[1] Lee J. Molecular Basis of Feed Efficiency in Meat-type Chickens[M]. Getd. Libs. Uga.Edu, 2012.
[2] Patience J F.Feed Efficiency in Swine[M].Wageningen Academic Publishers, 2012.
[3] Gunsett F C. Linear index selection to improve traits defined as ratios[J]. Journal of Animal Science, 1984, 59(5):1185-1193.
[4] Jr C D. Genetics of efficient feed utilization and national cattle evaluation:A review[J]. Genetics and Molecular Research Gmr, 2004, 4(2):152-165.
[5] Richardson E C, Herd R M. Biological basis for variation in residual feed intake in beef cattle. 2. Synthesis of results following divergent selection[J]. Animal Production Science, 2004, 44(5):431-440.
[6] Gilbert H, Bidanel J P, Billon Y, et al. Correlated responses in sow appetite, residual feed intake, body composition, and reproduction after divergent selection for residual feed intake in the growing pig[J]. Journal of Animal Science, 2012, 90(4):1097-1108.
[7] Lefaucheur L, Lebret B, Ecolan P, et al. Muscle characteristics and meat quality traits are affected by divergent selection on residual feed intake in pigs[J]. Journal of Animal Science, 2011, 89(4):996-1010.
[8] 农业行业标准.NY/T 33-2004鸡饲养标准[S].2004.
[9] 农业行业标准.NY/T 823-2004家禽生产性能名词术语和度量统计方法[S]. 2004.
[10] Folch J, Lees M, Sloane-Stanley G H. A simple method for the isolation and purification of total lipids from animal tissues[J]. J Biol Chem, 1957, 226(1):497-509.
[11] Berri C, Bihan-Duval L, Debut M, et al. Consequence of muscle hypertrophy on characteristics of pectoralis major muscle and breast meat quality of broiler chickens[J]. Journal of Animal Science, 2007, 85(8):2005-2011.
[12] Cai W, Casey D S, Dekkers J C M. Selection response and genetic parameters for residual feed intake in Yorkshire swine[J]. Journal of Animal Science, 2008, 86(2):287-298.
[13] Arthur P F, Archer J A, Johnston D J, et al. Genetic and phenotypic variance and covariance components for feed intake, feed efficiency, and other postweaning traits in Angus cattle[J]. Journal of Animal Science, 2001, 79(11):2805-2811.
[14] Faure J, Lefaucheur L, Bonhomme N, et al. Consequences of divergent selection for residual feed intake in pigs on muscle energy metabolism and meat quality[J]. Meat Science, 2013, 93(1):37-45.
[15] Aggrey S E, Karnuah A B, Sebastian B, et al. Genetic properties of feed efficiency parameters in meat-type chickens[J]. Genetics Selection Evolution, 2010, 42(1):25.
[16] Herd R M, Arthur P F. Physiological basis for residual feed intake[J]. Journal of Animal Science. 2009, 87(Suppl 14):64-71.
[17] Richardson E C, Herd R M, Oddy V H, et al. Body composition and implications for heat production and Angus steer progeny of parents selected for and against residual feed intake[J]. Animal Production Science, 2001, 41(7):1065-1072.
[18] Zhuo Z, Lamont S J, Lee W R, et al. RNA-Seq analysis of abdominal fat reveals differences between modern commercial broiler chickens with high and low feed efficiencies[J]. PLoS One, 2015, 10(8):e0135810.
[19] Zhou N, Lee W R, Abasht B. Messenger RNA sequencing and pathway analysis provide novel insights into the biological basis of chickens' feed efficiency[J]. BMC Genomics, 2015, 16(1):195.
[20] Young J M, Cai W, Dekkers J C. Effect of selection for residual feed intake on feeding behavior and daily feed intake patterns in Yorkshire swine[J]. Journal of Animal Science, 2011, 89(3):639-647.
[21] Nascimento M L, Souza A R, Chaves A S, et al. Feed efficiency indexes and their relationships with carcass, non-carcass and meat quality traits in Nellore steers[J]. Meat Science, 2016, 116:78-85.
[22] Mcdonagh M B, Herd R M, Richardson E C, et al. Meat quality and the calpain system of feedlot steers following a single generation of divergent selection for residual feed intake[J]. Animal Production Science. 2001, 41(7):1013-1021.
[23] Symeon G K, Mantis F, Bizelis I, et al. Effects of caponization on growth performance, carcass composition and meat quality of males of a layer line[J]. Animal, 2012, 6(12):2023-2030. |