suppress aerobic metabolism. The present study examined KGDC regulation during hibernation in skeletal muscle of the Richardson's ground squirrel (Urocitellus richardsonii). The KGDC was partially purified from skeletal muscle of euthermic and hibernating ground squirrels and kinetic properties were evaluated at 5°, 22°, and 37 °C. KGDC from hibernator muscle at all temperatures compared with euthermic controls exhibited a decreased affinity for CoA as well as reduced activation by Ca²⁺ ions at 5 °C from both euthermic and hibernating conditions. Co-immunoprecipitation was employed to isolate the E1, E2 and E3 enzymes of the complex (OGDH, DLST, DLD) to allow immunoblot analysis of post-translational modifications (PTMs) of each enzyme. The results showed elevated phospho-tyrosine content on all three enzymes during hibernation as well as increased ADP-ribosylation and succinylation of hibernator OGDH. Taken together these results show that the KGDC is regulated by posttranslational modifications and temperature effects to reorganize enzyme activity and mitochondrial function to aid suppression of mitochondrial activity during hibernation.     

Reassessment of the cold-labile nature of phosphofructokinase from a hibernating ground squirrel.

This study reassesses the proposal that cellular conditions of low temperature and relative acidosis during hibernation contribute to a suppression of phosphofructokinase (PFK) activity which, in turn, contributes to glycolytic rate suppression during torpor. To test the proposal that a dilution effect during in vitro assay of PFK was the main reason for activity loss (tetramer dissociation) at lower pH values, the influence of the macromolecular crowding agent, polyethylene glycol 8000 (PEG), on purified skeletal muscle PFK from Spermophilus lateralis was evaluated at different pH values (6.5, 7.2 and 7.5) and assay temperatures (5, 25 and 37degrees C). A 78 +/- 2.5% loss of PFK activity during 1 h incubation at 5 degrees C and pH 6.5 was virtually eliminated when 10% PEG was present (only 7.0 +/- 1.5% activity lost). The presence of PEG also largely reversed PFK inactivation at pH 6.5 at warmer assay temperatures and reversed inhibitory effects by high urea (50 or 400 mM). Analysis of pH curves at 5 degrees C also indicated that approximately 70% of activity would remain at intracellular pH values in hibernator muscle. The data suggest that under high protein concentrations in intact cells that the conditions of relative acidosis, low temperature or elevated urea during hibernation would not have substantial regulatory effects on PFK.     

Energy expenditure increases during the active season in the small,free-living hibernator Muscardinus avellanarius

Little is known about strategies employed by small mammals to reduce energy expenditure during the summer. To understand whether ambient conditions impact euthermic energy demands in a small free-living hibernator, we measured metabolic rate of hazel dormice (Muscardinus avellanarius) in the field. Furthermore, we aimed to reveal which variables influence torpor use. Our results show that hazel dormice altered euthermic energy expenditure during summer but not as expected as a response to environmental conditions. Euthermic resting metabolic rate was lowest directly after emergence from hibernation and increased by about 95% until the end of August. A considerable part of this increase was presumably caused by the changing influence of gender and rain on energy demands during different months, variation in food quality and quantity, and reversible size changes of organs that had been atrophied during hibernation. Torpor use in hazel dormice occurred more frequently when it was colder, earlier during the day, and in lighter individuals. Torpor was used routinely in males and non-reproductive females. We show that torpor is used more frequently than previously suggested by studies that only used visual proof of torpor use by surveying nest boxes.     

