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The effects of genetic selection for survivability and productivity on chicken physiological homeostasis

Published online by Cambridge University Press:  18 September 2007

H. Cheng  and
W.M. Muir
H. Cheng*
Affiliation:
Livestock Behaviour Research Unit, USDA-ARS, West Lafayette, IN 47907, USA
W.M. Muir
Affiliation:
Animal Sciences Department, Purdue University, West Lafayette, IN 47907, USA
*
*Corresponding author: hwcheng@purdue.edu
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Abstract

Genetic selection is an important breeding tool that can be used for improving animal's coping capability to modern production environments or for increasing economic benefits. However, over the past five decades, commercial breeding programmes have primarily concentrated on traits directly related to productivity. As a result those breeding programmes ignore traits that may impact animal welfare. To address this issue, a selection programme termed “group selection” developed. This method takes into account competitive interactions by emphasizing performance of the group, rather than the individual. Results from the current studies have showed that chickens'productivity and well-being can be improved the same time. We further demonstrated an association between the selected survivability and productivity and its respective physiological characteristics. These findings indicate that group selection altered the chickens' physiological homeostasis which is reflected in the line's unique coping ability with intensified domestic environments. These changes in physiological homeostasis provide an opportunity gain new insights for the development of interventions aimed at ameliorating the adverse impacts of the intensified poultry industry.

Keywords

group selectionchickensocial interactionsphysiologyimmunology
Type
Reviews
Information
World's Poultry Science Journal , Volume 61 , Issue 3 , September 2005 , pp. 383 - 397
Copyright
Copyright © Cambridge University Press 2005

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References

Barofsky, A.L., Taylor, J., Tizabi, Y., Kumar, R. and Jones-Quartey, K. (1983) Specific neurotoxin lesions of median raphe serotonergic neurons disrupt maternal behavior in the lactating rat. Endocrinology 113: 1884–893.CrossRefGoogle ScholarPubMed
Bayyari, G.R., Huff, W.E., Rath, N.C., Balog, J.M., Newberry, L.A., Villines, J.D., Skeeles, J.K., Anthony, N.B. and Nestor, K.E. (1997) Effect of the genetic selection of turkeys for increased body weight and egg production on immune and physiological responses. Poultry Science 76: 289296.CrossRefGoogle ScholarPubMed
Becu-Villalobos, D. and Libertun, C. (1995) Development of gonadotropin-releasing hormone (GnRH) neuron regulation in the female rat. Cellular and Molecular Neurobiology 15: 165176.Google Scholar
Bell, R. and Hepper, P.G. (1987) Catecholamines and aggression in animals. Behavioural. Brain Research 23: 121.Google Scholar
Bell, R. and Hobson, H. (1994) 5-HT1A receptor influences on rodent social and agonistic behavior: a review and empirical study. Neuroscience and BioBehavioural Reviews 18: 325338.Google Scholar
Berquist, J., Tarkowski, A.Ewing, A. and Ekman, R. (1998) Catecholaminergic suppression of immunocompetent cells. Immunology Today 19: 562567.Google Scholar
Boa-Amponsem, K., Dunnington, E.A., Baker, K.S. and Siegel, P.B. (1999) Diet and immunological memory of lines of White Leghorn chickens divergently selected for antibody response to sheep red blood cells. Poultry Science 78: 165170.CrossRefGoogle ScholarPubMed
Brown, K.I. and Nestor, K.E. (1974) Implications of selection for high and low adrenal response to stress. Poultry Science 53: 12971306.CrossRefGoogle ScholarPubMed
Brown-Borg, H.M., Klemcke, M.G. and Blecha, F. (1993) Lymphocyte proliferative responses in neonatal pigs with high or low plasma cortisol concentration after stress induced by restraint. American Journal of Veterinary Research 54: 20152020.Google Scholar
