Genetic variability in residual feed intake in rainbow trout clones and testing of indirect selection criteria (Open Access publication)
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Thierry Boujard | Béatrice Chatain | Edwige Quillet | Christèle Robert-Granié | C. Robert-Granié | T. Boujard | E. Quillet | Laure Grima | Muriel Mambrini | B. Chatain | M. Mambrini | L. Grima
[1] D. Chourrout,et al. Suppression of first egg mitosis induced by heat shocks in the rainbow trout , 1993 .
[2] T. Gjedrem. DEVELOPMENTS IN FISH BREEDING AND GENETICS , 1998 .
[3] I. Lund,et al. Genetic variation for growth rate, feed conversion efficiency, and disease resistance exists within a farmed population of rainbow trout , 2002 .
[4] F. C. Gunsett. Problems associated with selection for traits defined as a ratio of two component traits. , 1986 .
[5] D. Houlihan,et al. Recording strategies and selection potential of feed intake measured using the X-ray method in rainbow trout , 2006, Genetics Selection Evolution.
[6] V. Oddy,et al. Biological basis for variation in residual feed intake in beef cattle 1: Review of potential mechanisms , 2004 .
[7] P. Boudinot,et al. Wide range of susceptibility to rhabdoviruses in homozygous clones of rainbow trout. , 2007, Fish & shellfish immunology.
[8] L. D. Van Vleck,et al. Estimates of genetic parameters and selection strategies to improve the economic efficiency of postweaning growth in lambs. , 2003, Journal of animal science.
[9] W. Becker. Manual of procedures in quantitative genetics , 1965 .
[10] J. Silverstein. Relationships among Feed Intake, Feed Efficiency, and Growth in Juvenile Rainbow Trout , 2006 .
[11] J. Pirhonen,et al. Compensatory growth in juvenile rainbow trout, Oncorhynchus mykiss (Walbaum), held individually , 2004 .
[12] D. Crews,et al. Genetics of efficient feed utilization and national cattle evaluation: a review. , 2005, Genetics and molecular research : GMR.
[13] R. Wootton,et al. Effect of cycles of feed deprivation on growth and food consumption of immature three‐spined sticklebacks and European minnows , 2003 .
[14] A Bordas,et al. Direct and correlated responses to divergent selection for residual food intake in Rhode Island Red laying hens. , 1992, British poultry science.
[15] R. Blake,et al. Growth, carcass composition and plasma growth hormone levels in cyclically fed rainbow trout , 2006 .
[16] D. Covés,et al. Techniques for Measuring Feed Intake , 2007 .
[17] Malcolm Jobling,et al. Food intake in fish. , 2001 .
[18] T. Storebakken,et al. Genetic variation in feed intake, growth and feed utilization in Atlantic salmon (Salmo salar) , 2001 .
[19] D. Boichard,et al. Restricted maximum likelihood estimates of genetic parameters of adult male and female Rhode Island red chickens divergently selected for residual feed consumption. , 1995, Poultry science.
[20] F. Médale,et al. Selection for growth in brown trout increases feed intake capacity without affecting maintenance and growth requirements. , 2004, Journal of animal science.
[21] T. Boujard,et al. Selection for growth and feeding hierarchy in brown trout , 2006 .
[22] D. Houlihan,et al. Variation in individual food consumption rates of fish and its implications for the study of fish nutrition and physiology , 1993, Proceedings of the Nutrition Society.
[23] D. Houlihan,et al. Individual variation in protein turnover and growth efficiency in rainbow trout, Oncorhynchus mykiss (Walbaum) , 1994, Proceedings of the Royal Society of London. Series B: Biological Sciences.
[24] S. Siikavuopio,et al. The influence of previous feeding regime on the compensatory growth response of maturing and immature Arctic charr, Salvelinus alpinus , 1993 .
[25] C. Cho. Feeding systems for rainbow trout and other salmonids with reference to current estimates of energy and protein requirements , 1992 .
[26] R. Wootton,et al. Capacity for growth compensation in juvenile three‐spined sticklebacks experiencing cycles of food deprivation , 2001 .
[27] G. Thorgaard,et al. Androgenesis, gynogenesis and the production of clones in fishes: A review , 2007 .
[28] J. Silverstein,et al. Strain differences in feed efficiency measured as residual feed intake in individually reared rainbow trout, Oncorhynchus mykiss (Walbaum) , 2005 .
[29] Robin Thompson,et al. ASREML user guide release 1.0 , 2002 .
[30] S. Helland,et al. A simple method for the measurement of daily feed intake of groups of fish in tanks , 1996 .
[31] T. Boujard,et al. Selection for growth increases feed intake and affects feeding behavior of brown trout , 2004 .
[32] C. Cho,et al. Determination of the energy requirements of fish with particular reference to salmonids , 1995 .
[33] S. Helland,et al. Feed intake, growth and feed utilization of offspring from wild and selected Atlantic salmon (Salmo salar) , 1999 .
[34] B. Grisdale-Helland,et al. Family differences in feed efficiency in Atlantic salmon (Salmo salar) , 2004 .
[35] B. Kinghorn. Genetic variation in food conversion efficiency and growth in rainbow trout , 1983 .
[36] L. Labbé,et al. Enhanced individual selection for selecting fast growing fish: the "PROSPER" method, with application on brown trout (Salmo trutta fario) , 2004, Genetics Selection Evolution.
[37] M. A. Hoque,et al. Genetic parameters for feed efficiency traits and their relationships with growth and carcass traits in Duroc pigs. , 2007, Journal of animal breeding and genetics = Zeitschrift fur Tierzuchtung und Zuchtungsbiologie.
[38] D. Sklan,et al. Comparison of energy and protein efficiency among three fish species gilthead sea bream (Sparus aurata), European sea bass (Dicentrarchus labrax) and white grouper (Epinephelus aeneus): energy expenditure for protein and lipid deposition , 2003 .
[39] Wayne S. Pitchford,et al. Genetic improvement of feed efficiency of beef cattle: what lessons can be learnt from other species? , 2004 .
[40] A. Kause,et al. Breeding salmonids for feed efficiency in current fishmeal and future plant-based diet environments , 2007, Genetics Selection Evolution.
[41] D. Houlihan,et al. Feed efficiency of rainbow trout can be improved through selection: different genetic potential on alternative diets. , 2006, Journal of animal science.
[42] K. Ruohonen,et al. Genetic relationships of body composition and feed utilization traits in European whitefish (Coregonus lavaretus L.) and implications for selective breeding in fishmeal- and soybean meal-based diet environments. , 2007, Journal of animal science.
[43] T. Storebakken,et al. Genetic variation in mineral absorption of large Atlantic salmon (Salmo salar) reared in seawater , 2001 .