Body mass, thermogenesis and energy metabolism in Tupaia belangeri during cold acclimation

Автор: Zhu Wan-Long, Meng Lihua, Wang Zheng-Kun

Журнал: Журнал стресс-физиологии и биохимии @jspb

Статья в выпуске: 2 т.8, 2012 года.

Бесплатный доступ

In order to study the relationship between energy strategies and environmental temperature, basal metabolic rate (BMR), nonshivering thermogenesis (NST), the total protein contents, mitochondrial protein contents, state Ⅲ and state Ⅳ respiratory ability, cytochrome C oxidase activity of liver, heart, diaphragm, gastrocnemius and brown adipose tissue (BAT), serum leptin level and serum thyroid hormone levels were measured in tree shrews (Tupaia belangeri) during cold exposure (5±1oC) for 1 day, 7 days,14days,21 days. The results showed that body mass increased, BMR and NST increased, the change of liver mitochondrial protein content was more acutely than total protein. The mitochondrial protein content of heart and BAT were significantly increased during cold-exposed, however the skeletal muscle more moderate reaction. The state Ⅲ and state Ⅳ mitochondrial respiration of these tissues were enhanced significantly than the control. The cytochrome C oxidase activity with cold acclimation also significantly increased except the gastrocnemius. Liver, muscle, BAT, heart and other organs were concerned with thermoregulation during the thermal regulation process above cold-exposed. There is a negative correlation between leptin level and body mass. These results suggested that T. belangeri enhanced thermogenic capacity during cold acclimation, and leptin participated in the regulation of energy balance and body weight in T. belangeri.

Еще

Tupaia belangeri, adaptive thermogenesis, cold-exposure

Короткий адрес: https://sciup.org/14323617

IDR: 14323617

Список литературы Body mass, thermogenesis and energy metabolism in Tupaia belangeri during cold acclimation

