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Premium member Presentation Transcript Lecture 5 Artificial Selection: Lecture 5 Artificial Selection R = h2 SApplications of Artificial Selection: Applications of Artificial Selection Applications in agriculture and forestry Creation of model systems of human diseases and disorders Construction of genetically divergent lines for QTL mapping and gene expression (microarray) analysis Inferences about numbers of loci, effects and frequencies Evolutionary inferences: correlated characters, effects on fitness, long-term response, effect of mutations Response to Selection: Response to Selection Selection can change the distribution of phenotypes, and we typically measure this by changes in mean This is a within-generation change Selection can also change the distribution of breeding values This is the response to selection, the change in the trait in the next generation (the between-generation change)The Selection Differential and the Response to Selection: The Selection Differential and the Response to Selection The selection differential S measures the within-generation change in the mean S = m* - m The response R is the between-generation change in the mean R(t) = m(t+1) - m(t) The Breeders’ Equation: Translating S into R: The Breeders’ Equation: Translating S into R Recall the regression of offspring value on midparent value Averaging over the selected midparents, E[ (Pf + Pm)/2 ] = m*, Since E[ yo - m ] is the change in the offspring mean, it represents the response to selection, giving:Slide7: Note that no matter how strong S, if h2 is small, the response is small S is a measure of selection, R the actual response. One can get lots of selection but no response If offspring are asexual clones of their parents, the breeders’ equation becomes R = H2 S If males and females subjected to differing amounts of selection, S = (Sf + Sm)/2 An Example: Selection on seed number in plants -- pollination (males) is random, so that S = Sf/2 Response over multiple generations: Response over multiple generations Strictly speaking, the breeders’ equation only holds for predicting a single generation of response from an unselected base population Practically speaking, the breeders’ equation is usually pretty good for 5-10 generations The validity for an initial h2 predicting response over several generations depends on: The reliability of the initial h2 estimate Absence of environmental change between generations The absence of genetic change between the generation in which h2 was estimated and the generation in which selection is appliedSlide9: The selection differential is a function of both the phenotypic variance and the fraction selectedThe Selection Intensity, i: The Selection Intensity, i As the previous example shows, populations with the same selection differential (S) may experience very different amounts of selection The selection intensity i provided a suitable measure for comparisons between populations, One important use of i is that for a normally-distributed trait under truncation selection, the fraction saved p determines i, Selection Intensity Versions of the Breeders’ Equation: Selection Intensity Versions of the Breeders’ EquationThe Realized Heritability: The Realized Heritability Since R = h2 S, this suggests h2 = R/S, so that the ratio of the observed response over the observed differential provides an estimate of the heritability, the realized heritability Obvious definition for a single generation of response. What about for multiple generations of response?Slide13: (2) The Regression Estimator --- the slope of the Regression of cumulative response on cumulative differentialGene frequency changes under selection: Gene frequency changes under selection Additive fitnesses Let q = freq(A2). The change in q from one generation of selection is:Strength of selection on a QTL: Strength of selection on a QTL Have to translate from the effects on a trait under selection to fitnesses on an underlying locus (or QTL) Suppose the contributions to the trait are additive: For a trait under selection (with intensity i) and phenotypic variance sP2, the induced fitnesses are additive with s = i (a /sP ) Thus, drift overpowers selection on the QTL whenMore generally: More generallyChanges in the Variance under Selection: Changes in the Variance under Selection The infinitesimal model --- each locus has a very small effect on the trait. Under the infinitesimal, require many generations for significant change in allele frequencies However, can have significant change in genetic variances due to selection creating linkage disequilibrium Under linkage equilibrium, freq(AB gamete) = freq(A)freq(B) With positive linkage disequilibrium, f(AB) > f(A)f(B), so that AB gametes are more frequent With negativve linkage disequilibrium, f(AB) < f(A)f(B), so that AB gametes are less frequentSlide19: Changes in VA with disequilibrium Under the infinitesimal model, disequilibrium only changes the additive variance. Starting from an unselected base population, a single generation of selection generates a disequilibrium contribution d to the additive variance Changes in VA and VP change the heritability A decrease in the variance generates d < 0 and hence negative disequilibrium An increase in the variance generates d > 0 and hence positive disequilibriumSlide20: A “Breeders’ Equation” for Changes in Variance d(0) = 0 (starting with an unselected base population) k > 0. Within-generation reduction in variance. negative disequilibrium, d < 0 k < 0. Within-generation increase in variance. positive disequilibrium, d > 0 You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
