Liver proteome response to torpor in a basoendothermic mammal, Tenrec ecaudatus, provides insights into the evolution of homeothermy.

Many mammals use adaptive heterothermy (e.g., torpor, hibernation) to reduce metabolic demands of maintaining high body temperature (Tb). Torpor is typically characterized by coordinated declines in Tb and metabolic rate (MR) followed by active rewarming. Most hibernators experience periods of euthermy between bouts of torpor during which homeostatic processes are restored. In contrast, the common tenrec, a basoendothermic Afrotherian mammal, hibernates without interbout arousals and displays extreme flexibility in Tb and MR. We investigated the molecular basis of this plasticity in tenrecs by profiling the liver proteome of animals that were active or torpid with high and more stable Tb (∼32°C) or lower Tb (∼14°C). We identified 768 tenrec liver proteins, of which 50.9% were differentially abundant between torpid and active animals. Protein abundance was significantly more variable in active cold and torpid compared with active warm animals, suggesting poor control of proteostasis. Our data suggest that torpor in tenrecs may lead to mismatches in protein pools due to poor coordination of anabolic and catabolic processes. We propose that the evolution of endothermy leading to a more realized homeothermy of boreoeutherians likely led to greater coordination of homeostatic processes and reduced mismatches in thermal sensitivities of metabolic pathways.

Extreme physiological plasticity in a hibernating basoendothermic mammal, Tenrec ecaudatus.

Physiological plasticity allows organisms to respond to diverse conditions. However, can being too plastic actually be detrimental? Malagasy common tenrecs, Tenrec ecaudatus, have many plesiomorphic traits and may represent a basal placental mammal. We established a laboratory population of T. ecaudatus and found extreme plasticity in thermoregulation and metabolism, a novel hibernation form, variable annual timing, and remarkable growth and reproductive biology. For instance, tenrec body temperature (Tb) may approximate ambient temperature to as low as 12°C even when tenrecs are fully active. Conversely, tenrecs can hibernate with Tb of 28°C. During the active season, oxygen consumption may vary 25-fold with little or no change in Tb During the austral winter, tenrecs are consistently torpid but the depth of torpor may vary. A righting assay revealed that Tb contributes to but does not dictate activity status. Homeostatic processes are not always linked, e.g. a hibernating tenrec experienced a ∼34% decrease in heart rate while maintaining constant body temperature and oxygen consumption rates. Tenrec growth rates vary but young may grow ∼40-fold in the 5 weeks until weaning and may possess indeterminate growth as adults. Despite all of this profound plasticity, tenrecs are surprisingly intolerant of extremes in ambient temperature (<8 or >34°C). We contend that while plasticity may confer numerous energetic advantages in consistently moderate environments, environmental extremes may have limited the success and distribution of plastic basal mammals.

A systems-level approach to understanding transcriptional regulation by p53 during mammalian hibernation.

Presumably to conserve energy, many mammals enter into hibernation during the winter. Homeostatic processes such as transcription and translation are virtually arrested. To further elucidate transcriptional regulation during hibernation, we studied the transcription factor p53. Here, we demonstrate that changes in liver mRNA and protein concentrations of known regulators of p53 are consistent with activation. p53 mRNA and protein concentrations are unrelated. Importantly, p53 protein concentration is increased ~2-fold during the interbout arousal that punctuates bouts of torpor. As a result, both the interbout arousal and the torpid state are characterized by high levels of nuclear-localized p53. Chromatin immunoprecipitation assays indicate that p53 binds DNA during the winter. Furthermore, p53 recruits RNA polymerase II, as indicated by nuclear run-on data. However, and consistent with previous data indicating an arrest of transcriptional elongation during torpor, p53 'activity' does not result in expected changes in target gene transcripts. These data demonstrate the importance of using a systems level-approach in understanding a complex phenotype such as mammalian hibernation. Relying on interpretations of data that are based on steady-state regulation in other systems may be misleading in the context of non-steady-state conditions such as torpor.

Incomplete Caspase 3 Activation and Mitigation of Apoptosis in Hibernating Ground Squirrels, Spermophilus lateralis.

