OHHS AP Bio Chapter 22 Presentation

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  • Figure 22.1 How can this beetle survive in the desert, and what is it doing?
  • Figure 22.2 The historical context of Darwin’s life and ideas
  • Figure 22.3 Formation of sedimentary strata with fossils
  • Figure 22.4 Acquired traits cannot be inherited
  • Figure 22.5 The voyage of HMS Beagle For the Discovery Video Charles Darwin, go to Animation and Video Files.
  • Figure 22.5 The voyage of HMS Beagle
  • Figure 22.5 The voyage of HMS Beagle
  • Figure 22.6 Beak variation in Gal á pagos finches
  • Figure 22.6 Beak variation in Gal á pagos finches
  • Figure 22.6 Beak variation in Gal á pagos finches
  • Figure 22.6 Beak variation in Gal á pagos finches
  • Figure 22.7 “I think . . .”
  • Figure 22.8 Descent with modification
  • Figure 22.8 Descent with modification
  • Figure 22.9 Artificial selection
  • Figure 22.10 Variation in a population
  • Figure 22.11 Overproduction of offspring
  • Figure 22.12 Camouflage as an example of evolutionary adaptation
  • Figure 22.12 Camouflage as an example of evolutionary adaptation
  • Figure 22.12 Camouflage as an example of evolutionary adaptation
  • Figure 22.13 Can predation result in natural selection for color patterns in guppies?
  • Figure 22.13 Can predation result in natural selection for color patterns in guppies?
  • Figure 22.13 Can predation result in natural selection for color patterns in guppies?
  • Figure 22.14 Evolution of drug resistance in HIV
  • Figure 22.15 Fossil evidence of evolution in a group of trilobites
  • Figure 22.15 Fossil evidence of evolution in a group of trilobites
  • Figure 22.15 Fossil evidence of evolution in a group of trilobites
  • Figure 22.16 The transition to life in the sea
  • Figure 22.16 The transition to life in the sea
  • Figure 22.16 The transition to life in the sea
  • Figure 22.17 Mammalian forelimbs: homologous structures
  • Figure 22.18 Anatomical similarities in vertebrate embryos
  • Figure 22.18 Anatomical similarities in vertebrate embryos
  • Figure 22.18 Anatomical similarities in vertebrate embryos
  • Figure 22.19 Tree thinking: information provided in an evolutionary tree
  • Figure 22.20 Convergent evolution
  • OHHS AP Bio Chapter 22 Presentation

    1. 1. Chapter 22 Descent with Modification: A Darwinian View of Life
    2. 2. Overview: Endless Forms Most Beautiful <ul><li>A new era of biology began in 1859 when Charles Darwin published The Origin of Species </li></ul><ul><li>The Origin of Species focused biologists’ attention on the great diversity of organisms </li></ul>
    3. 3. <ul><li>Darwin noted that current species are descendants of ancestral species </li></ul><ul><li>Evolution can be defined by Darwin’s phrase descent with modification </li></ul><ul><li>Evolution can be viewed as both a pattern and a process </li></ul>
    4. 4. Fig. 22-1
    5. 5. <ul><li>To understand why Darwin’s ideas were revolutionary, we must examine them in relation to other Western ideas about Earth and its life </li></ul>Concept 22.1: The Darwinian revolution challenged traditional views of a young Earth inhabited by unchanging species
    6. 6. Fig. 22-2 American Revolution French Revolution U.S. Civil War 1900 1850 1800 1750 1795 1809 1798 1830 1831–1836 1837 1859 1837 1844 1858 The Origin of Species is published. Wallace sends his hypothesis to Darwin. Darwin begins his notebooks. Darwin writes essay on descent with modification. Darwin travels around the world on HMS Beagle . Malthus publishes “Essay on the Principle of Population.” Lyell publishes Principles of Geology . Lamarck publishes his hypothesis of evolution. Hutton proposes his theory of gradualism. Linnaeus (classification) Cuvier (fossils, extinction) Malthus (population limits) Lamarck (species can change) Hutton (gradual geologic change) Lyell (modern geology) Darwin (evolution, natural selection) Wallace (evolution, natural selection)
    7. 7. Scala Naturae and Classification of Species <ul><li>The Greek philosopher Aristotle viewed species as fixed and arranged them on a scala naturae </li></ul><ul><li>The Old Testament holds that species were individually designed by God and therefore perfect </li></ul>
    8. 8. <ul><li>Carolus Linnaeus interpreted organismal adaptations as evidence that the Creator had designed each species for a specific purpose </li></ul><ul><li>Linnaeus was the founder of taxonomy, the branch of biology concerned with classifying organisms </li></ul>
