中国农业科学 ›› 2018, Vol. 51 ›› Issue (16): 3191-3200.doi: 10.3864/j.issn.0578-1752.2018.16.015
所属专题: 加强环境生理研究应用 支撑畜禽养殖绿色发展
石雷,李云雷,孙研研,陈继兰
收稿日期:
2018-04-04
出版日期:
2018-08-16
发布日期:
2018-08-16
通讯作者:
陈继兰,Tel:010-62816005;E-mail:chen.jilan@163.com
作者简介:
石雷,E-mail:shilei2017@foxmail.com
基金资助:
SHI Lei, LI YunLei, SUN YanYan, CHEN JiLan
Received:
2018-04-04
Online:
2018-08-16
Published:
2018-08-16
摘要: 光照是生物体重要的环境因子。现代家禽生产普遍采用人工光照。禽类视觉敏感,光照对禽类的生长发育和繁殖的影响直接关系到生产效率。光照是温度、湿度和通风因素之外的另一个重要的环境因子。此外,鸡作为一种重要的模式动物,光照对其繁殖生理的影响和相关作用机制研究也具有重要科学意义。文章就禽类对光照的感知,光照节律对鸡性成熟和繁殖的影响进行归纳总结,同时概述了非自然光照节律、光照不应性和种蛋孵化期光照技术的研究进展,为深入理解光照节律对鸡繁殖性能的影响及其调控机制提供理论参考。禽类的光感受器如眼球(视网膜)、丘脑深部和松果体,能够将光信号转变为生物信号,并依靠神经内分泌系统,尤其是下丘脑-垂体-性腺轴,影响鸡的生殖系统发育和繁殖行为。育成期鸡群性腺发育很快,并对光照时间长短反应敏感。光照时长过短或者过长,可能导致鸡只生长受阻或者性成熟提前;每天维持恒定8或9 h的光照时长,可保证体况和体重在性成熟时达标,充分发挥繁殖潜力。产蛋期光照节律主要包括光照刺激时间和光照时长。光照刺激能促进鸡性成熟,但必须在恰当的阶段实施才能有效发挥其促进适时和整齐开产的作用。对于黄羽种鸡光照刺激时间的研究鲜有报道,生产中多参照蛋鸡的光照方案,或适当推延。进入产蛋期的鸡群,光照节律则由恒定短光照转变为恒定长光照,光照时长的选择也是提高鸡繁殖力的关键控制点之一。母鸡产蛋期需要较长的光照时长以维持其高产,但肉种鸡与蛋鸡在体况、饲喂方式和生理特点等不同,如光照不应性等生理特征。因此,肉种鸡的光照时长短于蛋鸡或蛋种鸡,一般为14或15h,而蛋鸡或蛋种鸡为16或17h。种公鸡性早熟在实际生产中具有重要作用,随着精液稀释和存储,以及种公鸡隔代利用等技术的应用发展,种公鸡光照调控技术研究也逐步开展。种公鸡性成熟后采取与母鸡同样的光照时长可能会降低精液品质,提示在公母分饲的条件下有必要对公鸡和母鸡进行有区别的光照节律管理。与常规24h光照节律不同,非自然光照节律的光照制度可以提高蛋重,但可能降低产蛋数。非自然光照周期不符合欧盟规定动物福利标准,与饲养人员的正常作息时间不一致,在实际生产中并未广泛应用,但是研究非自然光照周期对了解家禽的生物节律具有一定的参考价值。
石雷,李云雷,孙研研,陈继兰. 光照节律调控鸡繁殖性能机制研究进展[J]. 中国农业科学, 2018, 51(16): 3191-3200.
SHI Lei, LI YunLei, SUN YanYan, CHEN JiLan. Research Progress on the Regulatory Mechanism of Lighting Schedule Affecting the Reproduction Performance of Chickens[J]. Scientia Agricultura Sinica, 2018, 51(16): 3191-3200.
[1] DAWSON A, KING V M, BENTLEY G E, BALL G F. Photoperiodic control of seasonality in birds. Journal of Biological Rhythms, 2001, 16(4): 365-380.
