Prolonged food deprivation in mammals typically reduces glucose, insulin, and thyroid hormone (TH) concentrations, as well as tissue deiodinase (DI) content and activity, which, collectively, suppress metabolism. However, in elephant seal pups, prolonged fasting does not suppress TH levels; it is associated with upregulation of adipose TH-mediated cellular mechanisms and adipose-specific insulin resistance. The functional relevance of this apparent paradox and the effects of glucose and insulin on TH-mediated signaling in an insulin-resistant tissue are not well defined. To address our hypothesis that insulin increases adipose TH signaling in pups during extended fasting, we assessed the changes in TH-associated genes in response to an insulin infusion in early- and late-fasted pups. In late fasting, insulin increased DI1, DI2, and THrβ-1 mRNA expression by 566%, 44%, and 267% at 60 min postinfusion, respectively, with levels decreasing by 120 min. Additionally, we performed a glucose challenge in late-fasted pups to differentiate between insulin- and glucose-mediated effects on TH signaling. In contrast to the insulin-induced effects, glucose infusion did not increase the expressions of DI1, DI2, and THrβ-1 until 120 min, suggesting that glucose delays the onset of the insulin-induced effects. The data also suggest that fasting duration increases the sensitivity of adipose TH-mediated mechanisms to insulin, some of which may be mediated by increased glucose. These responses appear to be unique among mammals and to have evolved in elephant seals to facilitate their adaptation to tolerate an extreme physiological condition.
Thyroid hormones (TH) can increase cellular metabolism. Food deprivation
in mammals is typically associated with reduced thyroid gland responsiveness, in
an effort to suppress cellular metabolism and abate starvation. However, in
prolonged-fasted, elephant seal pups, cellular TH-mediated proteins are
up-regulated and TH levels are maintained with fasting duration. The function
and contribution of the thyroid gland to this apparent paradox is unknown and
physiologically perplexing. Here we show that the thyroid gland remains
responsive during prolonged food deprivation, and that its function and
production of TH increase with fasting duration in elephant seals. We discovered
that our modeled plasma TH data in response to exogenous thyroid stimulating
hormone predicted cellular signaling, which was corroborated independently by
the enzyme expression data. The data suggest that the regulation and function of
the thyroid gland in the northern elephant seal is atypical for a fasted animal,
and can be better described as, “adaptive fasting”. Furthermore,
the modeling data help substantiate the in vivo responses
measured, providing unique insight on hormone clearance, production rates, and
thyroid gland responsiveness. Because these unique endocrine responses occur
simultaneously with a nearly strict reliance on the oxidation of lipid, these
findings provide an intriguing model to better understand the TH-mediated
reliance on lipid metabolism that is not otherwise present in morbidly obese
humans. When coupled with cellular, tissue-specific responses, these data
provide a more integrated assessment of thyroidal status that can be
extrapolated for many fasting/food deprived mammals.
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