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Nothing in biology makes sense except in the light of evolution. – Theodosius Dobzhansky

Evolution. Nothing in biology makes sense except in the light of evolution. – Theodosius Dobzhansky. Charles Darwin in later years. What is Evolution?. The kind we’re talking about is sometimes called organic evolution to distinguish it from non-biological changes over time.

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Nothing in biology makes sense except in the light of evolution. – Theodosius Dobzhansky

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  1. Evolution Nothing in biology makes sense except in the light of evolution. – Theodosius Dobzhansky Charles Darwin in later years

  2. What is Evolution? The kind we’re talking about is sometimes called organic evolution to distinguish it from non-biological changes over time. Working definition: Evolution is the progressive change in populations over time. NOT SPECIES, NOT INDIVIDUALS

  3. Evolution Holds a Unique Place in Biology Other disciplines ask how? Evolutionary biology asks why?

  4. Evolution’s Core Principles Natural selection.

  5. Evolution’s Core Principles Common descent with modification.

  6. Evolutionary Time Scales Macroevolution: Long time scale events that create and eliminate species.

  7. Evolutionary Time Scales Microevolution: Short time scale events (generation-to-generation) that change the genotypes and phenotypes of populations. We’ll begin our more intensive look at evolution with microevolution.

  8. Darwin’s Voyage of Discovery A reconstruction of the HMS Beagle sailing off Patagonia.

  9. The Voyage of the Beagle

  10. Charles Lyell –(geologist) uniformatarianism. The Earth is older than 6,000 years 1797-1875 Georges Cuvier – species extinction. Fossils 1769-1832 Darwin’s Ideas Did Not Develop in a Vacuum Contributor’s to Darwin’s thinking included:

  11. Thomas Malthus – struggle for existence. Carrying capacity: J curve/S curve 1766-1834 Jean Baptiste de Lamarck – evolution by acquired characteristics. First evolution Theory, Giraffes get taller due to stretching In parents 1744-1829 Darwin’s Ideas Did Not Develop in a Vacuum Contributor’s to Darwin’s thinking included:

  12. Alfred Russel Wallace Independently Drew the Same Conclusions as Darwin Papers from Wallace and Darwin were jointly presented (with little impact) to the Linnaean Society in 1858.

  13. Darwin’s Observations and Inferences Organized by Ernst Mayr Observation 1: Left unchecked, the number of organisms of each species will increase exponentially, generation to generation. Observation 2: In nature, populations tend to remain stable in size. Observation 3: Environmental resources are limited. Inference 1: Production of more individuals than can be supported by the environment leads to a struggle for existence among individuals, with only a fraction of offspring surviving in each generation.

  14. Darwin’s Observations and Inferences Observation 4: Individuals of a population vary extensively in their characteristics with no two individuals being exactly alike. Observation 5: Much of this variation between individuals is heritable.

  15. Darwin’s Observations and Inferences Inference 2: Survival in the struggle for existence is not random, but depends in part on the heritable characteristics of individuals. Individuals who inherit characteristics most fit for their environment are likely to leave more offspring than less fit individuals.

  16. Darwin’s Observations and Inferences Inference 3: The unequal ability of individuals to survive and reproduce leads to a gradual change in a population, with favorable characteristics accumulating over generations (natural selection). Taken together, these three inferences are a statement of Darwin’s Theory of Evolution.

  17. Darwin in his early years. The Weak Link of Genetics and the Modern Synthesis A major problem in Darwin’s theory was the lack of a mechanism to explain natural selection. (No mitosis, meiosis, replication, chromosomes, laws of inheritance) How could favorable variations be transmitted to later generations? With the rediscovery of Mendel’s work and its vast extension in the first half of the 20th century, the missing link in evolutionary theory was forged. Darwinian theory supported by genetics is known as the modern synthesis.

  18. Evidence for Evolution – The Fossil Record

  19. Evidence for Evolution - Comparative Morphology Homologous structures Why use the same skeletal plan for these very different appendages?

  20. Evidence for Evolution - Comparative Embryology Why do embryos of different animals pass through a similar developmental stage? Recent discoveries of the conservation of molecular mechanisms of development are even more compelling.

  21. Evidence of Evolution –Conservation and Diversification at the Molecular Level Why should different organism possess related genes? Why does the degree of relationship of genes match their degree of relationship established by other methods?

  22. Evolution of pesticide resistance in response to selection. Evidence for Evolution – Evolution Observed

  23. Evidence for Evolution – Evolution Observed Evolution of drug-resistance in HIV

  24. SpecialExamples • Kin Selection: relative fitness includes fitness of close relatives • Artificial selection: farming/animal breeding • Sexual selection: based on mating • Convergent evolution: different ancestor common lifestyle (analogous structures result) • Divergent evolution: common ancestor different lifestyle (homologous structures result) • Parallel evolution: evolving in the same pattern • Coevolution: two evolving each other

  25. Speciation • Steps in the process: • Subdivision of the population • Evolution of each subpopulation in independent directions • Change in population that reproductively isolates the population from the other. • Return to same setting and no longer can members of the two populations mate.

  26. Speciation • Allopatric: Geographical separation leads to initial subdivision of the population. • Rivers, volcanoes, earthquakes, roads, train lines, etc..

  27. Sympatric speciation • Sympatric: Isolation of populations occurs while organisms have physical contact with each other.

  28. Reproductive Isolation • Prezygotic vs. Postzygotic • Needed for speciation: Organisms can look somewhat different and still be one species if this does not occur. • Organisms can look very much alike, but be two species if this occurs. • The idea is that eventually diversity will build up in the populations independently and thus would eventually look different.

  29. Courtship rituals, like these, are critical for mating within a species, but ineffective for attracting members of other species. Many Intrinsic Reproductive Isolating Mechanisms Drive Speciation

  30. Behavioral Isolation Mechanisms Courtship rituals, like these, are critical for mating within a species, but ineffective for attracting members of other species.

  31. (different habits within an overlapping range) Many Intrinsic Reproductive Isolating Mechanisms Drive Speciation

  32. Many Intrinsic Reproductive Isolating Mechanisms Drive Speciation

  33. Many Intrinsic Reproductive Isolating Mechanisms Drive Speciation

  34. Speciation Dynamics - Gradualism or Punctuated Equilibrium? Punctuated equilibrium appears to be a more accurate view of speciation dynamics. : long period lacking speciation where variation builds up followed by some dramatic change in the environment that leads to a struggle for survival and lots of speciation and microevolution.

  35. Evolution possibilities • Convergent evolution: leads to analogous structures. (same function/different ancestry)

  36. Parallel evolution vs. Coevolution • A: divergent B: convergent C. parallel

  37. Divergent evolution • Divergent evolution: leads to homologous structures. (same ancestry/different function)

  38. Coevolution • Yucca moth and Yucca flower

  39. Does coadaptation mean coevolution?

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