1. Modern Biology II

2. Who Are You? Your major Your year, part time or full time Your plans Your objectives Your interests

3. Evolution Evolution as fact and theory Evolution is change; “descent with modification” Small scale - changes in gene frequency from one population to the next Large scale - descent of different species from a common ancestor What are we trying to explain? –Adaptation: the good fit”of organisms to their environment

4. Evolution Please read Chapter 20 (Genes Within Populations) if you have not done so already Know who Charles Darwin is…(naturalist on the HMS Beagle in 1831; The Origin of the Species; Galapagos Islands, etc)

5. Descriptions of the history of life on Earth 1.Separate Creation: no mechanism involved; independent creation (‘nothing to explain’) 2.Transformism: Lamarck; inheritance of acquired characteristics (e.g., giraffe’s neck); internal forces/unknown mechanisms cause organisms to produce offspring slightly different from themselves 3.Evolution: Darwinian Natural Selection; Survival of the Fittest

6. Descriptions of the history of life on Earth Name Descent with modification? Common ancestor? Extinction? Creation (A) NoNoNo Transformism (B) Yes NoNo Evolution (C) Yes YesYes change extinction time

7. And let’s not forget about Intelligent Design… Created by a subset of Creationists; offers an alternative to Creationism Avoids specifying the identity of a ‘designer’ “Certain features of living things (and the universe) are best explained by an intelligent cause, not an undirected process” Very Controversial!

8. …or the Church of the Flying Spaghetti Monster (FSM) Satirical protest to the Kansas Board of Education’s decision to require the teaching of Intelligent Design in public schools Founded in 2005 The FSM is invisible and undetectable; evidence of evolution is planted by FSM to test the Pastafarian’s faith

9. Global Warming & Pirates

10. Evolution Evolution is descent with modification; living species are descendents of ancestral species that were different from present-day ones Evolution describes the genetic changes in a population over time

11. Evolution Organisms are not perfectly fit – a good fit, but not perfect As descendents of a remote ancestor spread into various habitats over millions and millions of years, they accumulated diverse modifications (adaptations) that fit them to specific ways of life; descent with modification (evolution!)

12. Evolution Natural variation among individuals is based on heredity (and mutation). These variations enable organisms to become adapted to their environment over time

13. Natural Selection Natural selection is the process by which favorable, inherited traits become more numerous in successive generations of a population of reproducing organisms

14. Natural Selection Over time, natural selection leads to species that are well adapted (highly evolved) to their environments

15. The Principles of Natural Selection King Penguin Rookery © Momatiuk - Eastcott/Corbis Struggle for existence/Competition –More offspring are produced than can be supported by resources

16. The Principles of Natural Selection Variation –Some individuals, due to heredity or mutation, possess characteristics which make them better adapted to their environment

17. The Principles of Natural Selection Inheritance of Traits –Best-suited organisms will survive to produce more individuals that share same adaptation

18. Survival of the Fittest Organisms are adapted to their environment through natural selection Natural selection is a pessimistic process

19. Population with varied inherited traits 1 Elimination of individuals with certain traits 2 Reproduction of survivors 3 Certain individuals with a distinct, inherited characteristic will be selected against, while others with a (different) distinct, inherited trait will survive

20. Evidence for Evolution Microevolution – can be observed in nature; small changes in organism, generations changing over time Artificial selection – evolution can be experimentally produced

21. Microevolution A well-known example of microevolution involves the peppered Moth, Biston betularia in England during the industrial revolution Prior to the industrial revolution, light variants of the peppered moth survived better than dark variants because they blended well with the light colored trees –caused by the presence of a light-colored lichen on the dark- colored bark

22. Microevolution Pre-industrial era – only light variant known During the industrial revolution, poor air quality killed the lichens which covered the (otherwise dark) trees and camouflaged the light moths against predation In 1848, the first dark variant collected By mid-1900’s, the dark variant made up 90% of population in industrial areas!

23. Microevolution

24. Artificial Selection Darwin got idea of natural selection by artificial selection! Modern corn looks very different from its ancestor Tumbler pigeons!!! www.flickr.com/photos/ terryandchristine/ 2399227035/ www.flickr.com/photos/rinalia/ 3285371111/

25. Artificial Selection All dogs are domesticated breeds of the Gray wolf, Canis lupus; “Fido” is actually a subspecies of the wolf!

