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A genetic analysis of litter traits in Bauscat and Giza White rabbits

Published online by Cambridge University Press:  02 September 2010

M. H. Khalil
Affiliation:
Department of Animal Production, Faculty of Agriculture at Moshtohor, Zagazig University, Banha Branch, Egypt
J. B. Owen
Affiliation:
Department of Agriculture, University College of North Wales, Bangor, Gwynedd LL57 2UW
E. A. Afifi
Affiliation:
Department of Animal Production, Faculty of Agriculture at Moshtohor, Zagazig University, Banha Branch, Egypt
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Abstract

An analysis of doe productivity traits was carried out on 884 litter records including 52 sires and 210 daughters (paternal half sisters) of Bauscat (B) and Giza White (G) rabbits. Traits examined included litter size and weight at birth and at weaning, pre-weaning mortality and mean weight of young at weaning. Year-of-kindling affected most litter traits but no pattern of parity effects on litter size and pre-weaning mortality was observed. Litter weight and mean weight of young at weaning generally increased linearly as parity advanced. Litter size and weight and mean weight of young tended to increase as month of kindling advanced from October to March, and to decrease again during April and May. Pre-weaning mortality decreased as month of kindling advanced up to March and increased thereafter during April and May. The sire of the doe affected all litter traits studied, with the exception of litter size at birth and pre-weaning mortality in the B breed. Estimates of heritability for most of the litter traits were moderate or high. Genetic and phenotypic correlations among litter size traits and between litter size and litter weight traits were positive and relatively moderate or large. Litter weight traits were positively correlated both genetically and phenotypically. The genetic and phenotypic correlations between litter size traits and mean weight of young at weaning were negative and relatively moderate or large.

Type
Research Article
Copyright
Copyright © British Society of Animal Science 1987

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References

Afifi, E. A., Galal, E. S. E., El-Oksh, H. A. and Kadry, A. E. 1980. Inter-relationships among doe's weight, litter size, litter weight and body weight at different ages in rabbits. Egyptian Journal of Animal Production 20: 127136.Google Scholar
Afifi, E. A., Galal, E. S. E., El-Tawil, E. A. and El-Khishin, S. S. 1976a. Litter weight in three breeds of rabbits and their crosses. Egyptian Journal of Animal Production 16: 99108.Google Scholar
Afifi, E. A., Galal, E. S. E., El-Tawil, E. A. and El-Khishin, S. S. 1976b. Litter size at birth and at weaning in three breeds of rabbits and their crosses. Egyptian Journal of Animal Production 16: 109119.Google Scholar
Afifi, E. A., Galal, E. S. E. and Kadry, A. E. H. 1982. The effect of breed and some environmental factors on litter traits in rabbits. 7th International Congress for Statistics, Computer Science, Social Demographic Research, Ain Shams University, Cairo, Egypt.Google Scholar
Baselga, M., Blasco, A. and Garcia, F. 1982. Genetic parameters for economic traits in rabbit populations. Proceedings of 2nd World Congress on Genetics Applied to Livestock Production, Madrid, pp. 471480.Google Scholar
Dadlani, H. V. and Prabhu, S. S. 1971a. Quantitative genetic studies in the mouse (Mus musculus L.). I. Litter size. Journal of Genetics 60: 184191.Google Scholar
Dadlani, H. V. and Prabhu, S. S. 1971b. Quantitative genetic studies in the mouse (Mus musculus L.). II. Litter weight. Journal of Genetics 60: 207213.Google Scholar
El-Khishin, A. F., Badreldin, A. L., Oloufa, M. M. and Kheireldin, M. A. 1951. Growth development and litter size in two breeds of rabbits. Bulletin, Faculty of Agriculture, Cairo University, Egypt, No. 2.Google Scholar
Emara, M. E. A. 1982. Effect of crossbreeding on some productive traits in rabbits. Ph.D. Thesis, Faculty of Agriculture, Moshtohor, Zagazig University, Egypt.Google Scholar
Garcia, F., Blasco, A., Baselga, M. and Salvador, A. 1980. [Genetic analysis of some reproductive traits n i meat rabbits.] Proceedings 2nd World Rabbit Congress, Barcelona. Annales de Genetique et de Selection Animate 12: 297 (Abstr.).Google Scholar
Gill, J. L. and Jensen, E. L. 1968. Probability of obtaining negative estimates of heritability. Biometrics 24: 517526.Google Scholar
Hanrahan, J. P. and Eisen, E. J. 1974. Genetic variation in litter size and 12-day weight in mice and their relationships with post-weaning growth. Animal Production 19: 1323.Google Scholar
Harvey, W. R. 1977. User's guide for LSML76. Mixed model least-squares and maximum likelihood computer program. Ohio State University, Columbus, (Mimeograph).Google Scholar
Henderson, C. R. 1953. Estimation of variance and covariance components. Biometrics 9: 226252.Google Scholar
Holdas, S. and Szendro, Z. 1982. Milk production of rabbits. Hungarian Agricultural Review 32: 95.Google Scholar
Khalil, M. H. E. 1980. Genetic and environmental studies on some productive traits in rabbits. M.Sc. Thesis, Faculty of Agricultural Science, Moshtohor, Zagazig University, Egypt.Google Scholar
Lahiri, S. S. and Mahajan, J. M. 1982. Note on the inheritance of age at first breeding, litter size and weight in rabbits. Indian Journal of Animal Sciences 52: 11481150.Google Scholar
Lampo, P. and Broeck, L. van den. 1975. [The influence of the heritability of some breeding parameters and the correlations between these parameters with rabbits.] Archiv fur Geflilgelkunde 39: 108211.Google Scholar
Lukefahr, S. 1982. Evaluation of rabbit breeds and crosses for overall commercial productivity. Ph.D. Thesis, Oregon State University, Corvallis, USA.Google Scholar
Lukefahr, S., Hohenboken, W. D., Cheeke, P. R. and Patton, N. M. 1983. Doe reproduction and preweaning litter performance of straightbred and crossbred rabbits. Journal of Animal Science 57: 10901099.Google Scholar
Lukefahr, S., Hohenboken, W. D., Cheeke, P. R. and Patton, N. M. 1984. Genetic effects on maternal performance and litter pre-weaning and post-weaning traits in rabbits. Animal Production 38: 293300.Google Scholar
Rollins, W. C., Casady, R. B., Sittmann, K. and Sittmann, D. B. 1963. Genetic variance component analysis of litter size and weaning weight of New Zealand White rabbits. Journal of Animal Science 22: 654657.Google Scholar
Rouvier, R., Poujardieu, B. and Vrillon, J.-L. 1973. [Statistical analysis of the breeding performance of female rabbits: Environmental factors, correlations and repeatabilities.] Annales de Genetique et de Selection Animate 5: 83107.Google Scholar
Schlolaut, W. 1982: The Nutrition of the Rabbit. Roche, Animal Nutrition Department, Switzerland.Google Scholar
Swiger, L. A., Harvey, W. R., Everson, D. O. and Gregory, K. E. 1964. The variance of intra-class correlation involving groups with one observation. Biometrics 20: 818826.Google Scholar
Tallis, G. M. 1959. Sampling errors of genetic correlation coefficients calculated from analysis of variance and covariance. Australian Journal of Statistics 1: 35.Google Scholar