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I. Importance What are species? How do they evolve? II. Levels of Variation ~ microevolution A ) Variation within locally breeding populations (=demes) 1) Environmental variation 2) Genetic variation 3) Genetic x Environment interaction = Adaptation. Lecture Topic : Speciation.
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I. Importance What are species? How do they evolve? II. Levels of Variation ~ microevolution A) Variation within locally breeding populations (=demes) 1) Environmental variation 2) Genetic variation 3) Genetic x Environment interaction = Adaptation Lecture Topic : Speciation
B) Variation between populations or demes. 1) Environment 2) Genetic (common environment) a. Selection b) Drift Balance between selection and drift. c) Reciprocal exchange of individuals = migration Population differentiation --> No population differentiation --> Levels of Variation (cont.)
C) Variation among GROUPS of populations 1. races 2. sub-species 3. often geographically isolated ~ lack of migration between populations 4. incipient species?? Levels of Variation (cont.)
D) Development of ecotypes (plants) and ecological races (animals) are produced by a G x E interaction ~ adaptation cline = trait exhibits gradual change along a gradient 1920s Turreson Defined term ecotype from plant work 1940-1970s Clausen, Keck, and Heisey: tested if ecotypic differentiation exists: 1) Reciprocal Transplant 2) Common Garden Levels of Variation (cont.)
E) Variation between species 1) individuals appear very different 2) often reproductively isolated 3) individuals of a species appear more similar to one another than to other species. III. A. History of Definition 1) Type Concept a. species is a special creation b. variation around true type "whether breed true" Levels of Variation (cont.)
John Ray First person who asked "what is a species?" He noted there exist individuals that produce similar looking offspring..... Linneaus –early 1700’s Species basic unit of organizing diversity with binomial nomenclature Genus species Thought elemental species from creator because often garden varieties need constant work to maintain (since artificially selected). III. History of Definition (cont.)
1940 Biological Species Concept: Evolutionary biologist Ernst Mayr = A species is defined as groups of actively or potentially cross fertilizing individuals which are isolated from other such groups. Alternate Defn.: Individuals whose genes can recombine with one another. Alternate Defn.:Similar individuals which breed mostly among themselves and which change as a unit through time. Phenotype? Breeding Behavior? Evolutionary Unit? III. B. Modern Usage of term
Figure Biological species concept is based on interfertility rather than physical similarity
Are species reproductive units? Is a species a unit of evolution? V. Origin of Species Microevolution = Macroevolution is the SAME PROCESS: An issue of scale and time! 1) Anagenesis = Slow and directional changes that transform a species. 2) Cladogenesis = Splitting of species (divergence) to form a new species or many species. Clade = group of species derived from a single common ancestral species. Problems with defining a species
Figure The biological species concept is based on interfertility rather than physical similarity
1)Sympatric Speciation Evolution of reproductive isolation within a local population (=deme) Likely infrequent but can occur. Species A and Species B Scale: 10 m square population Modes of Speciation A B A B A B B A A B B A B A BA
Figure Sympatric speciation by polyploidy in plants: Allopolyploidy
Figure Sympatric speciation by polyploidy in plants: Autopolyploidy
2)Allopatric Speciation~Geographic Speciation Evolution of reproductive isolation within a local population (=deme) Likely infrequent but can occur. Species A and Species B Scale: Mt. Range >1000 Km Modes of Speciation BB AA
2)Allopatric Speciation (cont.) ~Geographic Speciation geographical separation differences in habitat populations exposed to different selection pressures ->increasing divergence over time OR peripheral or splinter populations at the edges of the species range. Examples: Modes of Speciation
Figure Allopatric speciation of antelope squirrels in the Grand Canyon
Post-Zygotic Barriers (initial contact) zygotes do not develop normally or die = reduced hybrid viability 2) if zygotes develop normally they are sterile = reduced hybrid fertility 3) Less fit or vigorous F1 progeny produced, AxB mating < fit then AxA or BxB = heterozygote disadvantage 4)Hybrid breakdown= F1 hybrids okay but F2 and F3 etc. hybrid progeny produced are less fit then AxA and BxB. Isolating Mechanisms or Reproductive Barriers
Pre-Zygotic Barriers (secondary contact) 1) Mechanisms a) Ecological Isolation = 2 potentially interbreeding species found in same area but different habitats. Ex., tiger and lion b) Temporal Isolation = 2 species mate at different times during the year. Ex., flowering time, Isolating Mechanisms or Reproductive Barriers
c) Behavioral Isolation = often species specific, courtship behaviors etc. Ex., Blue footed boobies d) Mechanical Isolation = structural differences between species prevent copulation Ex., orchid pollinators Isolating Mechanisms or Reproductive Barriers
Figure Courtship ritual as a behavioral barrier between species
The role of sexual selection in the radiation of Hawaiian Drosophila species
Figure A summary of reproductive barriers between closely related species