The existence of the genome population in condition of radiation environment has been considered. The differences between the laws of the allele frequencies for autosomal genes and genes linked to sex are described. R...The existence of the genome population in condition of radiation environment has been considered. The differences between the laws of the allele frequencies for autosomal genes and genes linked to sex are described. Radiation conditions were found at maintenance of the balance of the Hardy-Weinberg genotype in the population, as well as conditions of complete elimination of the targeted allele by ionizing radiation. Conclusions about the nature of radiation resistance of the population are drawn.展开更多
Inbreeding,which refers to situations where relatives are mating,is unavoidable in aquaculture populations because of their restricted population size.The rate of inbreeding in a population is roughly equal to one ove...Inbreeding,which refers to situations where relatives are mating,is unavoidable in aquaculture populations because of their restricted population size.The rate of inbreeding in a population is roughly equal to one over twice the ’effective population size’,1/(2N_e),but a more accurate ’inbreeding coefficient’(F) is usually used to quantify inbreeding in populations undergoing artificial and/or natural selection.Inbreeding usually leads to reductions of performance in aquaculture species.Such ’inbreeding depression’ is mainly the result of recessive deleterious genes being unmasked and expressed in homozygous individuals.All aquaculture populations will accumulate recessive deleterious genes because of mutations in the DNA.It is assumed that most aquaculture species have a ’genetic load’ of about 100 recessive deleterious genes,which would be more than enough to cause the extinction of that species if these genes were made homozygous through mating between relatives.A literature review confirmed that traits related to the overall fitness of aquaculture species are strongly affected by inbreeding(ranging between 3%-50% inbreeding depression per 10% increase of the inbreeding coefficient,F).Fast inbreeding through full-sib mating has resulted,on average,in three times higher inbreeding depression in growth compared to slow inbreeding in large-scale selective breeding programs.Studies with other species suggest that slow inbreeding usually lead to more effective purging of recessive deleterious genes than rapid full-sib inbreeding since fewer genes are fixed because of random drift.Inbreeding will also reduce the additive genetic variation within hatchery populations,but increases the additive genetic variation between isolated hatchery populations.Inbred populations usually show different responses in different environments due to the reduced additive genetic variance and their loss of ability to adapt to environmental changes.Therefore,efforts should be made to restrict inbreeding and its negative c展开更多
文摘The existence of the genome population in condition of radiation environment has been considered. The differences between the laws of the allele frequencies for autosomal genes and genes linked to sex are described. Radiation conditions were found at maintenance of the balance of the Hardy-Weinberg genotype in the population, as well as conditions of complete elimination of the targeted allele by ionizing radiation. Conclusions about the nature of radiation resistance of the population are drawn.
文摘Inbreeding,which refers to situations where relatives are mating,is unavoidable in aquaculture populations because of their restricted population size.The rate of inbreeding in a population is roughly equal to one over twice the ’effective population size’,1/(2N_e),but a more accurate ’inbreeding coefficient’(F) is usually used to quantify inbreeding in populations undergoing artificial and/or natural selection.Inbreeding usually leads to reductions of performance in aquaculture species.Such ’inbreeding depression’ is mainly the result of recessive deleterious genes being unmasked and expressed in homozygous individuals.All aquaculture populations will accumulate recessive deleterious genes because of mutations in the DNA.It is assumed that most aquaculture species have a ’genetic load’ of about 100 recessive deleterious genes,which would be more than enough to cause the extinction of that species if these genes were made homozygous through mating between relatives.A literature review confirmed that traits related to the overall fitness of aquaculture species are strongly affected by inbreeding(ranging between 3%-50% inbreeding depression per 10% increase of the inbreeding coefficient,F).Fast inbreeding through full-sib mating has resulted,on average,in three times higher inbreeding depression in growth compared to slow inbreeding in large-scale selective breeding programs.Studies with other species suggest that slow inbreeding usually lead to more effective purging of recessive deleterious genes than rapid full-sib inbreeding since fewer genes are fixed because of random drift.Inbreeding will also reduce the additive genetic variation within hatchery populations,but increases the additive genetic variation between isolated hatchery populations.Inbred populations usually show different responses in different environments due to the reduced additive genetic variance and their loss of ability to adapt to environmental changes.Therefore,efforts should be made to restrict inbreeding and its negative c
