[1]YOUNG L E, ROGERS K, WOOD J L. Left ventricular size and systolic function in thoroughbred racehorses and their relationships to race performance[J]. Appl Physiol,2005,99:1278-1285.
[2]EVANS D L, HARRIS R C, SNOW D H. Correlation of racing performance with blood lactate and heart rate after exercise in thoroughbred horses[J]. Equine Vet,1993,25:441-445.
[3]HARRISON S P, TURRION-GOMEZ J L. Mitochondrial DNA:an important female contribution to thoroughbred racehorse performance[J]. Mitochondrion,2006,6:53-63.
[4]WADE C M, GIULOTTO E, SIGURDSSON S, et al. Genome sequence, comparative analysis, and population genetics of the domestic horse[J]. Science,2009, 326:865-867.
[5]SCHRÖDER W, KLOSTERMANN A, DISTLET O. Candidate genes for physical performance in the horse[J]. Vet J,2011, 190(1):39-48.
[6]GU J, ORR N, PARK S D, et al. A genome scan for positive selection in thoroughbred horses[J]. PLoS ONE,2009,4:e5767.
[7]PILEGAARD H, ORDWAY G A, SALTIN B, et al. Transcriptional regulation of gene expression in human skeletal muscle during recovery from exercise[J]. Am J Physiol, 2000, 279: 806-814.
[8]EIVERS S S, MCGIVNEY B A, FONSECA R G, et al. Alterations in oxidative gene expression in equine skeletal muscle following exercise and training[J]. Physiol Genomics, 2010, 40:83-93.
[9]HILL E W, GU J, McGIVNEY B A, et al. Targets of selection in the Thoroughbred genome contain exercise-relevant gene SNPs associated with elite racecourse performance[J]. Anim Genet, 2010, 41(2): 56-63.
[10]WENDE A R, HUSS J M, SCHAEFFER P J, et al. PGC-1α Coactivates PDK4 gene expression via the orphan nuclear receptor ERRα: a mechanism for transcriptional control of muscle glucose metabolism[J]. Mol Cell Biol, 2005, 25(24):10684-10694.
[11]EIVERS S S, McGIVNEY B A, GU J,et al. PGC-1a encoded by the PPARGC1A gene regulates oxidative energy metabolism in equine skeletal muscle during exercise[J]. Anim Genet,2011,43:153-162.
[12]FUKUDA R, ZHANG H, KIM J, et al. HIF-1 regulates cytochrome oxidase subunits to optimize efficiency of respiration inhypoxic cells[J]. Cell, 2007, 129(6):111-122.
[13]BOUCHARD C, CHAGNON M, THIBAULT M C, et al. Muscle genetic variants and relationship with performance and trainability[J]. Med Sci Sports Exerc,1989,21:71-77.
[14]APPLE P S, BILLARDELLO J J. Expression of creatine kinase M and B mRNAs in treadmill trained rat skeletal muscle[J]. Life Sci,1994,55(8):585-592.
[15]McGIVNEY B, EIVERS S, MACHUGH D, et al. Transcriptional adaptations following exercise in Thoroughbred horse skeletal muscle highlights molecular mechanisms that lead to muscle hypertrophy[J]. BMC Genomics, 2010, 10:638.
[16]HILL E W, EIVERS S S, MCGIVNEY B A, et al. Moderate and high intensity sprint exercise induce differential responses in COX4I2 and PDK4 gene expression in thoroughbred horse skeletal muscle[J]. Equine Vet,2010,42(38):576-581.
[17]MCPHERRON A C, LAWLER A M, LEE S J. Regulation of skeletal muscle mass in mice by a new TGF -β superfamily member[J]. Nature,1997,387:83-90.
[18]MOSHER D S, QUIGNON P, BUSTAMANTE C D, et al. A mutation in the myostatin gene increases muscle mass and enhances racing performance in heterozygote dogs[J]. PLoS Genet,2007,3:e79.
[19]HILL E W, GU J, EIVERS S S, et al. A sequence polymorphism in MSTN predicts sprinting ability and racing stamina in thoroughbred horses[J]. PloS ONE,2010,5:e8645. |