    9. 9. Ideas About Change over Time <ul><li>The study of fossils helped to lay the groundwork for Darwin’s ideas </li></ul><ul><li>Fossils are remains or traces of organisms from the past, usually found in sedimentary rock, which appears in layers or strata </li></ul>Video: Grand Canyon
    10. 10. Fig. 22-3 Younger stratum with more recent fossils Layers of deposited sediment Older stratum with older fossils
    11. 11. <ul><li>Paleontology , the study of fossils, was largely developed by French scientist Georges Cuvier </li></ul><ul><li>Cuvier advocated catastrophism , speculating that each boundary between strata represents a catastrophe </li></ul>
    12. 12. <ul><li>Geologists James Hutton and Charles Lyell perceived that changes in Earth’s surface can result from slow continuous actions still operating today </li></ul><ul><li>Lyell’s principle of uniformitarianism states that the mechanisms of change are constant over time </li></ul><ul><li>This view strongly influenced Darwin’s thinking </li></ul>
    13. 13. Lamarck’s Hypothesis of Evolution <ul><li>Lamarck hypothesized that species evolve through use and disuse of body parts and the inheritance of acquired characteristics </li></ul><ul><li>The mechanisms he proposed are unsupported by evidence </li></ul>
    14. 14. Fig. 22-4
    15. 15. <ul><li>As the 19th century dawned, it was generally believed that species had remained unchanged since their creation </li></ul><ul><li>However, a few doubts about the permanence of species were beginning to arise </li></ul>Concept 22.2: Descent with modification by natural selection explains the adaptations of organisms and the unity and diversity of life
    16. 16. Darwin’s Research <ul><li>As a boy and into adulthood, Charles Darwin had a consuming interest in nature </li></ul><ul><li>Darwin first studied medicine (unsuccessfully), and then theology at Cambridge University </li></ul><ul><li>After graduating, he took an unpaid position as naturalist and companion to Captain Robert FitzRoy for a 5-year around the world voyage on the Beagle </li></ul>
    17. 17. The Voyage of the Beagle <ul><li>During his travels on the Beagle, Darwin collected specimens of South American plants and animals </li></ul><ul><li>He observed adaptations of plants and animals that inhabited many diverse environments </li></ul><ul><li>Darwin was influenced by Lyell’s Principles of Geology and thought that the earth was more than 6000 years old </li></ul>
    18. 18. <ul><li>His interest in geographic distribution of species was kindled by a stop at the Galápagos Islands near the equator west of South America </li></ul>
    19. 19. Fig. 22-5 NORTH AMERICA EUROPE AFRICA AUSTRALIA GREAT BRITAIN SOUTH AMERICA ATLANTIC OCEAN PACIFIC OCEAN Cape of Good Hope Tierra del Fuego Cape Horn Tasmania New Zealand Andes Equator The Galápagos Islands Pinta Marchena Genovesa Santiago Daphne Islands Pinzón Fernandina Isabela San Cristobal Santa Fe Santa Cruz Florenza Española
    20. 20. Fig. 22-5a Darwin in 1840
    21. 21. Fig. 22-5b The Galápagos Islands Pinta Marchena Genovesa Santiago Daphne Islands Pinzón Fernandina Isabela San Cristobal Santa Fe Santa Cruz Florenza Española
    22. 22. Video: Galápagos Marine Iguana Video: Galápagos Tortoises Video: Galápagos Sea Lion Video: Galápagos Islands Overview Video: Blue-footed Boobies Courtship Ritual Video: Albatross Courtship Ritual Video: Soaring Hawk
    23. 23. Darwin’s Focus on Adaptation <ul><li>In reassessing his observations, Darwin perceived adaptation to the environment and the origin of new species as closely related processes </li></ul><ul><li>From studies made years after Darwin’s voyage, biologists have concluded that this is indeed what happened to the Galápagos finches </li></ul>
    24. 24. Fig. 22-6 (a) Cactus-eater (c) Seed-eater (b) Insect-eater
    25. 25. Fig. 22-6a (a) Cactus-eater
    26. 26. Fig. 22-6b (b) Insect-eater
    27. 27. Fig. 22-6c (c) Seed-eater
    28. 28. <ul><li>In 1844, Darwin wrote an essay on the origin of species and natural selection but did not introduce his theory publicly, anticipating an uproar </li></ul><ul><li>In June 1858, Darwin received a manuscript from Alfred Russell Wallace, who had developed a theory of natural selection similar to Darwin’s </li></ul><ul><li>Darwin quickly finished The Origin of Species and published it the next year </li></ul>
