Effects of prolonged fasting on plasma cortisol and TH in postweaned northern elephant seal pups

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Effects of prolonged fasting on plasma cortisol and TH in postweaned northern elephant seal pups

Rudy M. Ortiz¹^,², Charles E. Wade², and C. Leo Ortiz¹

¹ Department of Biology, University of California, Santa Cruz 95064; and ² Neuroendocrinology Lab, Division of Life Sciences, National Aeronautics and Space Administration Ames Research Center, Moffett Field, California 94035

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Northern elephant seal (Mirounga angustirostris) pups rely on the oxidation of fat stores as their primary source of energyduring their 8- to 12-wk postweaning fast; however, potentialendocrine mechanisms involved with this increased fat metabolismhave yet to be examined. Therefore, 15 pups were serially bloodsampled in the field during the first 7 wk of their postweaningfast to examine the changes in plasma concentrations of cortisoland thyroid hormones (TH), which are involved in fat metabolismin other mammals. Cortisol increased, indicating that it contributedto an increase in lipolysis. Increased total triiodothyronine(tT₃) and thyroxine (tT₄) may not reflect increased thyroid glandactivity, but rather alterations in hormone metabolism. tT₃-to-tT₄ratio decreased, suggesting a decrease in thyroxine (T₄) deiodination,whereas the negative correlation between total proteins and freeT₄ suggests that the increase in free hormone is attributed toa decrease in binding globulins. Changes in TH are most similarto those observed during hibernation than starvation in mammals,suggesting that the metabolic adaptations to natural fasting aremore similar to hibernation despite the fact these animals remainactive throughout the fastingperiod.

fat metabolism; food deprivation; leptin; marine mammals

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

NORTHERN ELEPHANT SEAL (Mirounga angustirostris) (NES) pups nurse for ~1 mo before their postweaning fast, which may lastas long as 3 mo (4, 23). Pups may increase their body fatto ~50% of body mass while they are nursing (26). During theirpostweaning fast, these extensive fat stores are the primary sourceof energy, supporting >95% of their metabolic rate (4, 26).Although such extended periods of complete abstinence from foodwould induce adverse effects on energy balance in most mammals,NES pups have developed robust physiological mechanisms to withstandthis potentially detrimentalperiod.

In terrestrial mammals, extended periods of food restriction are usually associated with an increase in glucocorticoids (3,28) and a decrease in thyroid hormones (20, 22) and leptin(2). During periods of reduced food intake or fasting, glucocorticoidshelp to provide energy by increasing lipolysis (3) and helpto maintain circulating glucose concentrations via increased gluconeogenesis(10). Glucocorticoids can also lessen the adverse affects ofmetabolic acidosis incurred during fasting by increasing Na⁺/K⁺-H⁺-ATPase synthesis (32). The increase in fat oxidation previouslydescribed in NES pups (4) suggests that glucocorticoids maybe elevated during the fast as in othermammals.

Because thyroid hormones are associated with an increase in metabolic rate, these hormones are usually reduced during periodsof food deprivation as a means to conserve energy (22). Fastingpups have been shown to decrease their absolute basal metabolicrates (26), apparently in an effort to conserve energy, suggestingthat thyroid hormones may be reduced during this period. Also,the increase in fat oxidation during the fast may induce a decreasein plasma leptin, because leptin has been reported to reflectchanges in body fat (6).