Bullock, J., Boyle, J. III and Wang, M.B. (1995) Physiology. Williams & Wilkins. Malvern, PA.Google Scholar
Cheng, H.W., Dillworth, G., Singleton, P., Chen, Y. and Muir, W.M. (2001a) Effect of genetic selection for productivity and longevity on blood concentrations of serotonin, catecholamine and corticosterone of chickens. Poultry Science 80: 12781285.Google Scholar
Cheng, H.W., Eicher, S.D., Chen, Y., Singleton, P. and Muir, W.M. (2001b) Effect of genetic selection for group productivity and longevity on immunological and hematological parameters of chickens. Poultry Science 80: 10791086.CrossRefGoogle Scholar
Contijoch, A.M., Gonzalez, C., Singh, H.N., Malamed, S., Troncoso, S. and Advis, J.P. (1992) Dopaminergic regulation of luteinizing hormone-releasing hormone release at the median eminence level: immunocytochemical and physiological evidence in hens. Neuroendocrinology 55: 290300.CrossRefGoogle ScholarPubMed
Cook, E.H. and Leventhal, B.L. (1996) The serotonin system in autism. Current Opinion in Pediatrics 8: 348354.Google Scholar
Craig, J.V. and Muir, M.W. (1996a) Group selection for adaptation to multiple-hen cages: beak-related mortality, feathering, and body weight responses. Poultry Science 75: 294302.CrossRefGoogle ScholarPubMed
Craig, J.V. and Muir, W.M. (1996b) Group selection for adaptation to multiple-hen cages: behavioral responses. Poultry Science 75: 11451155.CrossRefGoogle ScholarPubMed
Dhabhar, F.S., Miller, A.H., Stein, M., Mcewen, B.S. and Spencer, R.L. (1994). Diurnal and acute stress-induced changes in distribution of peripheral blood leukocyte subpopulations. Brain Behavior and Immunity 8: 6679.CrossRefGoogle ScholarPubMed
Dillon, J.E., Raleigh, M.J., Mcguire, M.T., Bergin-Pollack, D. and Yuwiler, A. (1992) Plasma catecholamines and social behavior in male vervet monkeys (Cercopithecus aethiops sabaeus). Physiology Behaviour 51: 973977.Google Scholar
Dunn, A.J. (1996) Psychoneuroimmunology, stress and infection. Pages 25–46. in: Psychoneuroimmunology, Stress, and Infection. Friedman, H.Klein, T.W. and Friedman, A. L., Eds. CRC Press. Boca Raton, FL.Google Scholar
Dygalo, N.N., Bykova, T.S. and Naumenko, E.V. (1988) Brain tyrosine hydroxylase activity in behavior-selected silver foxes. Zhurnal Evoliutsionnoi Biokhimii I Fiziologii 24: 503508.Google ScholarPubMed
Edens, F.W. (1987) Agonistic behavior and neurochemistry in grouped Japanese quail. Comparative Biochemistry and Physiology. Part A 86: 473479.Google Scholar
Goldstein, D.S. (2003) Catecholamines and stress. Endocrine Regulations 37: 6980.Google ScholarPubMed
Goldstein, D.S. (1981) Plasma norepinephrine as an indicator of sympathetic neural activity in clinical cardiology. American Journal of Cardiology 48: 11471154.CrossRefGoogle ScholarPubMed
Gonzalez, M.I., Greengrass, P., Russell, M. and Wilson, C.A. (1997) Comparison of serotonin receptor numbers and activity in specific hypothalamic areas of sexually active and inactive female rats. Neuroendocrinology 66: 384392.Google Scholar
Gray, H.G., Paradis, T.J. and Chang, P.W. (1989) Physiological effects of adrenocorticotropic hormone and hydrocortisone in laying hens. Poultry Science 68: 17101713.CrossRefGoogle ScholarPubMed
Griffing, B. (1976) Selection in reference to biological groups. V. Analysis of full-sib groups. Genetics 82: 703722.CrossRefGoogle ScholarPubMed
Gross, W.B. and Colmano, G. (1970) Corticosterone and ACTH as treatments for Escherichia coli infection in chickens. Poultry Science 49: 12561258.CrossRefGoogle ScholarPubMed
Gross, W.B. and Siegel, H.S. (1983) Evaluation of the heterophil/lymphocyte ratio as a measure of stress in chickens. Avian Diseases 27: 972979.Google Scholar
Haller, J., Makara, G.B. and Kruk, M.R. (1997) Catecholaminergic involvement in the control of aggression: hormones, the peripheral sympathetic, and central noradrenergic systems. Neuroscience and Behaviour Reviews 22: 8597.Google Scholar
