Influence of Atmospheric Ammonia on Serum Corticosterone, Estradiol-17β and Progesterone in Laying Hens
DOI:
https://doi.org/10.3923/ijps.2015.427.435Keywords:
Ammonia, corticosterone, layers, progesterone, estradiol-17βAbstract
Hormonal profiles of hens in curtain side-walled high-rise deep pit and flush-waste layer houses were initiated at placement of hens in cages in August and continued through a 50 weeks long laying trial. In mid-January, a cold weather-related incident caused the rupture of water lines and flooding of the manure pits in the deep pit layer house, allowing atmospheric ammonia to rise to a high of 135±29 ppm and remain high through mid-February when the pits were finally emptied. After removal of wet manure from the deep pit, atmospheric ammonia in the deep pit house decreased to 25±9 ppm compared to 21±4 ppm in the flush-waste house. Elevated atmospheric ammonia in the deep pit house caused the hens, compared to hens in the flush-waste house, to increase significantly (p<0.05) their serum corticosterone from mid-January through February followed by a decrease until June when it increased again in response to high summer temperatures. Serum progesterone and estradiol-17β in those hens in the deep pit house decreased significantly (p<0.05) in response to elevated atmospheric ammonia. Egg production of hens in the deep pit house was decreased from mid-January through February (p<0.05) followed by a slight rebound in March. Overall egg production remained lower in the deep pit house compared to production in the flush-waste house through July. Elevated atmospheric ammonia is a strong stressor, which will induce increased serum corticosterone that leads to loss of egg production associated with decreased serum concentrations of serum estradiol-17β and progesterone.
References
Anderson, K.E., G.B. Havenstein and J. Brake, 1995. Effects of strain and rearing dietary regimens on brown-egg pullet growth and strain, rearing dietary regimens, density and feeder space effects on subsequent laying performance. Poult. Sci., 74: 1079-1092.
Anderson, K.E., G.B. Havenstein, P.K. Jenkins and J. Osborne, 2013. Changes in commercial laying stock performance, 1958-2011: Thirty-seven flocks of the North Carolina random sample and subsequent layer performance and management tests. World's Poult. Sci. J., 69: 489-513.
Beuving, G. and G.M.A. Vonder, 1977. Daily rhythm of corticosterone in laying hens and the influence of egg laying. J. Reprod. Fert., 51: 169-173.
Beuving, G. and G.M.A. Vonder, 1978. Effect of stressing factors on corticosterone levels in the plasma of laying hens. Gen. Comp. Endocrinol., 35: 153-159.
Beuving, G. and G.M.A. Vonder, 1981. The influence of ovulation and oviposition on corticosterone levels in the plasma of laying hens. Gen. Comp. Endocrinol., 44: 382-388.
Bray, D.J. and J.A. Gesell, 1961. Studies with corn-soya laying diets 4. Environmental temperature-A factor affecting performance of pullets fed diets suboptimal in protein. Poult. Sci., 40: 1328-1335.
CDC., 2005. NIOSH pocket guide to chemical hazards: Ammonia. Centers for Disease Control and Prevention, Atlanta, GA., USA. http://www.cdc.gov/niosh/npg/npgd0028.html.
Charles, D.R. and C.G. Payne, 1966. The influence of graded levels of atmospheric ammonia on chickens. I. Effects on respiration and on the performance of broilers and replacement growing stock. Br. Poult. Sci., 7: 177-187.
Charles, D.R. and C.G. Payne, 1966. The influence of graded levels of atmospheric ammonia on chickens. II. Effects on the performance of laying hens. Br. Poult. Sci., 7: 189-198.
Ciccone, N.A., I.C. Dunn, T. Boswell, K. Tsutsui, T. Ubuka, K. Ukena and P.J. Sharp, 2004. Gonadotrophin inhibitory hormone depresses gonadotrophin α and follicle‐stimulating hormone β subunit expression in the pituitary of the domestic chicken. J. Neuroendocrinol., 16: 999-1006.
Deaton, J.W., F.N. Reece and B.D. Lott, 1984. Effect of atmospheric ammonia on pullets at point of lay. Poult. Sci., 63: 384-385.
Deaton, J.W., F.N. Reece and B.D. Lott, 1982. Effect of atmospheric ammonia on laying hen performance. Poult. Sci., 61: 1815-1817.
De Groef, B., K. Vandenborne, P. Van As, V.M. Darras, E.R. Kuhn, E. Decuypere and K.L. Geris, 2005. Hypothalamic control of the thyroidal axis in the chicken: Over the boundaries of the classical hormonal axes. Domestic Anim. Endocrinol., 29: 104-110.
Edens, F.W., 1978. Adrenal cortical insufficiency in young chickens exposed to a high ambient temperature. Poult. Sci., 57: 1746-1750.
Edens, F.W. and H.S. Siegel, 1975. Adrenal responses in high and low ACTH response lines of chickens during acute heat stress. Gen. Comp. Endocrinol., 25: 64-73.
Edens, F.W., G.A. Martin and T.A. Carter, 1984. Housing and seasonal influences on commercial caged layers. I. Corticosterone levels. Archiv Geflugelkunde J., 48: 121-125.
Harvey, S., J.G. Phillips, A. Rees and T.R. Hall, 1984. Stress and adrenal function. J. Exp. Zool., 232: 633-645.
Henriksen, R., T.G. Groothuis and S. Rettenbacher, 2011. Elevated plasma corticosterone decreases yolk testosterone and progesterone in chickens: Linking maternal stress and hormone-mediated maternal effects. PloS ONE, Vol. 6.
