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Long-term adaptation capacity of ponies: effect of season and feed restriction on blood and physiological parameters

Published online by Cambridge University Press:  10 July 2017

L. Brinkmann
Affiliation:
Department of Animal Sciences, University of Göttingen, Albrecht-Thaer Weg 3, 37075 Göttingen, Germany
A. Riek*
Affiliation:
Department of Animal Sciences, University of Göttingen, Albrecht-Thaer Weg 3, 37075 Göttingen, Germany
M. Gerken
Affiliation:
Department of Animal Sciences, University of Göttingen, Albrecht-Thaer Weg 3, 37075 Göttingen, Germany
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Abstract

Domesticated horses are increasingly kept under semi-natural housing conditions, whereas their adaptation capacity is not fully investigated. In all, 10 Shetland pony mares were held under semi-extensive conditions for 1 year. In winter animals were allocated into two feeding groups (60% and 100% of maintenance energy requirement, respectively). Triiodothyronine, thyroxine, non-esterified fatty acids (NEFA), total bilirubin, total protein, triglyceride, glucose, insulin and hair length were measured at monthly intervals, whereas BW, body condition score, cresty neck score and resting heart rate were recorded every 2 weeks. From summer to winter all Ponies showed a reduction in resting heart rate (P<0.001) and triiodothyronine (P<0.001) but an increase in NEFA (P<0.001), thyroxine (P<0.001) and triglyceride (P<0.001) concentrations. Feed restriction led to a reduced resting heart rate (P=0.009), increased NEFA (P<0.001) and total bilirubin (P=0.008) concentrations. Thyroid hormones did not differ between feeding groups (P>0.05). Refeeding of restrictively fed ponies resulted in a rapid increase in resting heart rate and BW and a return of blood parameters to reference values. Adequately supplied animals adapted without difficulty to varying environmental conditions, whereas feed restriction in ponies during winter resulted in reduced resting heart rates suggesting a reduced basal metabolic rate. The energy restriction was compensated by mobilizing body fat reserves which led to changes in blood parameters. Refeeding in feed restricted animals revealed a remarkably quick recovery of physiological and blood parameters to reference values. We therefore suggest that year round-outdoor housing can be a suitable housing system for robust horse breeds provided that an adequate food supply is available.