Previous studies have examined the effects of prolonged fasting in elephant seal pups on important biochemical parameters(7) as well as on insulin and glucagon (15), which are normallyaffected by periods of prolonged food deprivation. These studiesdemonstrated that fasting pups maintain biochemical homeostasisthat appears to be independent of insulin and glucagon. Therefore,to provide further insight to our understanding of the physiologicalmechanisms underlying the adaptation to prolonged periods of naturalfasting, plasma cortisol, thyroid hormones, and leptin, whichare all associated with changes in fat metabolism during periodsof food deprivation, were examined during the postweaning fastin NES pups. Because fat metabolism is increased during the postweaningfast, we hypothesized that plasma cortisol would increase, whereasthyroid hormones and leptin would decrease. This study shouldhelp elucidate the endocrine regulation of fasting energeticsduring this period in a species adapted to prolonged fasting suchas theNES.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Animals and blood sampling. Fifteen NES pups (9 males, 6 females) from Año Nuevo State Reserve (~30 km north of Santa Cruz, CA) were serially sampledin the field over the first 49 days of their postweaning fast.Only 9 of the 15 pups could be weighed at the beginning of thestudy, averaging 112 ± 25 kg (±SD; range 65-140 kg). Because animalswere left in their natural habitat between sampling periods, notall animals could be found on each designated blood-sampling day,which resulted in a reduction of sample size over the 49-day period.For example, of the original 15 pups sampled on the first dayof the study, only 7 could be found on day 49 forresampling.

Mother-pup pairs were individually identified to determine the date of weaning. A pup was considered weaned when its motherwas not seen on the subsequent day. Blood samples were not collectedfrom pups before weaning to avoid disturbing nursing mother-puppairs. Therefore, an initial blood sample was taken within thefirst 24 h postweaning and used to represent preweaned, "nonfasting"conditions. Subsequent blood samples were obtained on days 7,21, 35, and 49 of the fast. Blood sampling time was recorded andwas equivalent to total restraint time, because sampling timebegan the moment the study animal was initially touched and endedwhen the blood collection tube was filled. All blood samples (8ml) were obtained from the hind flipper, as previously described(23), and were collected into one prechilled heparinized vacutainer.After gentle rocking of the tubes in the shade, they were placedon ice in a portable ice chest until they could be returned tothe lab to be centrifuged, which was within 5-6 h. Blood sampleswere then centrifuged for 15 min (1,500 g at 4°C), and plasmawas collected and frozen at $-$ 20°C for lateranalyses.

Hormone and other plasma analyses. In the present study, cortisol, total triiodothyronine (tT₃), total thyroxine (tT₄), free thyroxine (fT₄), and leptin wereassayed with commercially available RIA kits and were validatedfor NES plasma. All samples were analyzed in duplicate and runin a single assay. Serially diluted pools were significantly parallelto the standard curve for each assay. Characteristics of %recoveryof radioinert hormone from plasma pools and intra-assay %coefficientof variation are summarized in Table 1.

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Table 1. Characteristics of radioimmunoassays

Blood urea nitrogen (BUN), creatinine, cholesterol, glucose, triglycerides, and total proteins were measured on a clinicalautoanalyzer (Roche Diagnostics, Somerville,NJ).

Statistics. Initially, statistical analyses were made to determine whether means changed over time in a linear or logarithmic fashionby producing a best-fit curve for means by regression analysis.If regression analysis did not detect a significant linear orlogarithmic trend, then means at each sampling period were comparedwith that for day 1 by unpaired t-test. Means (±SE) were consideredsignificantly different at P < 0.05, and correlations were consideredsignificant at P < 0.05. All statistical analyses were made usingStatview (27).

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Because animals were sampled in their natural habitat and moved freely about the park, recapturing pups for subsequent bloodsampling on the designated days (especially after the third weekpostweaning) was difficult despite every attempt to find them.Therefore, sample size was reduced after the third week. Bloodsampling times ranged between 2 and 16 min with a mean of 6.5± 0.4 min (n = 61 samples). Plasma cortisol was not positivelycorrelated with blood-sampling time on each designated samplingday or with blood-sampling time collectively over all samplingdays. Significant increases in cortisol, tT₃, and tT₄ were observedover the 49 days, with each hormone exhibiting a linear (Fig.1), parabolic (Fig. 2), or logarithmic (Fig. 2) trend, respectively.tT₃-to-tT₄ ratio decreased linearly over the 49 days (Fig. 2).fT₄ was elevated on days 21 and 49 (Table 1), whereas the percentageof fT₄ to tT₄ remained constant throughout the fast (0.027 ± 0.001%).Means for plasma total proteins and fT₄ were significantly andnegatively correlated over the 49-day period (Fig. 3). Plasmaleptin at the beginning of the fast (day 1, 1.31 ± 0.24 ng/ml)was not significantly altered during the fast (day 35, 1.00 ±0.24 ng/ml). BUN and creatinine were reduced as of day 35 andday 49, respectively (Table 2). Concentrations of plasma cholesteroland glucose were not altered over the fasting period, whereaschanges in triglyceride levels were variable (Table 2).

