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V p – the total variance in the phenotypic trait of a population.

Typically, this variation is considered as the phenotypic variation. Heritability – “the fraction of the total variation in a trait that is due to variation in genes.” (Freeman and Herron, 2007). V p – the total variance in the phenotypic trait of a population. V P = V G + V E

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V p – the total variance in the phenotypic trait of a population.

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  1. Typically, this variation is considered as the phenotypic variation. Heritability – “the fraction of the total variation in a trait that is due to variation in genes.” (Freeman and Herron, 2007) Vp – the total variance in the phenotypic trait of a population. VP = VG + VE VG = Genetic variation VE = Environmental variation

  2. Broad Sense Heritability h2 or H2 The problem? VG represents all of the genetic variation as a single value.

  3. Real genetic variation is complicated. VA = additive genetic variance VD = dominance genetic variance VI = variance due to epistatic interactions

  4. Additive Variation –VA • Important because it is why relatives resemble each other. • Alleles act independently. • The phenotype of an organism is the sum of the effect of each allele, hence additive. • Additive alleles are not affected by the presence of other alleles. • The effect of additive alleles allow biologists to follow evolution in a predictable way.

  5. Additive Variation –VA A1 = 0.5, A2 = 0.5 Note: The best fit line (far right) explains all of the genetic variation. VG = VA.

  6. Dominance Variation –VD • The addition of alleles is not additive. • Dominance is one type of variation where alleles interact (between sister alleles on other chromosome). • The effect of an allele depends upon what it is paired with. • Because of this dependence, the outcome of dominance variation is not entirely predictable - it is context dependent. • This context disappears every generation because of meiosis. The pairing of an allele with a sister allele on another chromosome in forming a zygote is unpredictable. • Because of this , the effects of dominance variation change every generation, and are not predictable.

  7. Dominance Variation –VD A1 = 0.5, A2 = 0.5 Note: Adding a second copy of A2 does not change the phenotype. The Dominance Variation (VD) does not explain all of the Genetic Variation (VG). VG = VA + VD

  8. Epistatic Effects –VI • The effect of an allele at a locus is dependent the presence of an allele at another locus. • The phenotype is dependent upon the allele at one locus interacting with an allele at another locus. Not a predictable outcome. • Allele X may affect the phenotype one way in the presence of allele A, and affect the phenotype another way in the presence of allele B. • Because of this dependence, the outcome of epistasis is not entirely predictable - it is context dependent. • This context disappears every generation because of meiosis. When chromosomes independently assort and recombine, the pairings of alleles change. • Because of this , the effects of epistasis change every generation, and are not predictable.

  9. Narrow-Sense Heritability h2 or H2 In determining heritability, only narrow-sense heritability is used, because only the variation due to additive effects permits predictions due to selection.

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