1. Evolution Evolution is genetic change in a line of descent through successive generations Cumulative change in a species over time

2. Early Scientific Theories Scala Naturae – Aristotle: life forms could be arranged on a scale of increasing complexity The Great Chain of Being –All species separate link –Each link created at the same time in the center of creation –All links have remained the same since creation New Evidence challenged these

3. Biogeography The world’s distribution of organisms Size of the known world expanded enormously in the 15th century Discovery of new organisms in previously unknown places could not be explained by accepted beliefs –How did species get from center of creation to all these places?

4. Comparative Morphology Study of similarities and differences in body plans of major groups Puzzling patterns: –Animals as different as whales and bats have similar bones in forelimbs –Some parts seem to have no function

5. Geological Discoveries Similar rock layers throughout world Certain layers contain fossils Deeper layers contain simpler fossils than shallow layers Some fossils seem to be related to known species

6. 19th Century - New Theories Scientists attempt to reconcile evidence of change with traditional belief in a single creation event –Georges-Louis Leclerc de Buffon – perhaps species originated in more than one place and perhaps they were modified over time –Georges Cuvier - multiple catastrophes –Jean Lamarck - inheritance of acquired characteristics (environmental pressures change individuals and the changes are passed on to their offspring) Use and disuse

7. The Theory of Uniformity Lyell’s Principles of Geology (book) Subtle, repetitive processes of change had shaped Earth (theory of uniformity) Challenged the view that Earth was only 6,000 years old

8. Darwin’s Voyage At age 22, Charles Darwin began a five- year, round-the-world voyage aboard the Beagle In his role as ship’s naturalist, he collected and examined the species that inhabited the regions the ship visited

9. Galapagos Islands Isabela Darwin Wolf Pinta Marchena Genovesa Fernandia Santiago Bartolomé Rabida Pinzon Seymour Baltra Santa Cruz Santa Fe Tortuga Española San Cristobal Floreana Volcanic islands far off coast of Ecuador All inhabitants are descended from species that arrived on islands from elsewhere Figure 17.4d Page 275

10. Malthus - Struggle to Survive Thomas Malthus, a clergyman and economist, wrote an essay that Darwin read on his return to England Argued that as human population size increases, resources dwindle, the struggle to live intensifies, and conflict increases

11. Darwin Expands Suspected that any population has the capacity to produce more individuals than the environment can support The environment restricts the number of reproducing individuals Variations in traits might affect an individual’s ability to secure resources, survive, and reproduce in particular environments

12. Darwin’s Theory A population can change over time when individuals differ in one or more heritable traits that are responsible for differences in the ability to survive and reproduce in certain environments. (descent with modification) Gradual evolution by natural selection

13. Darwin’s “Theory” In what way is evolution both fact and theory?

14. Alfred Wallace Naturalist who arrived at the same conclusions Darwin did Wrote to Darwin describing his views Prompted Darwin to finally present his ideas in a formal paper

15. Populations Evolve Biological evolution does not change individuals, it changes a population Traits in a population vary among individuals Evolution is change in frequency of traits

16. Genetic Equilibrium Allele frequencies at a locus are not changing Population is not evolving

17. Hardy-Weinberg theorem: Five Conditions for Genetic Equilibrium No mutation Random mating Gene doesn’t affect survival or reproduction Large population No immigration/emigration

18. Microevolutionary Processes Drive a population away from genetic equilibrium Small-scale changes in allele frequencies brought about by: –Natural selection –Gene flow –Genetic drift

19. Gene Mutations Infrequent but inevitable Each gene has own mutation rate Lethal mutations Neutral mutations Advantageous mutations

20. Hardy-Weinberg Rule (read the focus on science section in this chapter (17.5) At genetic equilibrium, proportions of genotypes at a locus with two alleles are given by the equation: p 2 + 2pq + q 2 = 1 –Frequency of dominant allele = p, frequency of recessive allele = q Used to see if allelic frequencies change between generations (can detect evolution) –Can only remain stable if the 5 assumptions of the rule are met (no mutations, large population, isolated population, all individuals survive and reproduce equally, and random matings occur)

21. Natural Selection A difference in the survival and reproductive success of different phenotypes Acts directly on phenotypes and indirectly on genotypes Eventually the individuals of a population will end up competing for resources Some phenotypes compete better than others

22. Change over Time Over time, the alleles that produce the most successful phenotypes will increase in the population Less successful alleles will become less common Change leads to increased fitness –Increased adaptation to environment

23. Directional Selection Allele frequencies shift in one direction Number of individuals in the population Range of values for the trait at time 1 Range of values for the trait at time 2 Range of values for the trait at time 3 Number of individuals in the population Number of individuals in the population Figure 17.10 Page 282

24. Stabilizing Selection Intermediate forms are favored and extremes are eliminated Number of individuals in the population Range of values for the trait at time 1 Range of values for the trait at time 2 Range of values for the trait at time 3 Figure 17.12 Page 284

25. Disruptive or Diversifying Selection Forms at both ends of the range of variation are favored Intermediate forms are selected against Number of individuals in the population Range of values for the trait at time 1 Range of values for the trait at time 2 Range of values for the trait at time 3 Number of individuals in the population Number of individuals in the population Figure 17.14 Page 285

26. Sexual Selection Selection favors certain secondary sexual characteristics Through nonrandom mating, alleles for preferred traits increase Leads to increased sexual dimorphism

27. Sickle-Cell Trait: Heterozygote Advantage Allele Hb S causes sickle-cell anemia when heterozygous Heterozygotes are more resistant to malaria than homozygotes less than 1 in 1,600 1 in 400-1,600 1 in 180-400 1 in 100-180 1 in 64-100 more than 1 in 64 Malaria case Sickle-cell trait Figure 17.17 Page 286-287

28. Gene Flow Physical flow of alleles into and out of a population –Through immigration and emigration Tends to keep the gene pools of populations similar –Keeps separated populations genetically similar Counters the differences that result from mutation, natural selection, and genetic drift Could move a unique gene in or out that would push the population away from equilibrium

29. Genetic Drift Random change in allele frequencies brought about by chance Effect is most pronounced in small populations Increases the chance that an allele will become more or less prevalent when the number of individuals in a population is small

30. Bottleneck A severe reduction in population size Causes pronounced drift Example –Elephant seal population hunted down to just 20 individuals –Population rebounded to 30,000 –Electrophoresis revealed there is now no allele variation at 24 genes

31. Founder Effect Effect of drift when a small number of individuals starts a new population By chance, allele frequencies of founders may not be same as those in original population Effect is pronounced on isolated islands