Type
Research Article
Copyright
© The Animal Consortium 2017 

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References

Arnold, W, Ruf, T and Kuntz, R 2006. Seasonal adjustment of energy budget in a large wild mammal, the Przewalski horse (Equus ferus przewalskii) II. Energy expenditure. Journal of Experimental Biology 209, 45664573.Google Scholar
Autio, E, Neste, R, Airaksinen, S and Heiskanen, ML 2006. Measuring the heat loss in horses in different seasons by infrared thermography. Journal of Applied Animal Welfare Science 9, 211221.Google Scholar
Breuhaus, BA 2002. Thyroid-stimulating hormone in adult euthyroid and hypothyroid horses. Journal of Veterinary Internal Medicine 16, 109115.Google Scholar
Brinkmann, L, Gerken, M, Hambly, C, Speakman, JR and Riek, A 2014. Saving energy during hard times: energetic adaptations of Shetland pony mares. Journal of Experimental Biology 217, 43204327.Google ScholarPubMed
Brinkmann, L, Gerken, M, Hambly, C, Speakman, JR and Riek, A 2016. Thyroid hormones correlate with field metabolic rate in ponies, Equus ferus caballus . Journal of Experimental Biology 219, 25592566.Google Scholar
Carroll, C and Huntington, P 1988. Body condition scoring and weight estimation of horses. Equine Veterinary Journal 20, 4145.CrossRefGoogle ScholarPubMed
Carter, RA 2005. Thyroid status in exercising horses and laminitic ponies. Master thesis, Virginia Polytechnic Institute and State University, Blacksburg, VA, USA.Google Scholar
Carter, RA, Geor, RJ, Staniar, WB, Cubitt, TA and Harris, PA 2009. Apparent adiposity assessed by standardised scoring systems and morphometric measurements in horses and ponies. Veterinary Journal 179, 204210.Google Scholar
Clarke, A 1991. Cold adaptation. Journal of Zoology 225, 691699.Google Scholar
Craik, DJ, Duggan, BM and Munro, SLA 1996. Conformations and binding interactions in thyroid hormones and analogues. In Biological inhibitors, studies in medical chemistry (ed. M Iqbal Chaudhary), p. 288. Harwood Academic Publishers, Amsterdam, the Netherlands.Google Scholar
Currie, SE, Körtner, G and Geiser, F 2014. Heart rate as a predictor of metabolic rate in heterothermic bats. Journal of Experimental Biology 217, 15191524.Google Scholar
Cymbaluk, NF and Christison, GI 1990. Environmental effects on thermoregulation and nutrition of horses. Veterinary Clinic of North America: Equine Practice 6, 355372.Google Scholar
Dugdale, AHA, Curtis, GC, Cripps, P, Harris, PA and Argo, CM 2010. Effect of dietary restriction on body condition, composition and welfare of overweight and obese pony mares. Equine Veterinary Journal 42, 600610.CrossRefGoogle ScholarPubMed
Ekpe, E and Christopherson, R 2000. Metabolic and endocrine responses to cold and feed restriction in ruminants. Canadian Journal of Animal Science 80, 8796.Google Scholar
Elliott, K, Welcker, J and Gaston, A 2013. Thyroid hormones correlate with resting metabolic rate, not daily energy expenditure, in two charadriiform seabirds. Biology Open 2, 580586.Google Scholar
Feldt-Rasmussen, U and Rasmussen, ÅK 2007. Thyroid hormone transport and actions. Archives of Pediatrics and Adolescent Medicine 11, 80103.Google Scholar
Hebert, JM, Rosenquist, T, Gotz, J and Martin, GR 1994. FGF5 as a regulator of the hair growth cycle: Evidence from spontaneous and targeted mutations. Cell 78, 10171025.Google Scholar
Johnson, HD, KaLli, PS, Hahn, L and Shanklin, MD 1988. Short-term heat acclimation effects on hormonal profile of lactating cows. University of Missouri Research Bulletin Nr. 1061. University of Missouri, Columbia, MO, USA.Google Scholar
Kienzle, E, Coenen, M and Zeyner, A 2010. Maintenance metabolisable energy requirements in horses. Übersichten Tierernährung 38, 3354.Google Scholar
Kraft, W and Dürr, UM 2005. Klinische Labordiagnostik in der Tiermedizin, 6th edition. Schattauer, Stuttgart, Germany.Google Scholar
Kronfeld, DS, Treiber, KH, Hess, TM and Boston, RC 2005. Insulin resistance in the horse: Definition, detection, and dietetics. Journal of Animal Science 83, E22E31.CrossRefGoogle Scholar
Laboklin 2016. Normwerte Hund, Katze, Pferd, Rind. Retrieved on 22 June 2016 from http://www.laboklin.de/pages/html/de/leistungsspektrum/referenzwerte/referenzwert_hdktz.htm Google Scholar
Langlois, B 1994. Inter-breed variation in the horse with regard to cold adaptation: a review. Livestock Production Science 40, 17.Google Scholar
Lim, CF, Munro, SL, Wynne, KN, Topliss, DJ and Stockigt, JR 1995. Influence of nonesterified fatty acids and lysolecithins on thyroxine binding to thyroxine-binding globulin and transthyretin. Thyroid 5, 319324.Google Scholar
MacLean, PS, Higgins, JA, Jackman, MR, Johnson, GC, Fleming-Elder, BK, Wyatt, HR, Melanson, EL and Hill, JO 2006. Peripheral metabolic responses to prolonged weight reduction that promote rapid, efficient regain in obesity-prone rats. American Journal of Physiology. Regulatory, Integrative and Comparative Physiology 290, R1577R1588.Google Scholar
McBride, G, Christopherson, R and Sauer, W 1985. Metabolic rate and plasma thyroid hormone concentrations of mature horses in response to changes in ambient temperature. Canadian Journal of Animal Science 65, 375382.Google Scholar
Mejdell, C and Bøe, K 2005. Responses to climatic variables of horses housed outdoors under Nordic winter conditions. Canadian Journal of Animal Science 85, 301308.CrossRefGoogle Scholar
Meyer, H and Coenen, M 2014. Pferdefütterung, 5th edition. Enke Verlag, Stuttgart, Germany.Google Scholar
Mogg, TD and Palmer, JE 1995. Hyperlipidemia, hyperlipemia, and hepatic lipidosis in American miniature horses: 23 cases (1990–1994). Journal of the American Veterinary Medical Association 207, 604607.Google Scholar
Naylor, J, Kronfeld, D and Johnson, K 1980. Fasting hyperbilirubinemia and its relationship to free fatty-acids and triglycerides in the horse. Proceedings of the Society for Experimental Biology and Medicine 165, 8690.Google Scholar
Price, EO 1984. Behavioral aspects of animal domestication. The Quarterly Review of Biology 59, 132.Google Scholar
Robinson, NE, Karmaus, W, Holcombe, SJ, Carr, EA and Derksen, FJ 2006. Airway inflammation in Michigan pleasure horses: prevalence and risk factors. Equine Veterinary Journal 38, 293299.CrossRefGoogle ScholarPubMed
Rudman, R and Keiper, RR 1991. The body condition of feral ponies on Assateague Island. Equine Veterinary Journal 23, 453456.Google Scholar
Russel, AJF and Redden, HL 1997. The effect of nutrition on fibre growth in the alpaca. Animal Science 64, 509512.CrossRefGoogle Scholar
Sticker, L, Thompson, D, Bunting, LD, Fernandez, JM, Depew, CL and Nadal, MR 1995. Feed deprivation of mares: plasma metabolite and hormonal concentrations and responses to exercise. Journal of Animal Science 73, 36963704.Google Scholar
Suagee, JK, Burk, AO, Quinn, RW, Petersen, ED, Hartsock, TG and Douglass, LW 2008. Effects of diet and weight gain on body condition scoring in thoroughbred geldings. Journal of Equine Veterinary Science 28, 156166.Google Scholar
Summermatter, S and Handschin, C 2012. PGC-1α and exercise in the control of body weight. International Journal of Obesity 36, 14281435.CrossRefGoogle ScholarPubMed
Suwannachot, P, Verkleij, CB, Kocsis, S, Enzerink, E and Everts, ME 2000. Prolonged food restriction and mild exercise in Shetland ponies: effects on weight gain, thyroid hormone concentrations and muscle Na+,K+-ATPase. Journal of Endocrinology 167, 321329.Google Scholar
Suzuki, Y, Nanno, M, Gemma, R and Yoshimi, T 1992. Plasma free fatty acids, inhibitor of extrathyroidal conversion of T4 to T3 and thyroid hormone binding inhibitor in patients with various nonthyroidal illnesses. Endocrinologia Japonica. 39, 445453.CrossRefGoogle ScholarPubMed
Zeitler-Feicht, MH 2013. Tiergerechte Haltungsverfahren für Sport und Freizeitpferde gemäß den Leitlinien des BMELV. Pferdeheilkunde 29, 476484.Google Scholar