1. Evolution of Life Chapter 13

2. Origin of Life Age of Planet Earth - 4.6 billion years Oldest fossils - 3.5 billion years Possible Formation of the First Cells –Inorganic molecules reacted to form organic molecules –Organic molecules polymerized to become macromolecules –Plasma membrane formed –Protocells formed

3. Evidence of Evolution

4. Evolution –All the changes that have occurred in living things since the beginning of life Due to differential reproductive success 4 main areas of evidence that lead us to believe in “some” evolution:

5. Evidence of Evolution Fossil Evidence Biogeographical evidence Anatomical evidence Biochemical evidence

6. 1. Fossil Evidence Fossils –The remains and traces of past life or any other direct evidence of past life Deposited in layers called strata –Each stratum is older than the one above and younger than the one below Transitional fossils –Especially significant –Represent evolutionary links

8. Fossil Evidence - Geological Timescale Based on dating of fossil evidence –Relative Dating Method Determines the relative order of fossils and strata but not the actual date –Absolute Method- Radioactive dating techniques Assign an actual date to a fossil Technique based on the half-life of radioactive isotopes

9. Absolute Method

10. Fossil Evidence - Mass Extinctions Large numbers of species become extinct in a short period of time –Remaining species may spread out and fill habitats left vacant Five Major Extinctions have occurred

11. 2. Biogeographical Evidence Biogeography –Study of the distribution of species throughout the world Earth has six biogeographical regions –Each has its own distinctive mix of species Barriers prevented evolving species from migrating to other regions Continental Drift- –The positions of continents and oceans has shifted through time –The distribution of fossils and existing species allows us to determine approximate timeline

13. 3. Anatomical Evidence Common descent offers explanation for anatomical similarities –Homologous Structures Same function and same basic structure, indicating a common ancestor Ex: human arm and whale forelimb –Analogous Structures Same basic function but different origins Ex: wing of bird and wing of an insect –Vestigial Structures Anatomical structures fully functional in one group and reduced, nonfunctional in another Ex: Modern whales have a pelvic girdle and hind leg bones

16. 4. Biochemical Evidence All organisms use same basic biochemical molecules –DNA –ATP –Identical or nearly identical enzymes Many developmental genes are shared Degree of similarity between DNA base sequences and amino acid sequences indicates the degree of relatedness

17. Process of Evolution

18. Occurs at the population level Evolution – genetic changes within population – more generations – phenotypic changes Microevolution - evolution on a small scale –Gene pool of a population All the alleles in all the individuals making up the population –When the allele frequencies for a population change, microevolution has occurred

19. Evolutionary Change Mutations Genetic drift Gene flow Nonrandom mating Natural selection

20. 1. Mutations Genetic changes that provide the materials for evolutionary change Can cause allele frequencies to change in a gene pool –microevolution to occur Has the ability to create new alleles in a population Happen randomly Does not have an adverse effect on the individual’s reproductive state

21. 2. Genetic Drift Changes in the allele frequencies of a gene pool due to chance Greater effects on smaller populations

22. 2. Genetic Drift Two main mechanisms –Founder Effect Few individuals found a colony Their collective genes represent only fraction of the original gene pool –Bottleneck Effect: Population is subjected to near extinction by a disaster Only a few genotypes contribute to next generation

23. 3. Gene Flow Movement of alleles between populations Occurs when individuals migrate from one population to another Keeps gene pools similar

24. 4. Nonrandom Mating Occurs when individuals pair up according to phenotype or genotype Inbreeding is an example

25. 5. Natural Selection Natural Selection –Process by which populations adapt to their environment –Charles Darwin explained evolution through natural selection –Why does this happen????

28. Charles Darwin and The Origin of Species Charles Darwin ’ s On the Origin of Species by Means of Natural Selection –Published on November 24, 1859 Argued that contemporary species arose from ancestors –Through a process of “ descent with modification, ” with natural selection as the mechanism

29. Darwin made two main points in The Origin of Species: –Organisms inhabiting Earth today descended from ancestral species –Natural selection was the mechanism for descent with modification Basic idea of natural selection is that: –Organisms can change over generations –Individuals with certain heritable traits leave more offspring than others The result of natural selection is evolutionary adaptation

31. Natural Selection Evolution by natural selection requires the following –Variation members of a population differ –Inheritance differences are inheritable –Overproduction populations produce more offspring than the environment can support (struggle for existence) –Differential Reproductive Success better adapted individuals survive to reproduce more offspring

32. Natural Selection Fitness –Measured by the number of fertile offspring produced by an individual

33. Natural Selection Three Main Types of Natural Selection: –Stabilizing Selection –Directional Selection –Disruptive Selection

34. Natural Selection Stabilizing Selection –Occurs when an intermediate, or average, phenotype is favored –Improves adaptation of population to a stable environment –Extreme phenotypes are selected against

35. Stabilizing Selection

36. Natural Selection Directional Selection –One extreme phenotype is favored –Distribution curve shifts in that direction –Can occur when population is adjusting to a changing environment

37. Directional Selection

38. Natural Selection Disruptive Selection –Two or more extreme phenotypes are selected –Two different habitats result in two different phenotypes in a population

39. Disruptive Selection

40. Speciation Chapter 14

41. What is a species? biological species All individuals of 1 species can interbreed Offspring are fertile Sterile zebra-horse cross: not a new species

42. Speciation Macroevolution –observed best within the fossil record Speciation –Splitting of one species into two or more –the transformation of one species into a new species over time

43. Hybrid Animals Breeding of two closely related but distinct species Human activities Unnatural conditions Usually sterile

44. Reproductive Barriers between Species Prezygotic isolating mechanisms Postzygotic isolating mechanisms

45. Reproductive isolating mechanisms Prezygotic isolating mechanisms –Habitat isolation –Temporal isolation –Behavioral isolation –Mechanical isolation –Gamete isolation

46. Reproductive isolating mechanisms Postzygotic isolating mechanisms –Zygote mortality –Hybrid sterility –F 2 fitness

48. Process of Speciation Allopatric Speciation –Geographical barriers separate a population into two groups Sympatric Speciation –Occurs without geographical barriers –Ex: Plants Self-reproduction can maintain a new species

51. Pace of Speciation How FAST does evolution occur? 2 main mechanisms to explain: –Phyletic Gradualism –Punctuated Equilibrium

52. Pace of Speciation 1. Phyletic Gradualism –Change is slow but steady before and after a divergence –Proposes that speciation occurs after populations become isolated Reproductive isolation cannot be detected in fossils

53. Pace of Speciation 2. Punctuated Equilibrium –Some think species appear suddenly Remain essentially unchanged phenotypically until they undergo extinction –Long periods of stasis followed by rapid speciation Occurs relatively rapidly

54. Extinction… Inevitable Occurs all the time –rates have not been steady Extinctions typically eliminate various species of organisms –followed by explosive diversifications of organisms