[2] 陈耀星, 王子旭, 内藤顺平, 鸡投射视顶盖视网膜节细胞的形态学分类. 解剖学报, 2002,33(1): 47-50.
CHEN Y X, WANG Z X, MEITENG S G. Morphological classification of retinotectal ganglion cells in the chick retina. Acta Anatomica Sinica, 2002, 33(1): 47-50. (in Chinese)
[3] LEWIS P D, Morris T R, Poultry and colored light. Worlds Poultry Science Journal, 2000, 56(3): 189-207.
[4] RENEMA R A, SIKUR V R, ROBINSON F E, KORVER D R, ZUIDHOF M J. Effects of Nutrient Density and Age at Photostimulation on Carcass Traits and Reproductive Efficiency in Fast- and Slow-Feathering Turkey Hens. Poultry Science, 2008, 87(9): 1897-1908.
[5] LEWIS P D, CIACCIARIELLO M, CICCONE N A, SHARP P J, GOUS R M. Lighting regimens and plasma LH and FSH in broiler breeders. British Poultry Science, 2005, 46(3): 349-353.
[6] MOORE R Y, SPEH J C, LEAK R K. Suprachiasmatic nucleus organization. Cell and Tissue Research, 2002, 309(1): 89-98.
[7] GILLETTE M U, TISCHKAU S A. Suprachiasmatic nucleus: the brain's circadian clock. Recent Progress in Hormone Research, 1999, 54(1): 33-58.
[8] SURBHI, KUMAR V. Avian photoreceptors and their role in the regulation of daily and seasonal physiology. General and Comparative Endocrinology, 2015, 220: 13-11.
[9] BOWMAKER J K, DARTNALL H J. Visual pigments of rods and cones in a human retina. Journal of Physiology, 1980, 298(1): 501-511.
[10] KUENZEL W J. The search for deep encephalic photoreceptors within the avian brain, using gonadal development as a primary indicator. Poultry Science, 1993, 72(5): 959-967.
[11] HARRISON P C. Extraretinal photocontrol of reproductive responses of Leghorn hens to photoperiods of different length and spectrum. Poultry Science, 1972, 51(6): 2060-2064.
[12] OLIVER J, BAYLÉ J D. Brain photoreceptors for the photo-induced testicular response in birds. Experientia, 1982, 38(9): 1021-1029.
[13] SALDANHA C J, SILVERMAN A J, SILVER R. Direct innervation of GnRH neurons by encephalic photoreceptors in birds. Journal of Biological Rhythms, 2001, 16(1): 39-49.
[14] MOBARKEY N, AVITAL N, HEIBLUM R, ROZENBOIM I. The role of retinal and extra-retinal photostimulation in reproductive activity in broiler breeder hens. Domestic Animal Endocrinology, 2010, 38(4): 235-243.
[15] UNDERWOOD H, MENAKER M. Photoperiodically significant photoreception in sparrows: is the retina involved? Science, 1970, 167(3916): 298-301.
[16] RATHINAM T, KUENZEL W J. Attenuation of gonadal response to photostimulation following ablation of neurons in the lateral septal organ of chicks. Brain Research Bulletin, 2005, 64(5): 455-461.
[17] KLEIN D C. The 2004 Aschoff/Pittendrigh lecture: Theory of the origin of the pineal gland a tale of conflict and resolution. Journal of Biological Rhythms, 2004, 19(4): 264-279.
[18] BINKLEY S, STEPHENS J L, RIEBMAN J B, REILLY K B. Regulation of pineal rhythms in chickens: photoperiod and dark-time sensitivity. General and Comparative Endocrinology, 1977, 32(4): 411-416.
[19] MOBARKEY N, AVITAL N, HEIBLUM R, ROZENBOIM I. The effect of parachlorophenylalanine and active immunization against vasoactive intestinal peptide on reproductive activities of broiler breeder hens photostimulated with green light. Biology of Reproduction, 2013, 88(4): 1-7.
[20] BENTLEY G E, VAN'T HOF T J, BALL G F. Seasonal neuroplasticity in the songbird telencephalon: a role for melatonin. Proceedings of the National Academy of Sciences of the United States of America, 1999, 96(8): 4674-4679.