Haller, J., Millar, S., Van De Schraaf, J., De Kloet, R.E. and Kruk, M.R. (2000) The active phase-related increase in corticosterone and aggression are linked. Journal of Neuroendocrinology 12: 431436.CrossRefGoogle ScholarPubMed
Hanna, G.L., Yuwiler, A. and Coates, J.K. (1995) Whole blood serotonin and disruptive behaviors in juvenile obsessive-compulsive disorder. Journal of the American Academy of Child and Adolescent Psychiatry 34: 2835.Google Scholar
Harvey, S., Phillips, J.G., Rees, A. and Hall, T.R. (1984) Stress and adrenal function. Journal of Experimental Zoology 232: 633645.Google Scholar
Hessing, M.J., Coenen, G.J., Vaiman, M. and Renard, C. (1995) Individual differences in cell-mediated and humoral immunity in pigs. Veterinary Immunology and Immunopathology 45: 97113.Google Scholar
Hester, P.Y., Muir, W.M. and Craig, J.V. (1996a) Group selection for adaptation to multiple-hen cages: humoral immune response. Poultry Science 75: 13151320.CrossRefGoogle ScholarPubMed
Hester, P.Y., Muir, W.M., Craig, J.V. and Albright, J.L. (1996b) Group selection for adaptation to multiple-hen cages: hematology and adrenal function. Poultry Science 75: 12951307.CrossRefGoogle ScholarPubMed
Hester, P.Y., Muir, W.M., Craig, J.V. and Albright, J.L. (1996c) Group selection for adaptation to multiple-hen cages: production traits during heat and cold exposures. Poultry Science 75: 13081314.CrossRefGoogle ScholarPubMed
Higley, J.D., King, S.T., Hasert, M.F., Champoux, M., Suomi, S.J. and Linnoila, M. (1996) Stability of interindividual differences in serotoin function and its relationship to severe aggression and competent social behavior in Rhesus macaque females. Neuropsychopharmacology 14: 6776.Google Scholar
Hohenhaus, M.A., Josey, M.J., Dobson, C. and Outteridge, P.M. (1998) The eosinophil leucocyte, a phenotypic marker of resistance to nematode parasites, is associated with calm behaviour in sheep. Immunology and Cell Biology 76: 153158.CrossRefGoogle ScholarPubMed
Ishizaki, H. and Kariya, Y. (1999) Effects of peripheral blood polymorphonuclear leukocyte function and blood components in Japanese black steers administered ACTH in a cold environment. Journal of Veterinary Medical Science 61: 487492.CrossRefGoogle Scholar
Jernej, B. and Cicin-Sain, L. (1990) Platelet serotonin level in rats is under genetic control. Psychiatry Research 32: 167174.CrossRefGoogle ScholarPubMed
Kuchel, O. (1991) Stress and catecholamines. In: Stress Revisited. I. Neuroendocrinology of stress. Jasmin, G and Cantin, M. eds. Methods achieve Exp Pathol. Basel Karger. Vol. 14. pp 80103.Google Scholar
Kuchel, O., Buu, N.T. and Wang, P.C. (1982) Stress, catecholamines and hypertension: Respective roles of free and conjugated catecholamines. Stress 3: 2231.Google Scholar
Kulikov, A.V., Elu., Zhanaeva and Popova, N.K. (1989) Change in tryptophan hydroxylase activity in the brain of silver foxes and wild Norway rats in the course of selection according to behavior. Genetika 25: 346350.Google ScholarPubMed
Lampugnani, M.G., Buczko, W., Ceci, A., Mennini, A. and De Gaetano, G. (1986) Normal serotonin uptake by blood platelets and brain synaptosomes but selective impairment of platelet serotonin storage in mice with Chediack-Higashi syndrome. Life Science 38: 21932198.CrossRefGoogle ScholarPubMed
Levinson, W. and Jawetz, E. (1996) Medical Microbiology and Immunology. Appleton and Lance. Stamford CT.Google Scholar
Lorrain, D.S., Matuszewich, L. and Hull, E.M. (1998) 8-OH-DPATinfluences extracellular levels of serotonin and dopamine in the medial preoptic area of male rats. Brain Research 790: 217223.CrossRefGoogle ScholarPubMed
Malyshev, V.V., Petrova, V.A. and Manukhin, B.N. (1985) Changes in the level of eosinophils, corticosterone and catecholamine metabolism in the dynamics of emotional-painful stress. Biulleten Eksperimentalnoi Biologii I Meditsiny 99: 267269.Google ScholarPubMed
Malyshev, V.V., Vasil'Eva, L.S. and Kuz'Menko, V.V. (1993) The interrelationship between inflammation and the stress reaction. Biulleten Eksperimentalnoi Biologii I Meditsiny 116: 348349.Google Scholar