    29. 29. The Origin of Species <ul><li>Darwin developed two main ideas: </li></ul><ul><ul><li>Descent with modification explains life’s unity and diversity </li></ul></ul><ul><ul><li>Natural selection is a cause of adaptive evolution </li></ul></ul>
    30. 30. Descent with Modification <ul><li>Darwin never used the word evolution in the first edition of The Origin of Species </li></ul><ul><li>The phrase descent with modification summarized Darwin’s perception of the unity of life </li></ul><ul><li>The phrase refers to the view that all organisms are related through descent from an ancestor that lived in the remote past </li></ul>
    31. 31. <ul><li>In the Darwinian view, the history of life is like a tree with branches representing life’s diversity </li></ul><ul><li>Darwin’s theory meshed well with the hierarchy of Linnaeus </li></ul>
    32. 32. Fig. 22-7
    33. 33. Fig. 22-8 Hyracoidea (Hyraxes) Sirenia (Manatees and relatives) Moeritherium Barytherium Deinotherium Mammut Elephas maximus (Asia) Stegodon Mammuthus Loxodonta africana (Africa) Loxodonta cyclotis (Africa) 0 10 4 2 5.5 24 34 Millions of years ago Years ago Platybelodon
    34. 34. Fig. 22-8a Elephas maximus (Asia) Stegodon Mammuthus Loxodonta africana (Africa) Loxodonta cyclotis (Africa) 0 10 4 2 5.5 24 34 Millions of years ago Years ago Platybelodon
    35. 35. Artificial Selection, Natural Selection, and Adaptation <ul><li>Darwin noted that humans have modified other species by selecting and breeding individuals with desired traits, a process called artificial selection </li></ul><ul><li>Darwin then described four observations of nature and from these drew two inferences </li></ul>
    36. 36. Fig. 22-9 Kale Kohlrabi Brussels sprouts Leaves Stem Wild mustard Flowers and stems Broccoli Cauliflower Flower clusters Cabbage Terminal bud Lateral buds
    37. 37. <ul><li>Observation #1: Members of a population often vary greatly in their traits </li></ul>
    38. 38. Fig. 22-10
    39. 39. <ul><li>Observation #2: Traits are inherited from parents to offspring </li></ul><ul><li>Observation #3: All species are capable of producing more offspring than the environment can support </li></ul>
    40. 40. Fig. 22-11 Spore cloud
    41. 41. <ul><li>Observation #4: Owing to lack of food or other resources, many of these offspring do not survive </li></ul>
    42. 42. <ul><li>Inference #1: Individuals whose inherited traits give them a higher probability of surviving and reproducing in a given environment tend to leave more offspring than other individuals </li></ul>
    43. 43. <ul><li>Inference #2: This unequal ability of individuals to survive and reproduce will lead to the accumulation of favorable traits in the population over generations </li></ul>
    44. 44. <ul><li>Darwin was influenced by Thomas Malthus who noted the potential for human population to increase faster than food supplies and other resources </li></ul><ul><li>If some heritable traits are advantageous, these will accumulate in the population, and this will increase the frequency of individuals with adaptations </li></ul><ul><li>This process explains the match between organisms and their environment </li></ul>
    45. 45. Natural Selection: A Summary <ul><li>Individuals with certain heritable characteristics survive and reproduce at a higher rate than other individuals </li></ul><ul><li>Natural selection increases the adaptation of organisms to their environment over time </li></ul><ul><li>If an environment changes over time, natural selection may result in adaptation to these new conditions and may give rise to new species </li></ul>Video: Seahorse Camouflage
    46. 46. Fig. 22-12 (b) A stick mantid in Africa (a) A flower mantid in Malaysia
    47. 47. Fig. 22-12a (a) A flower mantid in Malaysia
    48. 48. Fig. 22-12b (b) A stick mantid in Africa
    49. 49. <ul><li>Note that individuals do not evolve; populations evolve over time </li></ul><ul><li>Natural selection can only increase or decrease heritable traits in a population </li></ul><ul><li>Adaptations vary with different environments </li></ul>
    50. 50. Concept 22.3: Evolution is supported by an overwhelming amount of scientific evidence <ul><li>New discoveries continue to fill the gaps identified by Darwin in The Origin of Species </li></ul>