[21] 王艳利, 曲丽娜, 李莹辉. 生物节律基因非编码RNA调控机制. 中国生物化学与分子生物学报, 2016, 32(4): 353-358.
WANG Y L, QU L N, LI Y H. Regulation of circadian gene by non-coding RNAs. Chinese Journal of Biochemistry and Molecular Biology, 2016, 32(4): 353-358. (in Chinese)
[22] 邢陈, 顾晔, 宋伦. 昼夜节律在代谢调控中的作用. 军事医学, 2017, 41(7): 618-622.
XING C, GU Y, SONG L. Function of circadian rhythms in regulation of metabolism. Military Medical Sciences, 2017, 41(7): 618-622. (in Chinese)
[23] 韩芳. 昼夜节律性睡眠障碍. 生命科学, 2015, 27(11): 1448-1454.
HAN F. Circadian rhythm sleep disorders. Chinese Bulletin of Life Sciences, 2015, 27(11): 1448-1454. (in Chinese)
[24] HASTINGS M H, REDDY A B, MAYWOOD E S. A clockwork web: circadian timing in brain and periphery, in health and disease. Nature Reviews Neuroscience, 2003, 4(8): 649-661.
[25] PANDA S. Multiple photopigments entrain the mammalian circadian oscillator. Neuron, 2007, 53(5): 619-621.
[26] ALBRECHT U. Timing to perfection: the biology of central and peripheral circadian clocks. Neuron, 2012, 74(2): 246-260.
[27] MOHAWK J A, GREEN C B, TAKAHASHI J S. Central and peripheral circadian clocks in mammals. Annual Review of Neuroscience, 2012, 35(1): 445-462.
[28] 陈思禹, 钱近春, 刘畅. 代谢生物钟研究进展. 生命科学, 2015(11): 1409-1417.
CHEN S Y, QIAN J C, LIU C. The molecular mechanism for the integration of circadian clock and energy metabolism. Chinese Bulletin of Life Sciences, 2015, 27(11): 1409-1417. (in Chinese)
[29] 杨宁. 家禽生产学. 北京: 中国农业出版社, 2002.
YANG N. Poultry Science. Beijing: China Agriculture Press, 2002. (in Chinese)
[30] HASSANZADEH M, FARD M H, BUYSE J, DECUYPERE E. Beneficial effects of alternative lighting schedules on the incidence of ascites and on metabolic parameters of broiler chickens. Acta Veterinaria Hungarica, 2003, 51(4): 513-520.
[31] BRAKE J, GARLICH J D, BAUGHMAN G R. Effects of lighting program during the growing period and dietary fat during the laying period on broiler breeder performance. Poultry Science, 1989, 68(9): 1185-1192.
[32] IDRIS A A, ROBBINS K R. Light and feed management of broiler breeders reared under short versus natural day length. Poultry Science, 1994, 73(5): 603-609.
[33] 吕锦芳, 饶开晴, 姜锦鹏, 倪迎冬, 顾有方, 宁康健, 应如海, 周玉刚, 许百年. 光周期对蛋鸡GnRH-I, GnRH-Ra mRNA表达和卵巢发育的影响. 激光生物学报, 2015, 24(3): 251-256.
LÜ J F, RAO K Q, JIANG J P, NI Y D, GU Y F, NING K J, YING R H, ZHOU Y G, XU B N. Effects of photoperiods on GnRH-I, GnRH-Ra mRNA expression and ovary development in layers. Acta Laser Biology Sinica, 2015, 24(3): 251-256. (in Chinese)
[34] 吕锦芳, 倪迎冬, 宁康健, 赵茹茜, 陈杰, 金光明. 不同光周期下ISA褐蛋鸡松果腺GnRH-Ⅰ mRNA表达的变化. 中国兽医学报, 2009(3): 335-338.
