1. Evolution Chapters 22-25

2. Evolution Changes in populations, species, or groups of species. Variances of the frequency of heritable traits that appear from one generation to the next.

3. 2 Areas of Evolutionary Study Microevolution Details of how populations of organisms change. Generation to Generation New species origninate Macroevolution Patters of change in groups of related species. Broad period of geologic time Patterns determine phylogeny. The evolutionary relationships among species and groups of species

4. Agree or Disagree For each of the following statements decide if you agree that this is how evolution occurs or disagree. After you have agreed or disagreed choose 2 agree statements and site examples and 2 disagree statements and site examples.

5. Lamarck 3 ideas for evolution: Use and Disuse Inheritance of acquired characteristics Natural Transformation of species

6. Use and Disuse How body parts of organisms can develop with increased usage, while unused parts weaken.

7. Inheritance of Acquired Characteristics Described how body features acquired during the lifetime of an organism could be passed on to offspring.

8. Natural Transformation of Species Organisms produced offspring with changes, transforming each subsequent generation into a slightly different form toward some ultimate higher order of complexity. Species did not become extinct nor did they split and change into two or more species.

9. Evidence for Evolution Paleontology Biogeography Embryology Comparative Anatomy Molecular Biology

10. overproduction competition variation adaptation Natural Selection speciation More organisms are born than needed to maintain the population

11. competition variation adaptation Natural Selection speciation Organisms compete for limited natural resources such as food, water, shelter and space.

12. variation adaptation Natural Selection speciation Organisms within a population vary. Variation is heritable.

13. adaptation Natural Selection speciation Any inherited trait that increases the chances of survival. Fitness is determined by the environment.

14. Natural Selection speciation Individuals with favorable variations (adaptations) are more likely to survive and pass on these traits to their offspring “Survival of the Fittest”

15. Evolution and Speciation Favorable variations (adaptations) gradually accumulate and unfavorable variations disappear over many generations Eventually this leads to a new species

17. 4 Different types of Selection Stabilizing Selection Disruptive Selection Directional Selection Sexual Selection Artificial Selection

18. Sources of Variation Mutations Sexual Reproduction Diploidy Outbreeding Balanced Polymorphism

19. Mutations Raw material for new variation. Invents new genes that were never in the gene pool before.

20. Sexual Reproduction Creates individuals with new allele frequencies. Genetic Recombination- 3 events Crossing Over Independent Assortment of Homologues Random Joining of Gametes

21. Diploidy The presence of 2 copies of each chromosome in a cell. Recessive alleles are hidden in the gene pool.

22. Outbreeding Mating of unrelated partners. Increases the possibility of mixing different alleles and creating new combinations.

23. Balanced Polymorphism Maintenance of different phenotypes in a population. Heterozygote Advantage The heterozygote condition bears a greater selective advantage. (Sickle Cell in Africa) Hybrid Vigor/ heterosis Superior quality of offspring resulting from crosses between 2 different inbred strains of plants. Frequency-dependent selection Least common phenotypes have a selective advantage. Predator mimicking prey.

24. Causes of Changes in Allele Frequencies Natural Selection Mutations Gene Flow Genetic Drift Nonrandom Mating

25. Gene Flow The introduction or removal of alleles from the population Immigration Emigration

26. Genetic Drift A random increase or decrease of alleles. 2 Types Founder Effect Alleles in a group of migrating individuals are not the same as that of the origin population. Bottleneck Population undergoes a dramatic decrease in size due to a natural catastrophe.

27. Nonrandom Mating Individuals choose mates based upon their particular traits. Inbreeding Sexual Selection

28. How do we know evolution is occuring? Hardy-Weinberg 5 Conditions for Hardy-Weinberg Equilibrium (evolution is not happening) All traits are selectively neutral Mutations do no occur No gene flow No genetic drift Random mating

29. Genetic Equilibrium Determination Allele frequencies for each allele p is for the dominant allele q is for the recessive allele Frequency of homozygotes p 2 is for the homozygous dominant q 2 is for the homozygous recessive Frequency of heterozygotes pq + qp = 2pq

30. Equations p + q= 1 p 2 + 2pq + q 2 = 1

31. Example Problem Suppose a plant population consists of 84% plants with red flowers and 16% with white flowers. Assume the red allele (R) is dominant to the white allele (r).

32. Do Hardy-Weinberg conditions meet any population? NO! Why bother learning it? Starting point Further investigation as to which condition is being violated Mechanisms of evolution

33. Speciation Species Speciation The formation of a new species by one of 4 processes Allopatric Sympatric Sympatric by Polyploidy Adaptive Ratiation

34. Allopatric Speciation Population is divided by a geographic barrier. Barrier creates isolation of breeding. Species continue to evolve by natural selection (if environments are different), mutation, genetic drift.

35. Sympatric Speciation The formation of a species without the presence of a geographic barrier. Balanced Polymorphism Camouflage and Mimicry Hybridization

36. Sympatric Speciation by Polyploidy The posession of more than the normal two sets of chromosomes (2n). Polyploidy occurs as a result of non- disjunction of all chromosomes during meiosis. A tetraploid can occur when two diploid gametes come together. Reproductive Isolation thus speciation

37. Adaptive Radiation Rapid evolution from a single species Adapts to geographic or ecological conditions. Darwin’s Finches

38. Maintaining Reproductive Isolation Necessary for speciation Prezygotic Isolating Mechanisms Postzygotic Isolating Mechanisms

39. Prezygotic Isolating Mechanisms Habitat Isolation Temporal Isolation Behavioral Isolation Mechanical Isolation Gametic Isolation

40. Postzygotic Isolating Mechanisms Hybrid Inviability Hybrid Sterility Hybrid Breakdown

41. Patterns of Microevlution Divergent Evolution Convergent Evolution Parallel Evolution Coevolution Jigsaw Groups of 4, 1-2 sentence summary. Picture or graph of evolution

42. Patterns of Macroevolution Phyletic Gradualism Punctuated Equilibrium

43. Phyletic Gradualism Gradual Accumulation of small changes. Fossil evidence provides snapshots of the evolutionary process.

44. Punctuated Equilibrium Long periods of no evolution “stasis” followed by quick bursts of evolution.

45. The Earth and its atmosphere formed. Consisted of CO, Carbon dioxide, hydrogen gas, nitrogen gas, water, sulfur, and hydrochloric acid. Little or no oxygen gas.

46. The primordial seas formed The earth cooled, gases condensed to produce seas consisting of water and minerals.

47. Complex molecules were synthesized. Miller-Urey Experiment Oranic molecules were formed from inorganic molecules with help from energy.

48. Polymers and self-replicating molecules were synthesized. Monomers combined to form polymers. Proteinoids Abiotically produced polypeptides

49. Organic molecules were concentrated and isolated into protobionts. Protobionts Cell precursors. Able to carry out chemical processes Not able to reproduce. Microspheres and coacervates

50. Primitive heterotrophic prokaryotes formed. Heterotrophs formed to take in materials. Natural selection

51. Primitive autotrophic prokaryotes were formed. Mutation for an autotroph to be formed. Produces oxygen as a product of chemical processes.

52. Oxygen and the ozone layer formed and abiotic chemical evolution ended. Oxygen released in the atmosphere. Ozone layer made. UV light was filtered. Major source of energy was eliminated.

53. Eukaryotes formed Endosymbiotic Theory