Michael D. Blaha

Thermoregulatory, behavioral, and metabolic responses to heatstroke in a conscious mouse model

The typical core temperature (T(c)) profile displayed during heatstroke (HS) recovery consists of initial hypothermia followed by delayed hyperthermia. Anecdotal observations led to the conclusion that these T(c) responses represent thermoregulatory dysfunction as a result of brain damage. We hypothesized that these T(c) responses are mediated by a change in the temperature setpoint. T(c) (+/- 0.1 degrees C; radiotelemetry) of male C57BL/6J mice was monitored while they were housed in a temperature gradient with ambient temperature (T(a)) range of 20-39 degrees C to monitor behaviorally selected T(a) (T(s)) or an indirect calorimeter (T(a) = 25 degrees C) to monitor metabolism (V(O(2))) and calculate respiratory exchange ratio (RER). Responses to mild and severe HS (thermal area 249.6 +/- 18.9 vs. 299.4 +/- 19.3 degrees C.min, respectively) were examined through 48 h of recovery. An initial hypothermia following mild HS was associated with warm T(s) (approximately 32 degrees C), approximately 35% V(O(2)) decrease, and RER approximately 0.71 that indicated reliance on fatty acid oxidation. After 24 h, mild HS mice developed hyperthermia associated with warm T(s) (approximately 32 degrees C), approximately 20% V(O(2)) increase, and RER approximately 0.85. Severe HS mice appeared poikilothermic-like in the temperature gradient with T(c) similar to T(s) (approximately 20 degrees C), and these mice failed to recover from hypothermia and develop delayed hyperthermia. Cellular damage (hematoxylin and eosin staining) was undetectable in the hypothalamus or other brain regions in severe HS mice. Overall, decreases and increases in T(c) were associated with behavioral and autonomic thermoeffectors that suggest HS elicits anapyrexia and fever, respectively. Taken together, T(c) responses of mild and severe HS mice suggest a need for reinterpretation of the mechanisms of thermoregulatory control during recovery.

Attenuated thermoregulatory, metabolic, and liver acute phase protein response to heat stroke in TNF receptor knockout mice

Tumor necrosis factor (TNF) is considered an adverse mediator of heat stroke (HS) based on clinical studies showing high serum levels. However, soluble TNF receptors (sTNFR; TNF antagonists) were higher in survivors than nonsurvivors, and TNFR knockout (KO) mice showed a trend toward increased mortality, suggesting TNF has protective actions for recovery. We delineated TNF actions in HS by comparing thermoregulatory, metabolic, and inflammatory responses between B6129F2 (wild type, WT) and TNFR KO mice. Before heat exposure, TNFR KO mice showed ~0.4°C lower core temperature (T(c); radiotelemetry), ~10% lower metabolic rate (M(r); indirect calorimetry), and reduced plasma interleukin (IL)-1α and sIL-1RI than WT mice. KO mice selected warmer temperatures than WT mice in a gradient but remained hypothermic. In the calorimeter, both genotypes showed a similar heating rate, but TNFR KO maintained lower T(c) and M(r) than WT mice for a given heat exposure duration and required ~30 min longer to reach maximum T(c) (42.4°C). Plasma IL-6 increased at ~3 h of recovery in both genotypes, but KO mice showed a more robust sIL-6R response. Higher sIL-6R in the KO mice was associated with delayed liver p-STAT3 protein expression and attenuated serum amyloid A3 (SAA3) gene expression, suggesting the acute phase response (APR) was attenuated in these mice. Our data suggest that the absence of TNF signaling induced a regulated hypothermic state in the KO mice, TNF-IL-1 interactions may modulate T(c) and M(r) during homeostatic conditions, and TNF modulates the APR during HS recovery through interactions with the liver IL-6-STAT3 pathway of SAA3 regulation.