Abelenda M, Ledesma A, Rial E, Puerta M. (2003). Leptin administration to cold-acclimated rats reduces both food intake and brown adipose tissue thermogenesis. J.Therm.Biol. 28: 525-530.
Barb C.R., Kraeling R.R., (2004). Role of leptin in the regulation of gonadotropin secretion in farm animals. Anim Reprod Sci, 82-83: 155-167.
Bianco AC, Kieffer JD, Silva JE. (1992). Adenosine 3',5'-Monophosphate and thyroid hormone control of uncoupling protein messenger ribonucleic acid in freshly dispersed brown adipocytes. Endocrinology. 130 (5): 2625 -2633.
Bozinovic F. (1992). Rate of basal metabolism of grazing rodents from different habitats. J Mamm 73 (2): 379-384.
Brand MD, Couture P, Else PL, Withers KW, Hulbert AJ. (1991). Evolution of energy metabolism. Biochem. J. 275: 81-86.
Brzezinska-Slebodzinska E, Slebodzinski AB. (1993). Cold indued changes of thryroxine 5'-and 5-monodeiodinase activity in brown adipose tissue of neonatal rabbits.implications for thermogenesis. J. ther. Biol, 18 (4): 189 -195.
Cannon B, Lindberg O. (1979). Mitochondria from adipose tissue: Isolation and properties. Methods in Enzymology Vol. LV, Academic Press. New York. pp. 65-78.
Chaffee RRJ, Kaufman WC, Kratochvil CH, Sorenson MW, Conaway CH, Middleton CC. (1969). Comparative chemical thermregulation in cold-and heat-acclimated rodents, insectivores, protoprimates, and primates. Federation Proceedings. 28 (3): 1029-1034.
Claussen T, Hardeveld CV, Everts ME. (1991). Significance of cation transport in vontrol of energy metabolism and thermogenesis. Physiol. Review. 71 (3): 733-773.
Ernest SKM. (2005). Body size, energy use, and community structure of small mammals. Ecology, 86 (6):1407-1413.
Friedman JM, Hallas JL, (1998). Leptin and the regulation of body weight in mammals. Nature 395: 763 -770.
Gogllia F, Lanni A, Duchamp C, Rouanet JL, Barre H. (1993). Effest of cold acclimation on oxidative capacity and respiratory properties of liver and muscle mitochondria in dunckings, Cairina moschata. Comp. Biochem Physiol, 106B (1): 95-101.
Gordon CJ. (1993). Temperature regulation in laboratory rodents. Cambridge University Press. pp. 1-276.
Grodzinski W, Klekowski RZ, Duncan A. (1975). Methods for ecological bioenergetics. Page 309-333.
Haim A, Izhaki H. 1993. The ecological significance of resting metabolic rate and nonshivering thermogenesis for rodents. J Therm. Biol., 17 (6):347-351.
Heldmaier G, Steinlechner S, Rafael J, (1982). Nonshivering thermogenesis and cold resistance during seasonal acclimatization in the Djungarian hamster. J Comp Physiol 149B:1 -9.
Himms-Hagen J. (1990). Brown adipose tissue thermogenesis: interdisciplinary studies. FASEB J. 4:2890-2893.
Hill RW. 1972. Determination of oxygen consumption by use of the paramagnetic oxygen analyzer. J Applied Physiology 33 (2):261-263
Hirata K, Nagasaka T. (1981). Calorigenic and cardiovascular responses to norepinephrine in anesthetized and unanesthetized control and cold-acclimated rats. Jpn J Physiol. 31 (3):305-16.
Hukshorn C.J., Saris W.H., ().Leptin and energy expenditure. Curr Opin Clin Nutr Metab Care,7:629-633.
Jaccobsson A, Muhleisen M, Cannon B, Nedergaad J. (1994). The uncoupling thermogenin during acclimation: indications for pretraslational control. Am. J. Physiol., 267:R999-R1007.
Jacobs L L. Siwalik fossil tree shrews. In: Luckett W P ed. Comparative Biology and Evolutionary Relationships of Treeshrews. New York and London:Pleunm Preww,1980, 205-216
Jones R, Henshen L, Mohell N, Nedergaard J. (1986). Requirement of gene transcription and protein sythesis deiodinase for cold-and norepinephrine-induced stimulation of thyroxine deiodinase in rat brown adipose tissue. Biochemca et Biophysica Acta. 889:366-373.
Johnstone AM, Murison SD, Duncan JS, Rance KA, Speakman JR. (2005). Factors influencing variation in basal metabolic rate include fat-free mass, fat mass, age, and circulating thyroxine but not sex, circulating leptin, or triiodothyronine. Am. J. Clin. Nutr. 82, 941-948
Karasov WH. (1986). Energetics, physiology and vertebrate ecology. Trends Ecol Evol 1: 101-104.
Kluas S, Casteilla L, Bouillaud F, Ricquier D. (1991). Minireview: The uncoupling protein UCP: a mambraneous mitochondrial ion carrier exclusively expressed in brown adipose tissue. Int J Biochem. 23:791-801.
Lanni A, Martins R, Ambid L, Goglia F. (1990). Liver and brown fat mitochondrial response to cold in the garden dormouse (Eliomys quercinus). Comp Biochem Physiol B. 97 (4):809-13.
Leach BJ, Bauman TR, Turner CW. (1962). Thyroxine secretion rate of Missouri Valley mole, Scalopus aquaticus. Proceedings of the Society for Experimental Biology and Medicine, 110: 681-682.
Li XS, Wang DH, Yang M. (2004). Effects of cold acclimation on body mass, serum leptin level, energy metabolism and thermogenesis in Mongolian gerbil (Meriones unguiculatus). Acta Zoologica Sinica, 50 (3): 334-340.
McDevitt RM, Speakman JR. (1994a). Limits to sustainable metabolic rate during transient exposure to temperatures in short-tailed voles (Microtus agrestis). Physiol. Zool., 67 (5):1103-1116.
McDevitt RM, Speakman JR. (1994b). Central limits to sustainable metabolic rate have not role in cold acclimation of short-tailed field voles. Physiol. Zool., 67 (5):1117-1140.