LÜ J F, NI Y D, NING K J, ZHAO R X, CHEN J, JIN G M. Change of GnRH-I mRNA expression in pineal gland for ISA brown layers at different photoperiods. Chinese Journal of Veterinary Science, 2009(3): 335-338. (in Chinese)
[35] Han S, Wang Y, Liu L, Li D, Liu Z, Shen X, Xu H, Zhao X, Zhu Q, Yin H. Influence of three lighting regimes during ten weeks growth phase on laying performance, plasma levels- and tissue specific gene expression of reproductive hormones in Pengxian yellow pullets. PLoS One, 2017, 12(5): 1-11.
[36] LEWIS P D, CASTON L, LEESON S. Rearing photoperiod and abrupt versus gradual photostimulation for egg-type pullets. British Poultry Science, 2007, 48(3): 276-283.
[37] LEWIS P D, CASTON L, LEESON S. Influence of rearing photoperiod and age and mode of transfer to final photoperiod on performance in egg-type pullets. International Journal of Poultry Science, 2009, 8(1): 7-13.
[38] 孙研研, 陈继兰. 种公禽繁殖系统对光要素的应答机制研究进展. 中国畜牧兽医, 2017, 44(9): 2692-2698.
SUN Y Y, CHEN J L. Research progress on mechanisms of lighting affecting the reproduction of male poultry breeders. China Animal Husbandry and Veterinary Medicine, 2017, 44(9): 2692-2698. (in Chinese)
[39] RENDEN J A, OATES S S, WEST M S. Performance of two male broiler breeder strains raised and maintained on various constant photoschedules. Poultry Science, 1991, 70(7): 1602-1609.
[40] YALCIN S, MCDANIEL G R, WONGVALLE J. Effect of preproduction lighting regimes on reproductive performance of broiler breeders. Journal of Applied Poultry Research, 1993, 2(2): 51-54.
[41] SUN Y Y, TANG S, CHEN Y, CHEN J L. Effects of light regimen and nutrient density on growth performance, carcass traits, meat quality, and health of slow-growing broiler chickens. Livestock Science, 2017, 198: 201-208.
[42] DUNN I C, SHARP P J, HOCKING P M. Effects of interactions between photostimulation, dietary restriction and dietary maize oil dilution on plasma LH and ovarian and oviduct weights in broiler breeder females during rearing. British Poultry Science, 1990, 31(2): 415-427.
[43] LUPICKI, EWA M. Ovarian morpohology and steroidogenesis in domestic fowl (Gallus domesticus) [microform]: effects of aging, strain, photostimulation program and level of feeding. University of Alberta, 1994.
[44] YUAN T, LIEN R J, MCDANIEL G R. Effects of increased rearing period body weights and early photostimulation on broiler breeder egg production. Poultry Science, 1994, 73(6): 792-800.
[45] 石雷, 孙研研, 许红, 刘一帆, 徐松山, 李云雷, 叶建华, 陈超, 李冬立, 陈余, 郭艳丽, 陈继兰. 光照刺激时间对肉种鸡性成熟的影响. 畜牧兽医学报, 2017, 48(11): 2107-2114.
SHI L, SUN Y Y, XU H, LIU Y F, XU S S, LI Y L, YE J H, CHEN C, LI D L, CHEN Y, GUO Y L, CHEN J L. Effect of age at photostimulation on sexual maturation in broiler breeders. Acra Veterinaria et Zootechnica Sinica, 2017, 48(11): 2107-2114. (in Chinese)
[46] RENEMA R A, ROBINSON F E, ZUIDHOF M T, Reproductive efficiency and metabolism of female broiler breeders as affected by genotype, feed allocation, and age at photostimulation. 2. Sexual maturation. Poultry Science, 2007, 86(10): 2267-2277.
[47] ROBINSON F E WAUTIER T A HARDIN R T, ROBINSON N A, WILSON J L, NEWCOMBE M, MCKAY R I. Effects of age at photostimulation on reproductive efficiency and carcass characteristics. 1. Broiler breeder hens. Canadian Journal of Animal Science, 1996, 3(76): 275-282.
[48] LEWIS P D, CIACCIARIELLO M, BACKHOUSE D, GOUS R M. Effect of age and body weight at photostimulation on the sexual maturation of broiler breeder pullets transferred from 8L:16D to 16L:8D. British Poultry Science, 2007, 48(5): 601-608.