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Fig. 1. Plasma cortisol over 56 days of fasting in northern elephant seal pups. Filled data points are means ±SE from the present study. Open data points are means ± SE from Houser (14) and were not used to calculate the regression. Numbers in parentheses next to data points denote the sample size (1 sample per animal) for that sampling period. Regression was considered significant at P < 0.05.

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Fig. 2. Means ± SE plasma total triiodothyronine (tT₃) and thyroxine (tT₄) and tT₃-to-tT₄ ratio over 49 days of fasting in northern elephant seal pups. Numbers in parentheses denote the sample size (1 sample per animal) for that sampling period. Regressions were considered significant at P < 0.05.

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Fig. 3. Correlation between mean ± SE plasma total proteins and free thyroxine (fT₄) in fasting northern elephant seal pups. Numbers in parentheses next to data points denote the days of fasting. Regression was considered significant at P < 0.05.

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Table 2. Plasma parameters for 15 northern elephant seal pups sampled during the first 49 days of their postweaning fast

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Although some terrestrial mammals such as hibernating bears (21) or wintering deer (20) experience longer bouts of aphagiaor hypophagia as a natural component of their life history, the12-wk postweaning fast by NES pups initiated at ~30 days of agemay be unrivaled among mammals. In NES pups, many of the physiologicalmechanisms that allow them to withstand such a protracted periodof complete abstinence from food and water so early in life havebeen well described (1, 4, 23, 26). However, the hormonalchanges associated with these mechanisms are not well defined.The present study reports the potential importance of cortisolto the previously reported dependence on fat metabolism that allowsNES pups to fast for prolonged periods as well as the effectsof prolonged fasting on thyroid hormonemetabolism.

Forced fasting in mammals is usually associated with an elevation in glucocorticoids (3, 28), which induce both lipolyticand proteolytic activity to provide substrates for hepatic gluconeogenesis(10). The increase in plasma cortisol in the present study suggeststhat this glucocorticoid may contribute significantly to the reportedincrease in fat oxidation during the fast. The maintenance ofrelatively high glucose concentrations observed in the presentstudy suggests that cortisol may also support carbohydrate metabolism.Pups were previously reported to be insensitive to insulin duringthe fast (15); therefore, glycerol liberated from cortisol-inducedlipolysis may be shuttled into hepatic gluconeogenesis (10,11). Elevated cortisol concentrations may also serve as a cueto terminate fasting and initiate feeding. Increased cortisol-inducedlipolysis may result in fat mass reaching a critical lower limitat the end of the fast that may stimulate the pups to depart fromthe rookery and to begin foraging. Glucocorticoids have been shownto promote feeding behavior by stimulating the hypothalamus (12).

Although elevated glucocorticoids also exhibit proteolytic activity, the reductions in BUN, creatinine, and total proteinsin the present study support the previously reported decreasein protein catabolism in fasting NES pups (1), despite theobserved increase in cortisol. Mean triglycerides in the presentstudy were variable over the 49 days of the fast, but they weresimilar to those previously reported for fasting NES pups, whichwere significantly lower than those for nursing NES pups (7).This reduction in triglycerides suggests that use of triglyceridesby muscle is increased and storage in adipose tissue is decreased.Therefore, it is possible that proteins are protected from proteolysisduring the fast by a tissue-specific increase in lipolysis thatwould spare lean tissue in the presence of elevatedglucocorticoids.