The role of succinate dehydrogenase and oxaloacetate in metabolic suppression during hibernation and arousal

Hibernation elicits a major reduction in whole-animal O₂ consumption that corresponds with active suppression of liver mitochondrial electron transport capacity at, or downstream of, succinate dehydrogenase (SDH). During arousal from the torpor phase of hibernation this suppression is reversed and metabolic rates rise dramatically. In this study, we used the 13-lined ground squirrel (Ictidomys tridecemlineatus) to assess isolated liver mitochondrial respiration during the torpor phase of hibernation and various stages of arousal to elucidate a potential role of SDH in metabolic suppression. State 3 and state 4 respiration rates were seven- and threefold lower in torpor compared with the summer-active and interbout euthermic states. Respiration rates increased during arousal so that when body temperature reached 30°C in late arousal, state 3 and state 4 respiration were 3.3- and 1.8-fold greater than during torpor, respectively. SDH activity was 72% higher in interbout euthermia than in torpor. Pre-incubating with isocitrate [to alleviate oxaloacetate (OAA) inhibition] increased state 3 respiration rate during torpor by 91%, but this rate was still fourfold lower than that measured in interbout euthermia. Isocitrate pre-incubation also eliminated differences in SDH activity among hibernation bout stages. OAA concentration correlated negatively with both respiration rates and SDH activity. These data suggest that OAA reversibly inhibits SDH in torpor, but cannot fully account for the drastic metabolic suppression observed during this hibernation phase.     

Reassessment of the cold‐labile nature of phosphofructokinase from a hibernating ground squirrel

This study reassesses the proposal that cellular conditions of low temperature and relative acidosis during hibernation contribute to a suppression of phosphofructokinase (PFK) activity which, in turn, contributes to glycolytic rate suppression during torpor. To test the proposal that a dilution effect during in vitro assay of PFK was the main reason for activity loss (tetramer dissociation) at lower pH values, the influence of the macromolecular crowding agent, polyethylene glycol 8000 (PEG), on purified skeletal muscle PFK from Spermophilus lateralis was evaluated at different pH values (6.5, 7.2 and 7.5) and assay temperatures (5, 25 and 37°C). A 78 ± 2.5% loss of PFK activity during 1 h incubation at 5°C and pH 6.5 was virtually eliminated when 10% PEG was present (only 7.0 ± 1.5% activity lost). The presence of PEG also largely reversed PFK inactivation at pH 6.5 at warmer assay temperatures and reversed inhibitory effects by high urea (50 or 400 mM). Analysis of pH curves at 5°C also indicated that ~ 70% of activity would remain at intracellular pH values in hibernator muscle. The data suggest that under high protein concentrations in intact cells that the conditions of relative acidosis, low temperature or elevated urea during hibernation would not have substantial regulatory effects on PFK.     

Temperature and phosphate effects on allosteric phenomena of phosphofructokinase from a hibernating ground squirrel (Spermophilus lateralis)

Temperature effects on the kinetic properties of phosphofructokinase (PFK) purified from skeletal muscle of the golden-mantled ground squirrel, Spermophilus lateralis, were examined at 37 degrees C and 5 degrees C, values characteristic of body temperatures in euthermia vs. hibernation. The enzyme showed reduced sensitivity to all activators at 5 degrees C, the K(a) values for AMP, ADP, NH(4) (+) and F2,6P(2) were 3-11-fold higher at 5 degrees C than at 37 degrees C. Inhibition by citrate was not affected whereas phosphoenolpyruvate, ATP and urea became more potent inhibitors at low temperature. While typically considered an activator of PFK activity, inorganic phosphate performed as an inhibitor at 5 degrees C. Decreasing temperature alone causes the actions of inorganic phosphate to change from activation to inhibition. We found that K(m) values for ATP remained constant while V(max) dropped significantly upon the addition of phosphate. Phosphate inhibition at 5 degrees C was noncompetitive with respect to ATP and the K(i) was 0.15 +/- 0.01 mm (n = 4). The results indicate that PFK is less likely to be activated in cold torpid muscle; PFK is less sensitive to changing adenylate levels at the low temperatures characteristic of torpor, and PFK is clearly much less sensitive to biosynthetic signals. All of these characteristics of hibernator PFK would serve to reduce glycolytic rate and help to preserve carbohydrate reserves during torpor.     