Hester, P.Y., W.M. Muir, J.V. Craig and J.L. Albright, 1996. Group selection for adaptation to multiple-hen cages: Production traits during heat and cold exposures. Poult. Sci., 75: 1308-1314.
Kirby, E.D., A.C. Geraghty, T. Ubuka, G.E. Bently and D. Kaufer, 2009. Stress increases putative gonadotropin inhibitory hormone and decreases luteinizing hormone in male rats. Proc. Nat. Acad. Sci., 106: 11324-11329.
Kristensen, H.H., L.R. Burgess, T.G.H. Demmers and C.M. Wathes, 2000. The preferences of laying hens for different concentrations of atmospheric ammonia. Applied Anim. Behav. Sci., 68: 307-318.
Liang, Y., H. Xin, R.S. Gates and E.F. Wheeler, 2003. Updates on ammonia emission from Iowa layer houses. Proceedings of the Iowa Egg Industry Symposium, November 7, 2003, Ames, IA., USA., pp: 1331-1342.
Liu, L., Z. Song, A. Sheikhahmadi, H. Jiao and H. Lin, 2012. Effect of corticosterone on gene expression of feed intake regulatory peptides in laying hens. Comp. Biochem. Physiol. Part B: Biochem. Mol. Biol., 162: 81-87.
Mahmoud, K.Z., M.M. Beck, S.E. Scheideler, M.F. Forman, K.P. Anderson and S.D. Kachman, 1996. Acute high environmental temperature and calcium-estrogen relationships in the Hen. Poult. Sci., 75: 1555-1562.
Martin, G.A., 1983. Final summary report: Twenty Third North Carolina random sample laying test. Vol. 23, North Carolina Agricultural Extension Service, Raleigh, NC., USA.
Mashaly, M.M., G.L. Hendricks, M.A. Kalama, A.E. Gehad, A.O. Abbas and P.H. Patterson, 2004. Effect of heat stress on production parameters and immune responses of commercial laying hens. Poult. Sci., 83: 889-894.
Mumma, J.O., J.P. Thaxton, Y. Vizzier-Thaxton and W.L. Dodson, 2006. Physiological stress in laying hens. Poult. Sci., 85: 761-769.
OSHA., 2006. Ammonia in workplace atmospheres-solid sorbent. Occupational Safety and Health Administration, Washington, DC. https://www.osha.gov/dts/sltc/methods/inorganic/id188/id188.html.
Petitte, J.N. and R.J. Etches, 1988. The effect of corticosterone on the photoperiodic response of immature hens. Gen. Comp. Endocrinol., 69: 424-430.
Petitte, J.N. and R.J. Etches, 1989. The effect of corticosterone on the response of the ovary to pregnant mare's serum gonadotrophin in sexually immature pullets. Gen. Comp. Endocrinol., 74: 377-384.
Petitte, J.N. and R.J. Etches, 1991. Daily infusion of corticosterone and reproductive function in the domestic hen (Gallus domesticus). Gen. Comp. Endocrinol., 83: 397-405.
Porter, T.E., B.M. Hargis, J.L. Silsby and M.E. El Halawani, 1989. Differential steroid production between theca interna and theca externa cells: A three-cell model for follicular steroidogenesis in avian species. Endocrinology, 125: 109-116.
Randall, C.J. and S.R. Duff, 1988. Avulsion of the patellar ligament in osteopenic laying fowl. Vet. Rec., 123: 439-441.
Rivier, C. and S. Rivest, 1991. Effect of stress on the activity of the hypothalamic-pituitary-gonadal axis: Peripheral and central mechanisms. Biol. Reprod., 45: 523-532.
Rozenboim, I., E. Tako, O. Gal-Garber, J.A. Proudman and Z. Uni, 2007. The effect of heat stress on ovarian function of laying hens. Poult. Sci., 86: 1760-1765.
Sahin, K., M. Onderci, N. Sahin and S. Aydin, 2002. Effects of dietary chromium picolinate and ascorbic acid supplementation on egg production, egg quality and some serum metabolites of laying hens reared under a low ambient temperature (6°C). Archiv Tierernaehrung, 56: 41-49.
SAS Institute, 2004. Statistical Analysis System, Version 9.3. SAS Institute Inc., Cary, NC., USA.
Sechman, A., 2013. The role of thyroid hormones in regulation of chicken ovarian steroidogenesis. Gen. Comp. Endocrinol., 190: 68-75.
Shini, S., A. Shini and G.R. Huff, 2009. Effects of chronic and repeated corticosterone administration in rearing chickens on physiology, the onset of lay and egg production of hens. Physiol. Behav., 98: 73-77.
Tilly, J.L., K.I. Kowalski and A.J. Johnson, 1991. Stage of ovarian follicular development associated with the initiation of steroidogenic competence in avian granulosa cells. Biol. Reprod., 44: 305-314.
Tsutsui, K., E. Saigoh, K. Ukena, H. Teranishi and Y. Fugisawa et al., 2000. A novel avian hypothalamic peptide inhibiting gonadotropin release. Biochem. Biophys. Res. Commun., 275: 661-667.
United Egg Producers, 2005. Animal husbandry guidelines for U.S. laying flocks. United Egg Producers, Alpharetta, GA., USA.
United Egg Producers, 2008. United egg producers animal husbandry guidelines for US egg laying flocks. United Egg Producers, Alpharetta, GA., USA.
Whitehead, C.C. and R.H. Fleming, 2000. Osteoporosis in cage layers. Poult. Sci., 79: 1033-1041.
Wilson, S.C. and F.J. Cunningham, 1980. Concentrations of corticosterone and luteinizing hormone in plasma during the ovulatory cycle of the domestic hen and after the administration of gonadal steroids. J. Endocrinol., 85: 209-218.
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