McNabb FMA. (1992). Thyroid Hormones. Englewood Cliffs, NJ: Prentice Hall.
McNabb FMA. (1995). Thyroid-hormones, their activation, degra-dation and effects on metabolism. J Nutr. 125:S1773-S1776.
McNab BK. (1995). Energy expenditure and conservation in frigivorous and mixed diet carnivorans. J. Mammal 76 (1):206-222.
Nagy N, Negus NC. 1993. Energy acquisition and allocation in male collared lemmings (Dicrastonys groenlandlcus): effects of photoperiod, temperature, and diet quality. Physiol Zool, 66:537-560.
Nieminen P, Hyvarinen H, (2000). Seasonality of leptin levels in the BAT of the common shrew Sorex araneus. Verlag der Zeitschrift fur Naturforschung 55: 455 -460.
Olson LE, Sargis EJ, Martin RD. (2005) Intraordinal phylogenetics of treeshrews (Mammalia: Scandentia) based on evidence from the mitochondrial 12S rRNA gene. Molecular Phylogenetics and Evolution, 35: 656-673.
Oufara S, Barre H, Rouanet JL, Chatonnet J. (1987). Adaptation to extreme ambient temperatures in cold-acclimated gerbils and mice. Am. J. Physiol, 253:R39-R45.
Oufara S, Rouanet JL, Rouanet J L. (1988). Great adaptability of brown adipose tissue mitochondria to extreme ambient temperaturees in control and clod-acclimated gerbils as compared with mice. Com BP, 90:209-214.
Pazos-Moura CC, Moura EG, Dorris ML, Rehnmark S, Melendez L, Silva JE, Taurog A. (1991). Effect of iodine deficiency and cold exposure on 5'-deiodinase activity in various rat tissues. Am. J. Physiol., 260:E175-E182.
Praun C V, Burkert M, Gessner M, Klingenspor M. (2001). Tissue-specific expression and cold-induced mRNA levels of uncoupling proteins in the Djungarian hamster. Physiol. Biochem. Zool. 74 (2):203-211.
Raasmaja A. (1990). ?1-and ?-adrenergic recetors in brown adipose tissue and the adrenergic rugulation of thyroxine 5'-deiodonase. Acta Physiolgica Scandinavia 139, Supplementum 590:1-61.
Rabelo R, Schifman A, Rubio A, Sheng X, Siva J E. (1995). Delineation of thyroid hornome-responsvie sequencs within a critical enhancer in the rat uncoupling gene. Endocrinology. 136 (3):1003-1013.
Silva JE. (2006). Thermogenic mechanisms and their hormonal regulation. Physiol Rev, 86:435-464.
Speakman JR, Ergon T, Cavanagh R, Reid K, Scantlebury DM, Lambin X. (2003). Rest and daily energy expenditures of free-living field voles are positively correlated but reflect extrinsic rather than intrinsic effects. PNAS, 100 (24):14057-14062.
Speakman JR. (200) 7. The energy cost of reproduction in small rodents. Acta Theriologica Sinica, 27 (1):1-13.
Sundin U, Moore G, Nedergaard J, Cannon B. (1987). Thermogenesis amount and activity in hamster brown fat mitochondria: effect of cold acclimation. Am. J. Physiol., 252:R822-832.
Swanson DL, (2001). Are summit metabolism and thermogenic endurance correlated in winter-acclimatized passerine birds? Comp Physiol B 171:475 -481.
Tomasi TE. (1991). Utilization rates of thyroid hormones in mammals. Comp. Biochem. Physiol., 100A:503-516.
Tomasi TE, Michell DA. (1994). Seasonal shifts in thyroid function in the cotton rat (Sigmodon hispidus). J. Mammalogy. 75 (2):520-528.
Thomposon M.P., K. Singh, M. Canham, M.R. Grigor, J. MvEwan. (1989). Brown adipose tissue in lean and fat selection lines of sheep identified by immunodetectionof uncoupling protein in western blots of tissue homogenates. Comp. Biochem. Physiol., 94 (3):493-498.
Wang YX, Li CY, Ma SL. (1991). Class and zoology of Tupaia belangeri. In Peng YZ eds. Biology of Tupaia belangeri. Kunming, Yunnan Science and technology Press, 21-70.
Wang ZK, Sun RY, Li QF, Fang JM. (1994). Characteristics of the resting metabolic rate of the tree shrews (Tupaia belangeri). Acta Theriologica Sinica, 30 (3):408-414
Wang ZK, Li QF, Sun RY. (1995). Characteristics of the nonshivering thermogenesis and cellular respiration in the tree shrews. Zool Res, 16 (3):239-248
Wang ZK, Li QF, Sun RY, Liu L. (1999). Effects of photoperiod and temperature on thermogenesis in the tree shrews (Tupaia belangeri). Acta Zool Sin, 45 (3):287-293.
Wang ZK, Li QF, Sun RY. (2000). Effects of exogenous metatonin on the adaptive thermogenesis in the tree shrews (Tupaia belangeri). Acta Zool Sin, 46 (2):154-159.
Zhang WX, Wang ZK, Nian YK, Xu WJ, Yao Z. (2001). The effects of cold acclimation on thermogenesis in tree shrews (Tupaia belangeri). Zool Res, 22 (4):287-291.
Zhang WX, Wang ZK, Xu WJ, Yao Z, Nian YK. (2002). The effects of cold-acclimation on the metabolic of energy in Tupaia belangeri. Acta Theriologica Sinica 22 (2):123-129.
Zhang XY, Wang DH. (2006). Energy metabolic, thermogenesis and body mass regulation in Brandt's voles (Lasiopodomys brandtii) during cold acclimation and rewarming. Hormones and Behavior, 50:61-69
Zhao ZJ, Wang DH. (2005). Short photoperiod enhances thermogenic capacity in Brandt's voles. Physiol. Behav. 85 (2):143-149.
Zhao ZJ, Wang DH. (2006a). Effects of photoperiod on energy budgets and thermogenesis in Mongolian gerbils Meriones unguiculaus. J. Therm. Biol. 31:323-331.
Zhao ZJ, Wang DH. (b).Short photoperiod influences energy intake and serum leptin level in Brandt'voles Microtus brandtii. Horm. Behav. 49:463-469.

Еще

Статья научная