Martin, W.H., Rogol, A.D., Kaiser, D.L. and Thorner, M.O. (1981) Dopaminergic mechanisms and luteinizing hormone (LH) secretion. II. Differential effects of dopamine and bromocriptine on LH release in normal women. Journal of Clinical Endocrinology and Metabolism 52: 650656.CrossRefGoogle ScholarPubMed
Maswood, N., Caldarola-Pastuszka, M. and Uphouse, L. (1998) Functional integration among 5-hydroxytryptamine receptor families in the control of female rat sexual behavior. Brain Research 802: 98103.Google Scholar
Maxwell, M.H. (1993) Avian blood leucocyte responses to stress. World's Poultry Science Journal 49: 3443.Google Scholar
Miczek, K.A., Fish, E.W., De Bold, J.E. and De Almeida, R.M.M. (2002) Social and neural determinants of aggressive behavior: pharmacotherapeutics targets at serotonin, dopamine and γ-aminobutyric acid systems. Psychopharmacology 163: 434458.Google Scholar
Moffitt, T.E., Brammer, G.L., Caspi, A., Fawcett, J.P., Raleigh, M., Yuwiler, A. and Silva, P. (1998) Whole blood serotonin relates to violence in an epidemiological study. Biological Psychiatry 43: 446457.CrossRefGoogle Scholar
Morello, H., Caligaris, L., Haymal, B. and Taleisnik, S. (1992) Daily variations in the sensitivity of proestrous LH surge in the inhibitory effect of intraventricular injection of 5-HT or GABA in rats. Canadian Journal of Physiology and Pharmacology 70: 447451.Google Scholar
Muir, W.M. (1996) Group selection for adaptation to multiple-hen cages: selection program and direct responses. Poultry Science 75: 447458.Google Scholar
Muir, W.M. (2005) Incorporation of Competitive Effects in Breeding Programs for forest trees and Animals. Genetics (in press)Google Scholar
Muir, W.M. and Craig, J.V. (1998) Improving animal well-being through genetic selection. Poultry Science 77:1 7811788.Google Scholar
Muir, W.M. and Schinckel, A. (2002) Incorporation of competitive effects in breeding programs to improve productivity and animal well being. Proc. 7th World Congress of Genetics Applied to Livestock Breeding 32: 3536Google Scholar
Nagatsuka, Y. (1983) The regulation of pituitary gonadotropin release of the frontal lobe neocortex. (II). In relation to serotonergic neurons. Nippon Naibunpi Gakkai Zasshi 59: 18741883.Google Scholar
Nankova, B.B. and Sabban, E.L. (1999) Multiple signalling pathways exist in the stress-triggered regulation of gene expression for catecholamine biosynthetic enzymes and several neuropeptides in the rat adrenal medulla. Acta Physiologica Scandinavica 167: 19.Google Scholar
Parmigiani, S., Palanza, P., Rogers, J. and Ferrari, P.F. (1999) Selection, evolution of behavior and animal models in behavioral neuroscience. Neuroscience and Biobehavioral Reviews 23: 957969.CrossRefGoogle ScholarPubMed
Pietraszek, M.H., Takada, Y., Yan, D., Urano, T., Serizawa, K. and Takada, A. (1992) Relationship between serotonergic measures in periphery and the brain of mouse. Life Science 51: 7582.Google Scholar
Plaut, M. (1987) Lymphocyte hormone receptors. Annual Review of Immunology 5: 621669.Google Scholar
Pretorius, E. (2004) Corticosteroids, depression and the role of serotonin. Reviews in the Neurosciences 15: 109–16.Google Scholar
Raleigh, M.J., Mcguire, M.T., Brammer, G.L., Pollack, D.B. and Yuwiler, A. (1991) Serotonergic mechanisms promote dominance acquisition in adult male vervet monkeys. Brain Research 559: 181190.CrossRefGoogle ScholarPubMed
Reid, G.M. and Tervit, H. (1995) Sudden infant death syndrome (SIDS): immunoglobulins and hypoxia. Medical Hypotheses 44: 202206.Google Scholar
Richfield, E.K., Young, A.B. and Penney, J.B. (1987) Comparative distribution of dopamine D-1 and D-2 receptors in the basal ganglia of turtles, pigeons, rats, cats, and monkeys. Journal of Comparative Neurology 262: 446463.Google Scholar
Savory, C.J. and Mann, J.S. (1997) Is there a role for corticosterone in expression of abnormal behaviour in restricted-fed fowls? Physiology and Behavior 62: 713.Google Scholar
