<p>The ability of the animal to cope with environmental changes may be measured by log-transformed variance of deviations from expected weights (LnVar). We calculate LnVar by fitting the expected individual growth curve based on longitudinal weights (LnVar<sub>ind</sub>) of Nile tilapia that were grown in either an aerated or a non-aerated freshwater pond. We estimated genetic parameters for LnVar<sub>ind</sub> in Nile tilapia, the genetic correlation between LnVar<sub>ind</sub> and growth and the genetic correlation for LnVar<sub>ind</sub> between aerated and non-aerated pond. The heritability estimate for LnVar<sub>ind</sub> (0.28) in the non-aerated pond was higher than in aerated pond (0.06). In the aerated pond, genetic correlations of LnVar<sub>ind</sub> were − 0.44 ± 0.23 with daily growth coefficient (DGC) and − 0.45 ± 0.24 with harvest weight (W<sub>5</sub>). In the non-aerated pond, genetic correlations with DGC and W<sub>5</sub> were − 0.68 ± 0.12 and − 0.52 ± 0.17, respectively. These values suggest that selection for fish with high growth rate will reduce LnVar<sub>ind</sub>. However, genetic correlation of LnVar<sub>ind</sub> between aerated and non-aerated pond was 0.50, suggesting that genetic improvement in the aerated environment will reduce LnVar<sub>ind</sub> in the non-aerated environment. Therefore, incorporating records from relatives in non-aerated pond is beneficial for breeding programs targeting this environment.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Log-transformed variance from individual growth curves as a potential indicator of resilience in Nile tilapia Oreochromis niloticus

  • Muhammad Hunaina Fariduddin Aththar,
  • Samuel Bekele Mengistu,
  • John A.H. Benzie,
  • Hans Komen,
  • John W.M. Bastiaansen

摘要

The ability of the animal to cope with environmental changes may be measured by log-transformed variance of deviations from expected weights (LnVar). We calculate LnVar by fitting the expected individual growth curve based on longitudinal weights (LnVarind) of Nile tilapia that were grown in either an aerated or a non-aerated freshwater pond. We estimated genetic parameters for LnVarind in Nile tilapia, the genetic correlation between LnVarind and growth and the genetic correlation for LnVarind between aerated and non-aerated pond. The heritability estimate for LnVarind (0.28) in the non-aerated pond was higher than in aerated pond (0.06). In the aerated pond, genetic correlations of LnVarind were − 0.44 ± 0.23 with daily growth coefficient (DGC) and − 0.45 ± 0.24 with harvest weight (W5). In the non-aerated pond, genetic correlations with DGC and W5 were − 0.68 ± 0.12 and − 0.52 ± 0.17, respectively. These values suggest that selection for fish with high growth rate will reduce LnVarind. However, genetic correlation of LnVarind between aerated and non-aerated pond was 0.50, suggesting that genetic improvement in the aerated environment will reduce LnVarind in the non-aerated environment. Therefore, incorporating records from relatives in non-aerated pond is beneficial for breeding programs targeting this environment.