Lecture5 Justine Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 620 Category: Entertainment License: All Rights Reserved Like it (0) Dislike it (0) Added: November 19, 2007 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Lecture 5 Artificial Selection: Lecture 5 Artificial Selection R = h2 SApplications of Artificial Selection: Applications of Artificial Selection Applications in agriculture and forestry Creation of model systems of human diseases and disorders Construction of genetically divergent lines for QTL mapping and gene expression (microarray) analysis Inferences about numbers of loci, effects and frequencies Evolutionary inferences: correlated characters, effects on fitness, long-term response, effect of mutations Response to Selection: Response to Selection Selection can change the distribution of phenotypes, and we typically measure this by changes in mean This is a within-generation change Selection can also change the distribution of breeding values This is the response to selection, the change in the trait in the next generation (the between-generation change)The Selection Differential and the Response to Selection: The Selection Differential and the Response to Selection The selection differential S measures the within-generation change in the mean S = m* - m The response R is the between-generation change in the mean R(t) = m(t+1) - m(t) The Breeders’ Equation: Translating S into R: The Breeders’ Equation: Translating S into R Recall the regression of offspring value on midparent value Averaging over the selected midparents, E[ (Pf + Pm)/2 ] = m*, Since E[ yo - m ] is the change in the offspring mean, it represents the response to selection, giving:Slide7: Note that no matter how strong S, if h2 is small, the response is small S is a measure of selection, R the actual response. One can get lots of selection but no response If offspring are asexual clones of their parents, the breeders’ equation becomes R = H2 S If males and females subjected to differing amounts of selection, S = (Sf + Sm)/2 An Example: Selection on seed number in plants -- pollination (males) is random, so that S = Sf/2 Response over multiple generations: Response over multiple generations Strictly speaking, the breeders’ equation only holds for predicting a single generation of response from an unselected base population Practically speaking, the breeders’ equation is usually pretty good for 5-10 generations The validity for an initial h2 predicting response over several generations depends on: The reliability of the initial h2 estimate Absence of environmental change between generations The absence of genetic change between the generation in which h2 was estimated and the generation in which selection is appliedSlide9: The selection differential is a function of both the phenotypic variance and the fraction selectedThe Selection Intensity, i: The Selection Intensity, i As the previous example shows, populations with the same selection differential (S) may experience very different amounts of selection The selection intensity i provided a suitable measure for comparisons between populations, One important use of i is that for a normally-distributed trait under truncation selection, the fraction saved p determines i, Selection Intensity Versions of the Breeders’ Equation: Selection Intensity Versions of the Breeders’ EquationThe Realized Heritability: The Realized Heritability Since R = h2 S, this suggests h2 = R/S, so that the ratio of the observed response over the observed differential provides an estimate of the heritability, the realized heritability Obvious definition for a single generation of response. What about for multiple generations of response?Slide13: (2) The Regression Estimator --- the slope of the Regression of cumulative response on cumulative differentialGene frequency changes under selection: Gene frequency changes under selection Additive fitnesses Let q = freq(A2). The change in q from one generation of selection is:Strength of selection on a QTL: Strength of selection on a QTL Have to translate from the effects on a trait under selection to fitnesses on an underlying locus (or QTL) Suppose the contributions to the trait are additive: For a trait under selection (with intensity i) and phenotypic variance sP2, the induced fitnesses are additive with s = i (a /sP ) Thus, drift overpowers selection on the QTL whenMore generally: More generallyChanges in the Variance under Selection: Changes in the Variance under Selection The infinitesimal model --- each locus has a very small effect on the trait. Under the infinitesimal, require many generations for significant change in allele frequencies However, can have significant change in genetic variances due to selection creating linkage disequilibrium Under linkage equilibrium, freq(AB gamete) = freq(A)freq(B) With positive linkage disequilibrium, f(AB) > f(A)f(B), so that AB gametes are more frequent With negativve linkage disequilibrium, f(AB) < f(A)f(B), so that AB gametes are less frequentSlide19: Changes in VA with disequilibrium Under the infinitesimal model, disequilibrium only changes the additive variance. Starting from an unselected base population, a single generation of selection generates a disequilibrium contribution d to the additive variance Changes in VA and VP change the heritability A decrease in the variance generates d < 0 and hence negative disequilibrium An increase in the variance generates d > 0 and hence positive disequilibriumSlide20: A “Breeders’ Equation” for Changes in Variance d(0) = 0 (starting with an unselected base population) k > 0. Within-generation reduction in variance. negative disequilibrium, d < 0 k < 0. Within-generation increase in variance. positive disequilibrium, d > 0