26. Artificial Selection

27. Evidence for Evolution “ Ring species” –series of neighboring populations that can interbreed with closely-related populations, but two “dead ends” exist in the series that are too distantly-related to interbreed

28. Ring Species Larus gulls – forms a ‘ring’ around the North Pole; European gull can breed with American, which can breed with Vega and so on…but the European gull cannot breed with the Lesser blacked-back gull at ‘end’ of the ring

29. Evidence for Natural Selection Darwin’s fishes of the Galapagos 14 species of finch; 1 common ancestor (from the mainland); different beaks

30. Evidence for Evolution Homologous similarities: similarities between 2 species that is NOT functionally necessary Provide clues to common ancestry Constraint is not there, may look the same, but doesn’t have to Example: Tetrapods; do not need 5 digits to make flying wings, swimming structure, etc. Common pentadactyl ancestor; limb adapted into various ‘means’

31. Humerus Radius Ulna Carpals Metacarpals Phalanges HumanCatWhaleBat Evidence for Evolution Homologous structures – similar characteristics that result from a common ancestry

32. The Panda’s Thumb The panda’s thumb is a homologous trait; modification of the wrist bone, not anatomically a finger (or thumb) at all Constructed from the radial sesamoid, normally a small component of the wrist May have originated from a single genetic change (mutation)

33. The Panda’s Thumb

34. Homologies Fossil evidence of evolution: Whale ‘missing link” Vestigial structures – no apparent function, but resemble structures ancestors possessed

35. Homologies Vestigial structures of a whale http://www.edwardtbabinski.us/mpm/mpm_whale_limb.html

36. Evidence for Evolution

37. Evolutionary View of Homology Use the starting materials and processes already available Fashion adaptations, rather than starting from scratch Evolution is a tinkerer, not a master engineer

38. Evolutionary View of Homology Adaptations are NOT perfect – it is the imperfection of adaptation that, instead, gives evidence for evolution (a tinkerer uses tools already there to improve) Different homologies are correlated – similar patterns between human, ape, and monkey for many proteins Similarities stem from common ancestor

39. Anatomical Evidence of Evolution Orchid petals - used as pollinator lure Snake with 2 leg bones Manatee fingernails Humans – muscles for wiggling ears

40. Anatomical Evidence of Evolution Developmental similarities reflect descent from a common ancestor “Ontogeny recapitulates phylogeny”! (Ontogeny = growth and development of an organism; Phylogeny = evolutionary history of a species)

41. Evidence for Evolution In contrast to homologous structures, analogous structures also provide evidence for evolution Analogous structures are structures that share similarities by a way of life, not by a common ancestry Analogous structures arise among unrelated organisms in response to similar needs or similar environmental factors

42. Analogous structures Examples: wings of insects (a) and birds (b); flippers of seals (c) and penguins (d)

43. Origin of New Species Individuals do NOT evolve Populations are the smallest units that can evolve A population is a group of interbreeding individuals belonging to a particular species sharing a common geographic area

44. Origin of New Species What is a species? Biological species concept: a population or group whose members have the potential to interbreed with one another in nature to produce viable, fertile offspring, but who cannot interbreed with other such groups Species are based on ability to interbreed – NOT on physical similarities

45. Origin of New Species Example: Eastern and Western Meadowlarks – 2 different species with similar shape and coloration, but differences in song help prevent interbreeding Barriers to breeding can be behavioral Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

46. Origin of New Species In contrast, humans have considerable diversity, but we all belong to the same species because of our ability to interbreed Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

47. Speciation happens It takes a reproductive barrier to keep individuals of closely-related species from interbreeding Reproductive barriers may be behavioral, geographical, anatomical, or temporal

48. Allopatric Speciation How do reproductive barriers arise? One of the clearest forms of species is allopatric speciation caused by a geographic barrier When a geographic barrier occurs, the isolated populations each become adapted to their own environment, such that over time, they may no longer interbreed ( speciation)

