effect of naked neck gene and ambient temperature and their interaction on reproductive traits of heavy broiler dams

High ambient temperature is a major factor for diminishing reproductive performance of broiler parent stocks. Homozygous naked neck (NaNa) broilers, which possess a higher adaptation to heat due to a reduction of feather coverage, exhibited higher growth rates and meat yield. This study was conducte...

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Bibliographic Details
Published in:Poultry science 2010-07, Vol.89 (7), p.1360-1371
Main Authors: Sharifi, A.R, Horst, P, Simianer, H
Format: Article
Language:English
Subjects:
air temperature
animal reproduction
Animals
Body Weight - genetics
Body Weight - physiology
broiler chickens
cell respiration
Chickens - genetics
Chickens - metabolism
Chickens - physiology
chicks
Crosses, Genetic
developmental stages
egg hatchability
Eggs
embryo (animal)
embryogenesis
embryonic mortality
feathers
Feathers - physiology
fecundity
Female
food animals
genotype
genotype-environment interaction
heat stress
hens
homozygosity
Hot Temperature - adverse effects
Male
oxygen
oxygen consumption
Oxygen Consumption - physiology
Reproduction - genetics
Reproduction - physiology
Tropical Climate
viability
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Summary:High ambient temperature is a major factor for diminishing reproductive performance of broiler parent stocks. Homozygous naked neck (NaNa) broilers, which possess a higher adaptation to heat due to a reduction of feather coverage, exhibited higher growth rates and meat yield. This study was conducted to investigate the influence of genotype x temperature interactions on the reproduction traits of heavy broiler dams caused by different feathering genotypes induced by naked neck gene (Na). In an additional experiment, the effect of Na gene on embryonic activity using oxygen uptake was examined. Normal-feathered (nana) and NaNa hens were maintained in separate cages under high (30°C) and moderate (19°C) temperatures, with RH of 55% from the 18th to 72nd week of age. Egg production, fertility, hatchability, and the time of embryonic mortality were recorded. In comparison with the NaNa genotype, the nana hens showed clear performance depressions under thermal stress with respect to egg production (63%), fertility (20%), hatchability, and number of chicks (72%). Under temperate ambient temperature, there were no differences in laying performance and fertility between both genotypes, with the exception of hatchability due to an increase in embryonic mortality as a result of the Na gene and consequently in the complex trait number of chicks. The early embryonic mortality of eggs laid by nana hens exposed to heat stress is clearly higher than of eggs by nana hens kept under temperate ambient temperature. In contrast, there were no significant differences in early embryonic mortality of eggs of NaNa birds kept under high and temperate environmental temperatures, demonstrating that heat stress leads to reduced early embryonic livability. Embryonic mortality in the late developing stage is significantly increased, and the homozygous genotype is much more affected than the heterozygous embryo. The possible reason for the Na gene-induced embryonic mortality is still not clear. In this investigation, it is shown that the phenomenon cannot be explained by the oxygen consumption.
ISSN:0032-5791
1525-3171
DOI:10.3382/ps.2009-00593