[49] PISHNAMAZI A, RENEMA R A, ZUIDHOF M J, ROBINSON F. Effect of age at photostimulation on sexual maturation in broiler breeder pullets. Poultry Science, 2014, 93(5): 1274-1281.
[50] ZUIDHOF M J, RENEMA R A, ROBINSON F E. Reproductive efficiency and metabolism of female broiler breeders as affected by genotype, feed allocation, and age at photostimulation. 3. Reproductive efficiency. Poultry Science, 2007, 86(10): 2278-2286.
[51] SILVERSIDES F G, KORVER D R, BUDGELL K L. Effect of strain of layer and age at photostimulation on egg production, egg quality, and bone strength. Poultry Science, 2006, 85(7): 1136-1144.
[52] MELNYCHUK V L, KIRBY J D, KIRBY Y K, EMMERSON D A, ANTHONY N B. Effect of strain, feed allocation program, and age at photostimulation on reproductive development and carcass characteristics of broiler breeder hens. Poultry Science, 2004, 83(11): 1861-1867.
[53] ROBINSON F E, ZUIDHOF M J, RENEMA R A. Reproductive efficiency and metabolism of female broiler breeders as affected by genotype, feed allocation, and age at photostimulation. 1. Pullet growth and development. Poultry Science, 2007, 86(10): 2256-2266.
[54] MORRIS T R, PERRY G C. A model for predicting the age at sexual maturity for growing pullets of layer strains given a single change in photoperiod. Journal of Agricultural Science, 2002, 138(4): 441-458.
[55] GOUS N C T R M, GOUS A R M. Photorefractoriness in avian species - could this be eliminated in broiler breeders?. Worlds Poultry Science Journal, 2012, 68(4): 645-650.
[56] JOSEPH N S, ROBINSON F E, RENEMA R A, ZUIDHOF M J. Responses of two strains of female broiler breeders to a midcycle increase in photoperiod. Poultry Science, 2002, 81(6): 745-754.
[57] BORNSTEIN S, PLAVNIK I, LEV Y, Body weight and/or fatness as potential determinants of the onset of egg production in broiler breeder hens. British Poultry Science, 1984, 25(3): 323-341.
[58] ROBINSON F E, ZUIDHOF M J, RENEMA R A. Reproductive efficiency and metabolism of female broiler breeders as affected by genotype, feed allocation, and age at photostimulation. 1. Pullet growth and development. Poultry Science, 2007, 86(10): 2256-2266.
[59] TYLER N C, GOUS R M. The effect of age at photostimulation of male broiler breeders on testes growth and the attainment of sexual maturity. South African Journal of Animal Science, 2009, 39(3): 169-175.
[60] TYLER N C, GOUS R M. Selection for early response to photostimulation in broiler breeders. British Poultry Science, 2011, 52(4): 517-522.
[61] FOLLETT B K, FOSTER R G, NICHOLLS T J. Photoperiodism in birds. Ciba Foundation Symposium, 1985, 117: 93-105.
[62] LEWIS P D, TYLER N C, GOUS R M, DUNN I C, SHARP P J. Photoperiodic response curves for plasma LH concentrations and age at first egg in female broiler breeders. Animal Reproduction Science, 2008, 109(1-4): 274-286.
[63] GOW C B, SHARP P J, CARTER N B, YOO B H. Comparisons of time intervals and plasma LH concentrations during the ovulatory cycle of broiler breeder hens maintained under either a 24 h light:dark cycle or continuous light. British Poultry Science, 1987, 28(1): 129-137.
[64] 黄仁录, 陈辉, 邸科前, 张竞乾, 李军乔, 张振红, 潘栋. 不同光照周期对蛋鸡高峰期血液激素水平的影响. 畜牧兽医学报, 2008(3): 368-371.
HUANG R L, CHEN H, DI K Q, ZHANG J Q, LI J Q, ZHANG Z H, PAN D. Effect of different photoperiods on blood hormone of laying hens. Acra Veterinaria et Zootechnica Sinica, 2008(3): 368-371. (in Chinese)
[65] 黄仁录, 陈辉, 潘栋, 韩爱云, 邸科前, 郭云霞, 张振红. 不同光照周期对蛋鸡高峰期血液生化指标的影响. 华北农学报, 2007(03): 168-171.