Shea, M.M., Douglass, L.W. and Mench, J.A. (1991) The interaction of dominance status and supplemental tryptophan on aggression in Gallus domesticus males. Pharmacology, Biochemistry and Behavior 38: 587591.Google Scholar
Shively, C. and Bethea, C.L. (2004). Cognition, mood disorders, and sex hormones. Institute for Laboratory Animal Research Journal 45: 189–99.Google Scholar
Siegel, H.S. (1995) Gordon Memorial Lecture. Stress, strains and resistance. British Poultry Science 36: 322.Google Scholar
Siegel, H.S. (1971) Cold-induced necrosis in toes of chicks receiving daily dosages of adrenocorticotropin. General and Comparative Endocrinology 16: 281287.Google Scholar
Siegel, P.B. and Gross, W.B. (1980) Production and persistence of antibodies in chickens to sheep erythrocytes. 1. Directional selection. Poultry Science 59: 15.CrossRefGoogle Scholar
Siegel, P.B., Gross, W.P. and Cherry, J.A. (1982) Correlated responses of chickens to selection for production of antibodies to sheep erythrocytes. Animal Blood Groups Biochemical Genetics 13: 291297.CrossRefGoogle ScholarPubMed
Sirotkin, A.V. and Schaeffer, H.J. (1997) Direct regulation of mammalian reproductive organs by serotonin and melatonin. Journal of Endocrinology 154: 15.Google Scholar
Snider, S.R. and Kuchel, O. (1983) Dopamine: an important neurohormone of the sympathoadrenal system. Significance of increased peripheral dopamine release for the human stress response and hypertension. Endocrine Reviews 4: 291309.Google Scholar
Sotowska-Brochocka, J., Martynska, L. and Licht, P. (1994) Dopaminergic inhibition of gonadotropic release in hibernating frogs, Rana temporaria. General and Comparative Endocrinology 93: 192196.Google Scholar
Stanulis, E.D., Matulka, R.A., Jordan, S.D., Rosecrans, J.A. and Holsapple, M.P. (1997) Role of corticosterone in the enhancement of the antibody response after acute cocaine administration. Journal of Pharmacology and Experimental Therapeutics 280: 284291.Google ScholarPubMed
Steklis, H.D., Raleigh, M.J., Kling, A.S. and Tachiki, K. (1986) Biochemical and hormonal correlates of dominance and social behavior in all-male groups of squirrel monkeys (Saimiri sciureus). American Journal of Primatology 11: 133145.Google Scholar
Treloar, O.L. (1977) Hormonal regulation of rapid eosinopenia in the rat. Laboratory Animal Science 27: 635640.Google Scholar
Ubosi, C.O., Gross, W.B. and Siegel, P.B. (1985) Divergent selection of chickens for antibody production to sheep erythrocytes: age effect in parental lines and their crosses. Avian Diseases 29: 150158.CrossRefGoogle ScholarPubMed
Unis, A.S., Cook, E.H., Vincent, J.G., Gjerde, D.K., Perry, B.D., Mason, C. and Mitchell, J. (1997) Platelet serotonin measures in adolescents with conduct disorder. Biological Psychiatry 42: 553559.Google Scholar
Van Der Zijpp, A.J., Frankena, K., Boneschanscher, J. and Nieuwland, M.G. (1983) Genetic analysis of primary and secondary immune responses in the chicken. Poultry Science 62: 565–72.Google Scholar
Walker, E.A., Yamamoto, T., Hollingsworth, P.J., Smith, C.B. and Woods, J.H. (1991) Discriminative-stimulus effects of quipazine and 1-5-hydroxytryptophan in relation to serotonin binding sites in the pigeon. Journal of Pharmacology and Experimental Therapeutics 259: 772782.Google Scholar
Wilkie, B. and Mallard, B. (1999) Selection for high immune response: an alternative approach to animal health maintenance? Veterinary Immunology and Immunopathology 72: 231235.CrossRefGoogle ScholarPubMed
William, G.C. (1966) Adaptations and Natural Selection. Princeton Univ. Press, pp 1–14. Chicago: Aldine-Atherton.Google Scholar
Woolaston, R.R., Manueli, P., Eady, S.J., Barger, I.A., Le Jambre, L.F., Banks, D.J. and Windon, R.G. (1996) The value of circulating eosinophil count as a selection criteria for resistance of sheep to trichostrongyle parasites. International Journal for Parasitology 26: 123126.CrossRefGoogle ScholarPubMed