Sexual differences in over-winter torpor patterns of Richardson's ground squirrels in natural hibernacula

Summary Over-winter torpor patterns of Richardson's ground squirrels hibernating in southern Alberta were monitored with temperature-sensitive radiocollars to determine if these patterns differed between males and females in a manner related to the greater costs of mating effort by males than females. The hibernation season (from immergence to emergence) was composed of three periods: post-immergence euthermy, heterothermy, and pre-emergence euthermy. The hibernation season was shorter for juveniles than adults both among males (< 150 versus 234 days) and females (185 versus 231 days), a reflection of the later immergence into hibernation by juveniles. However, regardless of the absolute duration of hibernation, heterothermy accounted for a smaller proportion of the hibernation season of males (93±5%) than females (98±1%) and, within the heterothermal period, males had shorter torpor bouts and longer inter-torpor arousals. Overall, males spent a smaller proportion of the hibernation season in torpor (85±6%) than females (92±1%). This sexual difference was largely attributable to the longer duration of preemergence euthermy for males than females. Males terminated torpor in January and February, when hibernacula were at their coldest, then remained euthermic for 8.8 days (range 0.5–25.0 days) before emergence. In contrast, females terminated torpor in March, when hibernaculum temperatures were increasing, then remained euthermic for only 1.1 days (range 0.5–2.0 days) before emergence. Males lost less mass per euthermic day during hibernation than females (7.0 versus 9.3 g/day). Males and females hibernated at similar depths (56 cm), but males had larger chambers than females (18 versus 16 cm³/g). Many males, but no females, cached seeds in the hibernaculum. Males met the costs of thermogenesis and euthermy from a combination of fat reserves and food caches, whereas females relied solely on fat. Access to food caches permitted males to terminate torpor several weeks in advance of emergence, during which time they recouped mass and developed sperm in preparation for the forthcoming mating season.     

The Dynamics of Adaptive Changes in the Spleen of the Hibernating Ground Squirrel <Emphasis Type="Italic">Spermophilus undulatus</Emphasis>

In hibernation season during torpor bouts, the spleen weight and the hemoglobin level, as well as the total and extracted protein contents in the spleen of the ground squirrel Spermophilus undulatus are increased when animals enter torpor and reach maximum values when the body temperature drops below 25°C. All these parameters return to the characteristic values of the euthermic animals during arousal, before the body temperature increases to 20°C. There were no significant differences in the numbers of splenocytes between ground squirrels in interbout euthermia and torpor. The minimum number of splenocytes was observed in animals that entered torpor when the core body temperature was approximately 18°C. The activity of ornithine decarboxylase, a key enzyme in polyamine synthesis, which is correlated with the functional and proliferative status of lymphoid tissue, was the same for the euthermic and summer ground squirrels and decreased monotonically during torpor. Upon arousal of the animals when body temperature was below 29°C, no resumption of the spleen ornithine decarboxylase activity was observed.     

Myosin isoform expression and MAFbx mRNA levels in hibernating golden-mantled ground squirrels (Spermophilus lateralis)

Hibernating mammals present many unexplored opportunities for the study of muscle biology. The hindlimb muscles of a small rodent hibernator (Spermophilus lateralis) atrophy slightly during months of torpor, representing a reduction in the disuse atrophy commonly seen in other mammalian models. How torpor affects contractile protein expression is unclear; therefore, we examined the myosin heavy-chain (MHC) isoform profile of ground squirrel skeletal muscle before and after hibernation. Immunoblotting was performed first to identify the MHC isoforms expressed in this species. Relative percentages of MHC isoforms in individual muscles were then measured using SDS-PAGE (sodium dodecyl sulfate-polyacrylamide gel electrophoresis). The soleus and diaphragm did not display differences in isoforms following hibernation, but we found minor fast-to-slow isoform shifts in MHC protein in the gastrocnemius and plantaris. These subtle changes are contrary to those predicted by other models of inactivity but may reflect the requirement for shivering thermogenesis during arousals from torpor. We also measured mRNA expression of the Muscle Atrophy F-box (MAFbx), a ubiquitin ligase important in proteasome-mediated proteolysis. Expression was elevated in the hibernating gastrocnemius and the plantaris but was not associated with atrophy. Skeletal muscle from hibernators displays unusual plasticity, which may be a combined result of the intense activity during arousals and the reduction of metabolism during torpor.