HUANG R L, CHEN H, PAN D, HAN A Y, DI K Q, GUO Y X, ZHANG Z H. Effect of different photoperiods on blood biochemical parameters of hens. Acta Agriculturae Boreali-Sinica, 2007(03): 168-171. (in Chinese)
[66] 黄仁录, 陈辉, 潘栋, 邸科前, 侯永刚. 不同光增方式和周期对蛋鸡蛋品质和血液生化指标的影响. 中国畜牧杂志, 2007, 43(13): 52-55.
HUANG R L, CHEN H, PAN D, DI K Q, HOU Y G. Effect of different lighting increscent and photoperiod on egg characters and blood biochemical parameters of laying hen. Chinese Journal of Animal Science, 2007, 43(13): 52-55. (in Chinese)
[67] 王翠菊, 陈辉, 侯永刚, 王飞, 王洪芳, 黄仁录. 不同光照周期下鸡输卵管比较形态学及蛋品质的研究. 河北农业大学学报. 2009, 32(04): 88-91.
WANG C J, CHEN H, HOU Y G, WANG F, WANG H F, HUANG R L. Comparative morphological study on oviduct and egg quality in different photoperiod. Journal of Agricultural University of Hebei, 2009, 32(04): 88-91. (in Chinese)
[68] 潘栋. 光照周期对蛋鸡卵巢输卵管形态、生产性能及血液生化指标的影响[D]. 保定: 河北农业大学, 2008.
PAN D. Effect of photoperiod on procreation morphology, production and haemal biochemical parameters[D]. Baoding: Agricultural University of Hebei, 2008. (in Chinese)
[69] CHEN H, HUANG R L, ZHANG H X, DI K Q, PAN D, HOU Y G. Effects of Photoperiod on Ovarian Morphology and Carcass Traits at Sexual Maturity in Pullets. Poultry Science, 2007, 86(5): 917-920.
[70] LEWIS P D, DANISMAN R, GOUS R M. Photoperiods for broiler breeder females during the laying period. Poultry Science, 2010, 89(1): 108-114.
[71] LEWIS P D, GOUS R M. Effect of final photoperiod and twenty-week body weight on sexual maturity and early egg production in broiler breeders. Poultry Science, 2006, 85(3): 377-383.
[72] LEWIS P D, GOUS R M. Constant and changing photoperiods in the laying period for broiler breeders allowed normal or accelerated growth during the rearing period. Poultry Science, 2006, 85(2): 321-325.
[73] FLOYD M H, TYLER N C. Photostimulation of male broiler breeders to different photoperiods. South African Journal of Animal Science, 2011, 41(2): 146-155.
[74] YANNAKOPOULOS A L. Effect of an ahemeral light cycle on yolk weight and relationship between egg weight and yolk weight late in the pullet year. Poultry Science, 1985, 64(8): 1596-1598.
[75] PROUDFOOT F G. The effects of dietary protein levels, ahemeral light and dark cycles, and intermittent photoperiods on the performance of chicken broiler parent genotypes. Poultry Science, 1980, 59(6): 1258-1267.
[76] HAWES R O, LAKSHMANAN N, KLING L J. Effect of ahemeral light:dark cycles on egg production in early photostimulated brown-egg pullets. Poultry Science, 1991, 70(7): 1481-1486.
[77] SPIES A A, ROBINSON F E, RENEMA R A, FEDDES J J, ZUIDHOF M J, FITZSIMMONS R C. The effects of body weight and long ahemeral days on early production parameters and morphological characteristics of broiler breeder hens. Poultry Science, 2000, 79(8): 1094-1100.
[78] WATERS C J, ROSE S P, BAMPTON P R. Production responses of laying hens to 28 h bright:dim light cycles using different light intensity ratios and a 24 h temperature regimen. British Poultry Science, 1987, 28(2): 207-212.
[79] BOERSMA S I, ROBINSON F E, RENEMA R A. The effect of twenty-eight-hour ahemeral day lengths on carcass and reproductive characteristics of broiler breeder hens late in lay. Poultry Science, 2002, 81(6): 760-766.