    51. 51. Direct Observations of Evolutionary Change <ul><li>Two examples provide evidence for natural selection: the effect of differential predation on guppy populations and the evolution of drug-resistant HIV </li></ul>
    52. 52. Predation and Coloration in Guppies : Scientific Inquiry <ul><li>John Endler has studied the effects of predators on wild guppy populations </li></ul><ul><li>Brightly colored males are more attractive to females </li></ul><ul><li>However, brightly colored males are more vulnerable to predation </li></ul><ul><li>Guppy populations in pools with fewer predators had more brightly colored males </li></ul>
    53. 53. Fig. 22-13 Predator: Killifish; preys mainly on juvenile guppies (which do not express the color genes) Guppies: Adult males have brighter colors than those in “pike-cichlid pools” Experimental transplant of guppies Pools with killifish, but no guppies prior to transplant Predator: Pike-cichlid; preys mainly on adult guppies Guppies: Adult males are more drab in color than those in “killifish pools” Source population Transplanted population Source population Transplanted population Number of colored spots Area of colored spots (mm 2 ) 12 12 10 10 8 8 6 6 4 4 2 2 0 0 RESULTS EXPERIMENT
    54. 54. Fig. 22-13a Predator: Killifish; preys mainly on juvenile guppies (which do not express the color genes) Guppies: Adult males have brighter colors than those in “pike-cichlid pools” Experimental transplant of guppies Pools with killifish, but no guppies prior to transplant Predator: Pike-cichlid; preys mainly on adult guppies Guppies: Adult males are more drab in color than those in “killifish pools” EXPERIMENT
    55. 55. Fig. 22-13b Source population Transplanted population Source population Transplanted population Number of colored spots Area of colored spots (mm 2 ) 12 12 10 10 8 8 6 6 4 4 2 2 0 0 RESULTS
    56. 56. <ul><li>Endler transferred brightly colored guppies (with few predators) to a pool with many predators </li></ul><ul><li>As predicted, over time the population became less brightly colored </li></ul><ul><li>Endler also transferred drab colored guppies (with many predators) to a pool with few predators </li></ul><ul><li>As predicted, over time the population became more brightly colored </li></ul>
    57. 57. The Evolution of Drug-Resistant HIV <ul><li>The use of drugs to combat HIV selects for viruses resistant to these drugs </li></ul><ul><li>HIV uses the enzyme reverse transcriptase to make a DNA version of its own RNA genome </li></ul><ul><li>The drug 3TC is designed to interfere and cause errors in the manufacture of DNA from the virus </li></ul>
    58. 58. <ul><li>Some individual HIV viruses have a variation that allows them to produce DNA without errors </li></ul><ul><li>These viruses have a greater reproductive success and increase in number relative to the susceptible viruses </li></ul><ul><li>The population of HIV viruses has therefore developed resistance to 3TC </li></ul><ul><li>The ability of bacteria and viruses to evolve rapidly poses a challenge to our society </li></ul>
    59. 59. Fig. 22-14 Weeks Patient No. 3 Patient No. 2 Patient No. 1 Percent of HIV resistant to 3TC 0 0 25 50 75 100 2 4 6 8 10 12
    60. 60. <ul><li>Natural selection does not create new traits, but edits or selects for traits already present in the population </li></ul><ul><li>The local environment determines which traits will be selected for or selected against in any specific population </li></ul>
    61. 61. The Fossil Record <ul><li>The fossil record provides evidence of the extinction of species, the origin of new groups, and changes within groups over time </li></ul>
    62. 62. Fig. 22-15 Bristolia insolens Bristolia bristolensis Bristolia harringtoni Bristolia mohavensis Latham Shale dig site, San Bernardino County, California Depth (meters) 0 2 4 6 8 10 12 14 16 18 1 2 3 3 3 1 2 4 4
    63. 63. Fig. 22-15b Bristolia harringtoni Bristolia mohavensis Latham Shale dig site, San Bernardino County, California 12 14 16 18 2 Depth (meters) 1 1 2
    64. 64. Fig. 22-15c Bristolia insolens 10 8 0 Depth (meters) 4 Bristolia bristolensis 2 4 6 3 4 3
    65. 65. <ul><li>The Darwinian view of life predicts that evolutionary transitions should leave signs in the fossil record </li></ul><ul><li>Paleontologists have discovered fossils of many such transitional forms </li></ul>
    66. 66. Fig. 22-16 (a) Pakicetus (terrestrial) (b) Rhodocetus (predominantly aquatic) (c) Dorudon (fully aquatic) Pelvis and hind limb Pelvis and hind limb (d) Balaena (recent whale ancestor)