AbstractHibernating golden-mantled ground squirrels, Spermophilus [Callospermophilus] lateralis, tolerate proapoptotic conditions, such as low body temperature, anorexia, acidosis, and ischemia/reperfusion. Avoiding widespread apoptosis is critical for hibernator survival. Caspase 3, the key executioner of apoptosis, cleaves a majority of apoptotic targets. Under proapoptotic conditions, inactive procaspase 3 (32 kDa) is activated when cleaved into 17- and 12-kDa fragments (p32, p17, and p12, respectively). Caspase 3 activation results in extreme enzymatic activation. Activity increases >10,000-fold followed by apoptotic execution. Is widespread apoptosis occurring during the proapoptotic hibernation season? Western blots showed p17 increased ∼2-fold during hibernation, indicating caspase 3 activation. However, in vitro caspase 3 activity assays found no extreme increases in activity. Downstream caspase 3 targets ICAD (inhibitor of caspase-activated deoxyribonuclease) and PARP (poly (ADP-ribose) polymerase) did not experience elevated cleavage during hibernation, which is inconsistent with caspase 3 activation. TUNEL (terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate nick-end labeling) assays from multiple tissues found only 0.001%-0.009% of cells were TUNEL positive during winter, indicating negligible apoptosis during hibernation. Typically, caspase 3 activation generates a strong commitment toward apoptosis. We found that despite a ∼2-fold increase in active caspase 3, hibernators experience no downstream caspase 3 activity or widespread apoptosis. A systems-level approach suggests an incomplete signaling cascade wherein some caspase 3 activation during hibernation does not necessarily lead to bona fide apoptosis.

Mitigating Apoptotic and Inflammatory Signaling via Global Caspase Inhibition in Hibernating Ground Squirrels, Spermophilus lateralis.

AbstractIn most systems, the caspase cascade is activated during cellular stress and results in inflammation and apoptosis. Hibernators experience stressors such as extremely low body temperatures, bradycardia, possible ischemia and reperfusion, and acidosis. However, widespread inflammation and apoptosis would represent an energetic expense that is incompatible with hibernation. To better understand global caspase regulation during hibernation, we employed a systems-level approach and analyzed 11 caspases in ground squirrel liver that are involved in inflammatory (caspases 1, 4, 5, 11, and 12) and apoptotic (caspases 2, 6, 7, 8, 9, and 10) pathways. Western blots revealed liberation of active forms for two inflammatory (caspases 11 and 12) and two apoptotic (caspases 6 and 9) caspases during hibernation (e.g., p15, the most active fragment of caspase 6, increased 8.26±0.70-fold in interbout-aroused animals). We used specific peptide substrates to interrogate the four seemingly activated caspases and demonstrated no expected increases in proteolytic activity. Specific targets of these four caspases were similarly not cleaved, demonstrating that initiation of caspase activation may occur without concomitant downstream effects. Similarly, we found no evidence for upstream activation for caspase 9 signaling based on permeabilization of the outer mitochondrial membrane. We contend that these caspases are suppressed after seeming activation during hibernation. Incomplete caspase signaling is effectively mitigating the induction of widespread inflammation and apoptosis during hibernation.

Torpor Does Not Influence Spatial Memory in Hibernating Golden-Mantled Ground Squirrels (Spermophilus [Callospermophilus] lateralis).

AbstractMammalian hibernation in ground squirrels is characterized by periods of torpor wherein body temperature approaches ambient temperature and metabolism is reduced to as low as 1/100th of active rates. It is unclear how hibernation affects long-term spatial memory, as tremendous remodeling of neurons is associated with torpor use. Given the suspected links between remodeling and memory formation and retention, we examined long-term spatial memory retention throughout a hibernation season. Animals were trained on a Barnes maze before entering torpor. Animals were tested for memory retention once a month throughout a hibernation season. Results indicate marked variation between individuals. Some squirrels retained memory across multiple torpor bouts, while other squirrels did not. No relationship was found between the number of torpor bouts, duration of bouts, or time spent torpid on long-term memory retention. However, that some squirrels successfully retain memory suggests that the profound remodeling of dendritic spines during torpor does not always lead to memory loss.

A refined technique for sciatic denervation in a golden-mantled ground squirrel (Callospermophilus lateralis) model of disuse atrophy.

Disuse atrophy of both muscle and bone can occur rapidly during periods of inactivity. In several rodent models developed for the study of disuse atrophy, immobilization is induced by prolonged cage restraint, hind limb unloading, tenotomy, sciatic nerve block or sciatic denervation. In less tractable species such as wild-caught hibernating rodents, the sciatic denervation model is superior in terms of both animal welfare and applicability to the characteristics of natural cases of disuse atrophy. The authors describe a refined surgical approach to sciatic denervation in golden-mantled ground squirrels (Callospermophilus lateralis), a hibernating species, that improves animal welfare and reduces the incidence of post-operative complications such as autotomy.