[80] SANTÉ O M D L, L'ALIMENTATION U P. laying down minimum rules for the protection of chickens kept for meat production. Official Journal of the European Union, 2007, 182(7): 19-28.
[81] TYLER N C, GOUS R M. Photorefractoriness in avian species – could this be eliminated in broiler breeders? World's Poultry Science Journal, 2012, 68(04): 645-650.
[82] LEWIS P D, GOUS R M, MORRIS T R. Model to predict age at sexual maturity in broiler breeders given a single increment in photoperiod. British Poultry Science, 2007, 48(5): 625-634.
[83] FOLLETT B K, ROBINSON J E. Photoperiod and gonadotrophin secretion in birds. Progress in Reproductive Biology, 1980, 59: 39-61.
[84] SHARP P J, DUNN I C, CEROLINI S. Neuroendocrine control of reduced persistence of egg-laying in domestic hens: evidence for the development of photorefractoriness. Journal of Reproduction and Fertility, 1992, 94(1): 221-235.
[85] TYLER N C, LEWIS P D, GOUS R M. Reproductive status in broiler breeder males is minimally affected by a mid-cycle increase in photoperiod. British Poultry Science, 2011, 52(1): 140-145.
[86] SOCKMAN K W, WILLIAMS T D, DAWSON A, BALL G F. Prior experience with photostimulation enhances photo-induced reproductive development in female European starlings: a possible basis for the age-related increase in avian reproductive performance. Biology of Reproduction, 2004, 71(3): 979-986.
[87] 赵兴绪. 家禽的繁殖调控. 北京: 中国农业出版社, 2010.
ZHAO X X. The Reproductive Regulation of Poultry. Beijing: China Agriculture Press, 2010. (in Chinese)
[89] HUTH J C, ARCHER G S. Effects of LED lighting during incubation on layer and broiler hatchability, chick quality, stress susceptibility and post-hatch growth. Poultry Science, 2015, 94(12): 3052-3058.
[90] ARCHER G S, SHIVAPRASAD H L, MENCH J A. Effect of providing light during incubation on the health, productivity, and behavior of broiler chickens. Poultry Science, 2009, 88(1): 29-37.
[91] ROZENBOIM I, PIESTUN Y, MOBARKEY N, BARAK M, HOYZMAN A, HALEVY O. Monochromatic light stimuli during embryogenesis enhance embryo development and posthatch growth. Poultry Science, 2004, 83(8): 1413-1419.
[92] HALEVY O, PIESTUN Y, ROZENBOIM I, YABLONKA- REUVENI Y. In ovo exposure to monochromatic green light promotes skeletal muscle cell proliferation and affects myofiber growth in posthatch chicks. American Journal of Physiology Regulatory Integrative and Comparative Physiology, 2006, 290(4): 1062-1070.
[93] ZHANG L, ZHANG H J, WANG J, WU S G, QIAO X, YUE H Y, YAO J H, QI G H. Stimulation with monochromatic green light during incubation alters satellite cell mitotic activity and gene expression in relation to embryonic and posthatch muscle growth of broiler chickens. Animal: An International Journal of Animal Bioscience, 2014, 8(1): 86-93.
[94] ZHANG L, ZHANG H J, QIAO X, YUE H Y, WU S G, YAO J H, QI G H. Effect of monochromatic light stimuli during embryogenesis on muscular growth, chemical composition, and meat quality of breast muscle in male broilers. Poultry Science, 2012, 91(4): 1026-1031.
[95] TAMIMIE H S, FOX M W. Effect of continuous and intermittent light exposure on the embryonic development of chicken eggs. Comparative Biochemistry and Physiology, 1967, 20(3): 793-796.
[96] AIGEGIL V, MURILLOFERROL N. Effects of white light on the pineal gland of the chick embryo. Histology & Histopathology, 1992, 7(1): 1-6.
[97] ARCHER G S, SHIVAPRASAD H L, MENCH J A. Effect of providing light during incubation on the health, productivity, and behavior of broiler chickens. Poultry Science, 2009, 88(1): 29-37. |
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