    67. 67. Fig. 22-16ab (a) Pakicetus (terrestrial) (b) Rhodocetus (predominantly aquatic)
    68. 68. Fig. 22-16cd (c) Dorudon (fully aquatic) Pelvis and hind limb Pelvis and hind limb (d) Balaena (recent whale ancestor)
    69. 69. Homology <ul><li>Homology is similarity resulting from common ancestry </li></ul>
    70. 70. Anatomical and Molecular Homologies <ul><li>Homologous structures are anatomical resemblances that represent variations on a structural theme present in a common ancestor </li></ul>
    71. 71. Fig. 22-17 Humerus Radius Ulna Carpals Metacarpals Phalanges Human Whale Cat Bat
    72. 72. <ul><li>Comparative embryology reveals anatomical homologies not visible in adult organisms </li></ul>
    73. 73. Fig. 22-18 Human embryo Chick embryo (LM) Pharyngeal pouches Post-anal tail
    74. 74. Fig. 22-18a Chick embryo (LM) Pharyngeal pouches Post-anal tail
    75. 75. Fig. 22-18b Human embryo Pharyngeal pouches Post-anal tail
    76. 76. <ul><li>Vestigial structures are remnants of features that served important functions in the organism’s ancestors </li></ul><ul><li>Examples of homologies at the molecular level are genes shared among organisms inherited from a common ancestor </li></ul>
    77. 77. Homologies and “Tree Thinking” <ul><li>The Darwinian concept of an evolutionary tree of life can explain homologies </li></ul><ul><li>Evolutionary trees are hypotheses about the relationships among different groups </li></ul><ul><li>Evolutionary trees can be made using different types of data, for example, anatomical and DNA sequence data </li></ul>
    78. 78. Fig. 22-19 Hawks and other birds Ostriches Crocodiles Lizards and snakes Amphibians Mammals Lungfishes Tetrapod limbs Amnion Feathers Homologous characteristic Branch point (common ancestor) Tetrapods Amniotes Birds 6 5 4 3 2 1
    79. 79. Convergent Evolution <ul><li>Convergent evolution is the evolution of similar, or analogous , features in distantly related groups </li></ul><ul><li>Analogous traits arise when groups independently adapt to similar environments in similar ways </li></ul><ul><li>Convergent evolution does not provide information about ancestry </li></ul>
    80. 80. Fig. 22-20 Sugar glider Flying squirrel AUSTRALIA NORTH AMERICA
    81. 81. Biogeography <ul><li>Darwin’s observations of biogeography , the geographic distribution of species, formed an important part of his theory of evolution </li></ul><ul><li>Islands have many endemic species that are often closely related to species on the nearest mainland or island </li></ul>
    82. 82. <ul><li>Earth’s continents were formerly united in a single large continent called Pangaea , but have since separated by continental drift </li></ul><ul><li>An understanding of continent movement and modern distribution of species allows us to predict when and where different groups evolved </li></ul>
    83. 83. What Is Theoretical About Darwin’s View of Life? <ul><li>In science, a theory accounts for many observations and data and attempts to explain and integrate a great variety of phenomena </li></ul><ul><li>Darwin’s theory of evolution by natural selection integrates diverse areas of biological study and stimulates many new research questions </li></ul><ul><li>Ongoing research adds to our understanding of evolution </li></ul>
    84. 84. Fig. 22-UN1 Observations Over time, favorable traits accumulate in the population. Inferences and Individuals in a population vary in their heritable characteristics. Organisms produce more offspring than the environment can support. Individuals that are well suited to their environment tend to leave more offspring than other individuals
    85. 85. Fig. 22-UN2
    86. 86. Fig. 22-UN3
    87. 87. You should now be able to: <ul><li>Describe the contributions to evolutionary theory made by Linnaeus, Cuvier, Lyell, Lamarck, Malthus, and Wallace </li></ul><ul><li>Describe Lamarck’s theories, and explain why they have been rejected </li></ul><ul><li>Explain what Darwin meant by “descent with modification” </li></ul><ul><li>List and explain Darwin’s four observations and two inferences </li></ul>
    88. 88. <ul><li>Explain why an individual organism cannot evolve </li></ul><ul><li>Describe at least four lines of evidence for evolution by natural selection </li></ul>

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