1. EVOLUTION & SPECIATION

2. Microevolution. What is it? changes in the gene pool of a population over time which result in relatively small changes to the organisms in the population changes in the gene pool of a population over time which result in relatively small changes to the organisms in the population changes which would not result in the newer organisms being considered a different species. changes which would not result in the newer organisms being considered a different species. Examples would include a change in a species’ coloring or size. Examples would include a change in a species’ coloring or size.

3. VOCABULARY REVIEW EVOLUTION – CHANGE OVER TIME EVOLUTION – CHANGE OVER TIME NATURAL SELECTION NATURAL SELECTION INDIVIDUALS BETTER ADAPTED TO THE ENVIRONMENT ARE ABLE TO SURVIVE & REPRODUCE –A.K.A. “SURVIVAL OF THE FITTEST”

4. NEW VOCABULARY POPULATION POPULATION GROUP OF INDIVIDUALS OF SAME SPECIES THAT INTERBREED GROUP OF INDIVIDUALS OF SAME SPECIES THAT INTERBREED GENE POOL GENE POOL COMMON GROUP OF ALL GENES PRESENT IN A POPULATION

5. Evolution of Populations Occurs when there is a change in relative frequency of alleles

6. Gene Pool Combined genetic information of all members Allele frequency is # of times alleles occur For some traits certain phenotypes appear more frequently

7. Variation in Populations 2 processes can lead to this: Mutations - change in DNA sequence DO not always change the phenotypes, but can affect an organisms 'fitness'. Gene Shuffling – from sexual reproduction

8. Mechanisms of Microevolution 1. Natural Selection 2. Sexual Selection 3. Genetic Drift 4. Gene Flow

9. Natural Selection: environment increases the frequency of alleles that provide a reproductive advantage Natural Selection: environment increases the frequency of alleles that provide a reproductive advantage only form of microevolution that adapts a population to its environment only form of microevolution that adapts a population to its environment

15. Natural Selection on Different Traits 3 Types that affect the phenotypes in a population 1. Shifts to middle range 2. Shifts to 2 extremes 3. Shifts to 1 extreme

16. 1. Stabilizing Selection- individuals near the center of the phenotype range have a higher fitness then those at both ends.

17. 2. Directional Selection- Population may find itself in circumstances where individuals occupying one extreme in the range of phenotypes are favoured over others

18. 3. Disruptive Selection- occurs when both extremes are favoured in a population.

19. Sexual selection Sexual dimorphism: secondary sex characteristic distinction Sexual dimorphism: secondary sex characteristic distinction Sexual selection: selection towards secondary sex characteristics that leads to sexual dimorphism Sexual selection: selection towards secondary sex characteristics that leads to sexual dimorphism

20. Nonrandom mating: inbreeding and assortive mating (both shift frequencies of different genotypes) Nonrandom mating: inbreeding and assortive mating (both shift frequencies of different genotypes)

21. Genetic Drift = changes to allele frequency as a result of chance Genetic Drift = changes to allele frequency as a result of chance

22. Genetic Drift changes populations……. Example- Random change in allele frequency causes an allele to become common Example- Random change in allele frequency causes an allele to become common

23. Bottleneck effect = dramatic reduction in population size usually resulting in significant genetic drift Occurs when disasters such as earthquakes, floods, droughts, and fires reduce the population

24. Founder Effect: Founder Effect: - Genetic Drift that occurs when individuals from a large population leave to establish a new population - Allele frequencies of the new population will not be the same as those of the original

25. Gene Flow: genetic exchange due to the migration of fertile individuals or gametes between populations (reduces differences between populations) Gene Flow: genetic exchange due to the migration of fertile individuals or gametes between populations (reduces differences between populations)

26. SPECIATION THE FORMATION OF NEW SPECIES THE FORMATION OF NEW SPECIES AS NEW SPECIES EVOLVE, POPULATIONS BECOME REPRODUCTIVELY ISOLATED AS NEW SPECIES EVOLVE, POPULATIONS BECOME REPRODUCTIVELY ISOLATED REPRODUCTIVE ISOLATION – MEMEBERS OF 2 POPULATIONS CANNOT INTERBREED & PRODUCE FERTILE OFFSPRING. REPRODUCTIVE ISOLATION – MEMEBERS OF 2 POPULATIONS CANNOT INTERBREED & PRODUCE FERTILE OFFSPRING.

28. These squirrels live on opposite sides of the Grand Canyon. This is an example of allopatric speciation.

29. SPECIATION IN DARWIN’S FINCHES SPECIATION IN THE GALAPAGOS FINCHES OCCURRED BY: SPECIATION IN THE GALAPAGOS FINCHES OCCURRED BY: - FOUNDING OF A NEW POPULATION, - GEOGRAPHIC ISOLATION which led to - - REPRODUCTIVE ISOLATION and CHANGES IN THE NEW POPULATION’S GENE POOL due to COMPETITION.

31. Evidence of Evolution 1. Fossil Record 2. Geographic Distribution of Living Species 3. Homologous Body structures 4. Similarities in Embryology

32. Evidence of Evolution Fossil Record provides evidence that living things have evolved Fossils show the history of life on earth and how different groups of organisms have changed over time