Aside from providing energy via lipolytic pathways, the increase in cortisol observed in the present study may also serveto maintain acid-base homeostasis. The observed increase in cortisolin the present study may contribute to the synthesis of Na⁺/K⁺-H⁺-ATPase as a potential mechanism to abolish metabolic acidosisassociated with fasting, because glucocorticoids have been reportedto regulate renal ATPase transcription (32). The increase inaldosterone over the course of the fast was previously suggestedto contribute to an increase in renal Na⁺/K⁺-H⁺-ATPase, because an increase in Na⁺ and K⁺ resorption from the filtrate was calculated (25) in the presenceof an increase in excreted H⁺ (1). During conditions of acidosis, synthesis of H⁺-related ATPases is increased to correct acid-base imbalances(31, 33). Fasting pups do not exhibit signs of metabolic acidosis(16), which may be attributed to an increase in mineralocorticoid(25)- and glucocorticoid-induced H⁺-related ATPasesynthesis.

The lack of a correlation between cortisol concentrations and blood-sampling time at each sampling period individually andcollectively suggests that the observed increase in cortisol wasinduced by fasting duration and not an artifact of handling stress.Also, mean cortisol concentrations measured previously (14)and independent of our data fall remarkably close to the regressiondetermined in the present study (Fig. 1), further suggesting thatthe increase in plasma cortisol is a consequence of fasting durationand not handlingstress.

Starvation or reduced food intake is typically associated with reduced thyroid hormone concentrations resulting in a decreasein metabolic rate and activity level (5, 9). However, inthe present study, an elevation in tT₃, tT₄, and fT₄ was observedover the course of the fast, despite the previously reported decreasein absolute metabolic rate (26). This elevation in thyroid hormonesduring a period of restricted food intake is not novel amongstmarine mammals. West Indian manatees also exhibited an increasein thyroid hormone concentrations during an acute (19 days) periodof restricted food intake (24). Therefore, the thyroid hormoneresponses observed in the present study and in manatees may betypical of marine mammals during periods of fasting or reducedfood availability, which is a normal component of their lifehistory.

The observed increases in both total and free thyroid hormones may not reflect increased synthesis and release, but ratheralterations in clearance from circulation, in binding kineticsof the free fraction, and/or in deiodination. In hibernating groundsquirrels (Spermophilus richardsoni), the increase in thyroxine(T₄) was attributed to greatly reduced clearance rates (8),which may be likely in the present study. Also, hibernating squirrelsexhibited an increase in total thyroid hormones that was attributedto an increase in binding capacity and affinity, because the percentageof free fraction was reduced (18). However, in the present study,the percentage of fT₄ to tT₄ was not changed when total proteinconcentrations were reduced, suggesting that the free fractionwas increased due to a decrease in binding proteins (17, 29).The decrease in tT₃-to-tT₄ ratio over the 49 days is similar tothat observed in food-restricted manatees (24) and suggeststhat deiodination of T₄ was decreased (30, 34). Reduced deiodinationmay serve as a mechanism to protect target tissues from the oxygen-demandingprocesses induced by the cellular actions of triiodothyronine(T₃) (22). Therefore, the increase in thyroid hormones duringthe postweaning fast in NES pups appears to be associated collectively,or in part, with 1) a decrease in clearance from circulation,2) a decrease in binding of the free fraction, and 3) a decreasein deiodination of T₄.

The presence of elevated thyroid hormones in circulation may permissively support fat metabolism via their lipolytic functions.The permissive effects of thyroid hormones on lipolysis have beenwell documented (5). Therefore, the elevated concentrationsof thyroid hormones suggest that these hormones may also be involvedin fat metabolism. However, the hormones can only be functionalif the number of nuclear receptors they bind is not significantlyreduced during the fast. Hibernating squirrels also exhibitedincreased thyroid hormones during hibernation, however, a reductionin nuclear receptors makes the squirrels resistant to the actionsof the hormones, primarily T₃ (19).

Prolonged fasting results in a reduction in body mass and body fat, which is known to induce a decrease in circulating leptinconcentrations in mammals (2, 6). During the postweaningfast in NES pups, body mass and body fat content are reduced (26),however, a significant decrease in plasma leptin was not detectedin the present study. This relationship between reduced body fatand unaltered leptin concentrations suggests that in fasting pups,leptin may not be significantly involved in the regulation ofbody fat or in alleviating the inhibition on neuropeptide Y, whichinitiates the signal to begin feeding (2, 6). Leptin concentrationsin the present study are the first reported for any marine mammaland are similar to those reported for fasted mice (2) and onthe lower range for lean humans (6).

