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Models of Selection

Models of Selection. Goal: to build models that can predict a population’s response to natural selection What are the key factors? Today’s model: haploid, one locus Outline: triclosan in biosolids fitness haploid life cycle selection coefficients

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Models of Selection

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  1. Models of Selection • Goal: to build models that can predict a population’s response to natural selection • What are the key factors? • Today’s model: haploid, one locus • Outline: triclosan in biosolids • fitness • haploid life cycle • selection coefficients • long term predictions

  2. When does selection act?

  3. Triclosan and biosolids Triclosan: Biosolids: Triclosan in biosolids??

  4. Fitness: The sum total effect of selection within a generation • Absolute Fitness = • Relative Fitness =

  5. Key questions for model

  6. One-locus haploid model • For what organisms is this model appropriate?

  7. Initial frequencies, fitness f(A) = p(t) f(a) = q(t) WA = relative fitness of A Wa = relative fitness of a

  8. One-locus haploid model f'(A) = __WAp(t)___ WAp(t) + Waq(t) f'(a) = __Waq(t)___ WAp(t) + Waq(t) Example: p(t) = 0.5; q(t) = 0.5 WA = 1; Wa = 0.8 WA Wa p[t] q[t]

  9. p(t)WA p(t)WA + q(t)Wa One-locus haploid model

  10. A A A A A A A A A A A A A A A A A A A A A a a a a a a a a a a a a a a a a a a a Relative, not absolute, fitness determines changes in allele frequencies 6 A, 6 a 6 A, 6 a Survival of A = 1/2, of a = 1/3 Survival of A = 1, of a = 2/3 f’(A) = 0.6 f’(A) = 0.6

  11. Haploid selection: rest of life cycle

  12. One-locus haploid model • Adults mate at random • Undergo meiosis

  13. One-locus haploid model p(t+1) = p(t)WA p(t)WA + q(t)Wa p = p(t+1) – p(t) = (WA – Wa)p(t)q(t) W(t) W(t) = p(t)WA + q(t)Wa

  14. One-locus haploid model p = p(t+1) – p(t) = (WA – Wa)p(t)q(t) W(t) What does this tell us about selection?

  15. A note about variance

  16. What will happen over periods of time longer than one generation? • We can use a simple trick to answer this question. If we divide p[t+1] by q[t+1]: p(t+1) p(t)WA q(t+1) q(t)Wa = The ratio of p[t] to q[t] changes by WA/Wa every generation.

  17. Now, for any generation t: p(t) p(0)WAt q(t) q(0)Wat = q(t) = 1- p(t), so p(0)WAt p(0)WAt + q(0)Wat p(t) = Predicting allele frequencies hint: keep right side together, divide by fraction

  18. p(t) = p(0)WAt p(0)WAt + q(0)Wat Using the model I What would the frequency of allele A be after 100 generations of selection if A is 10% more fit than allele a and if one in every hundred alleles is initially A?

  19. p(t) p(0)WAt q(t) q(0)Wat = Using the model II If A changes in frequency from 0.001 to 0.01 in 10 generations, by how much must it be favored?

  20. Selection coefficients

  21. Selection coefficient example How long would it take for 95% of the alleles to be A if A is initially present in 5% of the population and if the selection coefficient favoring allele A is... s = 0.1?

  22. Some general principles • The time needed for an allele to go from low frequency to high is the inverse of the selection coefficient • s = 0.1 -> tens of generations

  23. Var(W(t)) = p(t)(WA - W(t))2 + q(t)(Wa-W(t))2 = p(t)q(t)(WA - Wa)2 ΔW = W(t+1) - W(t) = Var(W(t)) W(t) • Does the mean fitness of a population always increase over time?

  24. The Fundamental Theorem of Natural Selection • "The rate of increase in fitness of any organism at any time is equal to its genetic variance in fitness at that time." • R. A. Fisher (1930) The Genetical Theory of Natural Selection

  25. Example: Dykhuizen and Dean (1990) • Two strains of E. coli (TD9 and TD1) • Had a genetic difference in the lactose pathway • Competed in two environments: • Glucose-limited (Open symbols) • Lactose-limited (Closed symbols) • What is the selection coefficient (s)?

  26. References and readings • References • Heidler, J. et al. 2006. Partitioning, Persistence, and Accumulation in Digested Sludge of the Topical Antiseptic Triclocarban during Wastewater Treatment. Environ. Sci. Technol.; 40(11); 3634-3639 • Readings • Chapter 6.1 – 6.3 (5.1 – 5.3), question 3. • More questions • Would a dominant or recessive allele change frequency faster in a haploid organism? why? • Calculate the relative fitnesses for these two genotypes: • genotype: A a • starting count (before selection) 100 100 • ending count (after selection) 90 30 • What is the selection co-efficient? • Assume that the mixture starts out with f(A) = 0.5. What will the frequency be after 20 generations?

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