Darwin’s Theory of Evolution and Origins of Life

1. Darwin’s Theory of Evolution and Origins of Life

2. Charles Darwin • Charles Darwin(1809-1882) - the father of evolution - believed environment determined traits Darwin traveled around the world for 5 years on the HMS Beagle collecting data on many unique organisms.

3. Darwin’s Journey

4. Giant Tortoises of the Galápagos Islands Pinta Tower Marchena Pinta IslandIntermediate shell James Fernandina Santa Cruz Isabela Santa Fe Hood Island Saddle-backed shell Floreana Hood Isabela Island Dome-shaped shell

5. Evidence for Evolution Fossil Record • Shows species that once existed. • Comparing fossils and rock layers one can find relationships showing change.

6. Evidence: Fossils

7. Evidence: Embryology Embryology- comparing early growth stages of organisms. Fish chicken rabbit human

8. Embryology

9. Evidence Homologous structures • Structures in different species that share similar design/function. • Shows species have common ancestors.

10. Homologous Body Structures Turtle Alligator Bird Mammal Ancient lobe-finned fish

11. Homologous Structures

12. Evidence: Analogous Structures • Different continents have different species. • Species may evolve similar traits if environments are the similar.

13. Analogous Structures Beaver Beaver Muskrat Beaver andMuskrat Coypu Capybara Coypu andCapybara NORTH AMERICA Muskrat Are these the same two animals? SOUTH AMERICA Capybara Coypu

14. Evidence: Vestigial structure structure with no function in present-day organisms, but was useful to an ancestor. • Natural selection does not get rid of the organ.

15. Biochemical Evidence - Comparing DNA of organisms - shows how closely organisms are related - can link organisms to common ancestors

16. CladogramShows evolutionary relationships

17. A Summary of Darwin’s Theory 1. Differences are inherited. 2. Organisms produce more offspring than can survive. 3. Increase in organisms causes competition. 4. Best adapted organisms survive & reproduce. 5. Today’s species are descended with modifications from their ancestors.

18. How did life begin? Miller & Urey’s Experiment - produced amino acids by passing hydrogen, methane, ammonia, and water through electric sparks. - demonstrates how simple compounds could form organic compounds.

19. Miller & Urey’s Experiment

20. Progression of Life 1. Anaerobic prokaryotes (no oxygen) 2. Photosynthetic bacteria (produce oxygen) 3. Aerobic prokaryotes 4. Prokaryotes join together to form eukaryotes* (*endosymbiotic theory*) 5. Protists, plants, fungi, & animals - occurred due to sexual reproduction

21. Endosymbiotic Theory - Idea that eukaryotes formed from groups of prokaryotes

22. Genetics and Evolution • Gene pool = all the alleles in a population. Ex- Pea plants: - Height alleles: T = tall t = short • Relative frequency= % of each allele Ex- Pea plants: - Height alleles: T = 70% t = 30% • Evolution= change in relative frequency.

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24. Section 16-1 Relative Frequencies of Alleles Sample Population Frequency of Alleles allele for brown fur allele for black fur 48% heterozygous black 16% homozygous black 36% homozygous brown

25. Sources of Evolution 1. Mutations 2. Genetic variation due to sexual reproduction 3. Environmental changes

26. Phenotypes for Single-Gene Trait 100 80 60 40 20 0 Frequency of Phenotype (%) Blue Spiny Puffs Green Spiny Puffs Phenotype

27. Single trait mutation Observe this population of delicious spiny puffs in pond water. Imagine there’s a predator that loves to eat delicious blue spiny puffs instead of green spiny puffs. What would happen to the color of spiny puffs over time?

28. Year # 1

29. Year # 2

30. Year #3

31. Phenotypes for Single-Gene Trait 100 80 60 40 20 0 Frequency of Phenotype (%) Blue Spiny Puffs Blue Spiny Puffs Green Spiny Puffs Green Spiny Puffs Phenotype

32. Bell Curve for Polygenic Trait Phenotypes Frequency (%) of Phenotype Phenotype (height) 5 ft 5 ft 8 in 6 ft 6 in

33. Natural Selection of Polygenic traits • Changes create 3 types of selection 1. Directional selection 2. Stabilizing selection 3. Disruptive selection

34. Directional Selection One trait is favored. Shifts the population’s average toward that trait. Key Low mortality, high fitness High mortality, low fitness Food becomes scarce.

35. Stabilizing Selection Average traits are favored. Stabilizing Selection Selection against both extremes keep curve narrow and in same place. Key Low mortality, high fitness High mortality, low fitness Percentage of Population Birth Weight

36. Disruptive Selection Only organisms with extreme traits survive. Creates two different extreme phenotypes. Largest and smallest seeds become more common. Key Beak Size Beak Size Low mortality, high fitness Population splits into two subgroups specializing in different seeds. Number of Birdsin Population Number of Birdsin Population High mortality, low fitness

37. Genetic Drift (Founder’s Effect) Sample of Original Population

38. Genetic Drift (Founder’s Effect) Sample of Original Population Founding Population A Founding Population B

39. Genetic Drift(Founder’s Effect) Sample of Original Population Descendants Founding Population A Founding Population B

40. Speciation • Evolution of new species - Large allele changes can create new species - Isolation can cause allele changes: Types 1. Behavioral Isolation 2. Geographic Isolation

41. Behavioral Isolation • A change of behavior within a population that creates 2 new gene pools. • Example : Birds with different mating songs.

42. Geographic Isolation If a geographic barrier splits a population, then two new genetic pools may form.

43. A

44. B

45. C

46. D

47. E

48. F