In summary, cortisol increased linearly over at least the first 8 wk of fasting (including cortisol data from Ref. 14),whereas total and free thyroid hormones increased significantlyafter the first week of fasting and remained elevated at leastuntil the seventh week. The increase in cortisol likely contributedto the previously reported increase in fat metabolism (4, 23)and may play a significant role in carbohydrate metabolism viagluconeogenesis as indicated by the relatively high and constantglucose concentrations observed during the 7 wk of the fast. Therefore,cortisol may have replaced the pancreatic hormones in regulatingcarbohydrate metabolism and leptin as a potential cue to terminatefasting and initiate feeding. Elevated thyroid hormone concentrationsduring the fast in NES pups may be the consequence of decreasedclearance and deiodination. Leptin does not appear to play a significantrole in fat metabolism or in signaling the termination of thefast to initiate feeding. The present study suggests that 1) cortisolplays an integral part in the regulation of fat and, very likely,carbohydrate metabolism during the postweaning fast in NES pupsand 2) thyroid hormone kinetics and metabolism are altered duringthe fast in a similar manner to hibernation in othermammals.

Perspectives

The complete abstinence from food and water may fall under one of three physiological conditions: 1) force fasting (starvation),2) hibernation, and 3) natural fasting. Although humans and rodentsmay be acutely fasted, they quickly begin to exhibit pathologicalsigns of starvation. Hibernating mammals do not generally exhibitsigns of starvation, however, they remain metabolically quiescent.Seals do not exhibit the pathologies of starvation (except forprematurely weaned pups) while remaining metabolically activethroughout the course of their prolonged fasting periods. Thesedistinctions must be made when comparing the physiological responsesto abstinence of food and water. However, little data exist onthe endocrine changes in metabolically active, naturally fastingmammals. The focus of the present study was to observe the effectsof prolonged fasting under natural conditions on hormones notpreviously examined to help elucidate the physiological adaptationsunderlying this remarkable fast. The endocrine responses observedin the present study are most similar to those for hibernatingmammals (Table 3) (8, 18, 19, 21), suggesting that animalsthat experience extended periods of restricted dietary intakeas a natural component of their life history have adapted physiologicallyin a similar manner. Postweaned elephant seal pups provide aninteresting model to study the endocrinology in a metabolicallyactive mammal fasting for an extended period under natural conditions.

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Table 3. Summary of generalized changes in cortisol and thyroid hormones associated with starvation in humans, hibernation in squirrels or bats, and fasting in northern elephant seal pups (this study)

	ACKNOWLEDGEMENTS

We thank D. S. MacKenzie for reviewing this manuscript. We also thank D. Crocker, D. Houser, S. Kohin, D. Noren, P. Webb,and the many students of the winter field class (Biology 141)from the Univ. of California Santa Cruz (UCSC) for assistancethroughout thestudy.

	FOOTNOTES

This research was supported by National Institutes of Health Minority Access to Research Careers Grant GM 58903-01 (C. L.Ortiz), National Aeronautics and Space Administration (NASA) GraduateStudent Research Program NGT-2-52230 (R. M. Ortiz), and NASA Grants121-10-50 and 121-40-10 (C. E.Wade).

This research was conducted in partial fulfillment of the requirements for the doctorate degree in biology for R. M. Ortiz.Research was conducted under National Marine Fisheries Servicemarine mammal permit #836 to C. L. Ortiz and UCSC Chancellor'sAnimal Research Committee permit Orti89.08 to C. L. Ortiz andR. M.Ortiz.

Address for reprint requests and other correspondence: R. M. Ortiz (E-mail: rortiz{at}mail.arc.nasa.gov).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

Received 10 July 2000; accepted in final form 31 October 2000.

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