49. Speciation Reasons for geographic (allopatric) isolation Example of allopatric isolation: antelope squirrels on south and north rim of Grand Canyon

50. Speciation

51. Prezygotic vs. Postzygotic Prezygotic – mechanisms preventing formation of a zygote (ecological, behavioral, temporal, mechanical) Postzygotic – mechanisms preventing organisms from developing into a reproducing adult

52. Prezygotic examples Ecological – Lions and Tigers Behavioral – blue- footed boobies Temporal – Wild lettuce (different blooming periods) Mechanical - insects

53. Postzygotic example Hybrid inviability or infertility – mule Mules are the reproductive result of a horse and a donkey breeding Mules are sterile Therefore, a horse and a donkey must represent 2 distinct species

54. Sympatric Speciation Sympatric speciation – the process by which new species arise within the range of another species More controversial In this case, a new species does not arise from geographic isolation Instead, a new species may arise by accident when errors during cell division resulted in organisms with extra sets of chromosomes (very common in plants)

55. Sympatric Speciation New species formed by having extra sets of chromosomes are considered to be polyploid Polyploid organisms have more than 2 complete sets of chromosomes For example, a polyploid containing 4 sets of chromosomes will produce diploid (2n) gametes! This species would be unable to mate with normal diploid species (which produce haploid gametes)

56. Parent species Diploid Polyploid (“tetraploid”) 1 Diploid gametes 2 Viable, fertile tetraploid species Self- fertilization 3 Error in cell division Polyploid cells undergo meiosis Polyploidy by error in cell division and self- fertilization

57. Species A 2n = 4 Gamete n = 2 1 2 Species B 2n = 6 Gamete n = 3 Sterile hybrid n = 5 Chromosomes not homologous (cannot pair) Viable, fertile hybrid species 2n = 10 3 3. However, ‘sterile’ hybrid can reproduce asexually (as many plants do), and if subsequent errors in cell division occur, chromosome duplications can result in a fertile polyploid species! Polyploidy by errors in cell division of a ‘sterile’ hybrid

58. Polyploid speciation Remember, polyploidy is a type of sympatric speciation As many as 80% of all living plants today are believed to have arisen by polyploidy! A polyploid contains twice (or sometimes more) the genetic diversity as its diploid predecessors, which provides an adaptive advantage!

59. Polyploid speciation Many of the plants grown for food are polyploids –Oats and Barley –Potatoes –Bananas –Peanuts –Plums and Apples –Wheat –Coffee!

60. Speciation

61. Macroevolution Origin of taxonomic groups higher than the species level Evolutionary change substantial enough to view its products as new genera, families or phyla Has a random component Considers major evolutionary innovations – bird feathers, insect wings Extinctions and Radiations

62. Macroevolution

63. Adaptive Radiation The evolution of many diverse species from a common ancestor is called adaptive radiation The adaptations of these species allow them to fill new habitats or roles in their communities (“niches”) New phenotypes arise in response to the environment, driven by natural selection

64. Adaptive Radiation Example: Development of a fourth cusp in mammalian tooth – increases range of food which can be utilized Adaptive radiation typically occurs when a few organisms colonize new, unexploited habitats, or when environmental changes open up new opportunities for the survivors

65. Adaptive Evolution The Galapagos Islands is one of the world’s greatest showcases of adaptive radiation Each island arose ‘naked’ from underwater volcanoes and were gradually clothed by plants, animals and micro-organisms which strayed from the South American mainland

66. Darwin’s finches are a prime example of adaptive evolution

67. Rise of the mammals The extinction of the dinosaurs provided a tremendous evolutionary opportunity to mammals, who once lived in their shadows

68. Macroevolution Mass extinctions

69. Macroevolution Fossil record provides clues for the outline of macroevolution Extant (living) species also supply clues What about soft-bodied organisms which do not leave a fossil record? Does evolution occur in ‘fits’ and ‘starts’ or is our understanding of historical accounts skewed?

70. Suggested Readings The Selfish Gene, Richard Dawkins The Blind Watchmaker, Richard Dawkins Unweaving the Rainbow, Richard Dawkins The Panda’s Thumb (and any other collection of stories by), Stephen J. Gould …some light reading for a spring night.