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Ch. 24 – The Origin of Species

Ch. 24 – The Origin of Species. What is a Species?. Speciation – the origin of new species

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Ch. 24 – The Origin of Species

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  1. Ch. 24 – The Origin of Species

  2. What is a Species? • Speciation – the origin of new species • The biological species concept defines a species as a population or group of populations whose members have the potential to interbreed with one another in nature to produce viable, fertile offspring, but who cannot produce viable, fertile offspring with members of other species Eastern and Western Meadowlarks

  3. The Origin of Species • Reproductive Isolation – biological species concept states that each species is isolated by factors (barriers) that prevent interbreeding • Prezygotic Barriers – impede mating between species or hinder fertilization of ova • Habitat Isolation • Behavioral Isolation • Temporal Isolation • Mechanical Isolation • Gametic Isolation

  4. Prezygotic Barriers • Habitat Isolation – two species living in different habitats within the same area will not encounter one another • Example: garter snakes in the same genus that live in the same area, but one lives mainly in water and one on land; they will most likely NOT mate.

  5. Prezygotic Barriers • Behavioral Isolation – Special signals used by a species to attract mates • Examples: fireflies recognize signals of their own species, frogs have calls that only attract their own species, and birds have songs that only attract their own species Blue-Footed Boobies

  6. Prezygotic Barriers • Temporal Isolation – Species that breed during different times of the day, season, or year • Example: Similar frog species that do not interbreed

  7. Prezygotic Barriers • Mechanical Isolation – Structural differences in genitalia or flowers • Example: flowers whose pollen is carried by insects to flowers of other species; insects whose copulatory organs may not fit together, so no sperm would be transferred

  8. Prezygotic Barriers • Gametic Isolation – male and female gametes fail to attract each other or are unviable • Example: aquatic species who release sperm and egg into the water where the eggs are fertilized. Gamete recognition does not occur and the sperm are unable to fertilize the egg. Similar to the mechanism used by flowers to recognize sperm (pollen) of their own species.

  9. Postzygotic Barriers • If a sperm cell from one species does fertilize an ovum of another species, then postzygotic barriers usually prevent the hybrid zygote from developing into a viable, fertile adult • Reduced Hybrid Viability • Reduced Hybrid Fertility • Reduced Breakdown

  10. Postzygotic Barriers • Reduced Hybrid Viability – hybrid zygotes fail to develop or fail to reach sexual maturity • Example: Some species of frogs in the genus Rana may interbreed, however the offspring usually do not complete development and those that do are frail.

  11. Postzygotic Barriers • Reduced Hybrid Fertility – hybrid fails to produce functional gametes • Example: mules – a hybrid of a donkey and a horse. Mules cannot backbreed with either species

  12. Postzygotic Barriers • Hybrid Breakdown – offspring of hybrids have reduced viability or fertility • Example: different cotton species can produce fertile hybrids, but breakdown occurs in the next generation when offspring of the hybrids die as seeds or grow into weak and defective plants

  13. Reproductive Barriers

  14. Modes of Speciation • Allopatric Speciation – speciation that takes place in populations with geographically separate ranges. Gene flow is initially interrupted because they are separated in space

  15. Allopatric Speciation • Likelihood of allopatric speciation increases with small, isolated populations; Ex. Galapagos Islands • Conditions: • Mountain ranges • Land bridges • Large lakes reduced to several smaller lakes • The barrier’s effect depends on the ability of the organisms to move about • The gene pool can be changed dramatically by genetic drift and natural selection

  16. Allopatric Speciation

  17. Allopatric Speciation Antelope Squirrels

  18. Does Speciation Always Occur with Allopatric Conditions? • Allopatric conditions could lead to reproductive isolation • Evolutionary divergence of the ring species • Adaptive radiation of the island species • Origin of prezygotic barriers (ex. Fruit flies) • Origin of postzygotic barriers between distant populations of the monkey flower • The isolated population’s gene pool evolves by genetic drift and natural selection; reproductive isolation evolves as a byproduct

  19. An Example of Adaptive Radiation on Island Chains

  20. Modes of Speciation • Sympatric Speciation – speciation that takes place in geographically overlapping populations; gene flow is reduced due to chromosomal changes and nonrandom mating

  21. Sympatric Speciation • In plants • Autopolyploids have more than 2 chromosome sets • Allopolyploids are hybrids of two different species with more than 2 chromosome sets

  22. Sympatric Speciation Autopolyploidy in plants Allopolyploidy in plants

  23. Sympatric Speciation • In animals • Genetic factors could cause “daughter” populations to become dependent on resources other than the parent population • Ex. Fig-eating wasps may prefer other fig trees to lay their eggs. Over time the two wasp populations may diverge into two species • Ex. Cichlids in Lake Victoria show sexual dimorphism and females tend to mate only with males who have their same coloration although they are able to mate with both morphs. Over time the two cichlid populations may diverge into two species

  24. Punctuated Equilibrium Model • Paleontologists rarely find gradual transitions of fossil forms. • They often observe species appearing as new forms rather suddenly in a layer of rock, persisting essentially unchanged, and then disappearing from the fossil record as suddenly as they appeared.

  25. Punctuated Equilibrium Model • Punctuated Equilibrium – species diverge in spurts of relatively rapid change. Long periods of stasis punctuated by episodes of speciation.

  26. From Speciation to Macroevolution • Microevolution – change over generations in a population's allele frequencies (by genetic drift and natural selection) • Speciation – population’s genetic divergence from its ancestral population that results in reproductive isolation. • Macroevolution – Level of change evident over the time scale of the fossil record

  27. Morphological Transformations • The evolution of complex structures from simpler versions (ex. eyes) • Exaptations – structures that evolve in one context, but become co-opted for another function (ex. birds hollow bones must have had some adaptation on the ground)

  28. Evo-devo • Evo-devo – interface between evolutionary biology and the study of how organism’s develop • Allometric Growth – variations in relative rates of growth of various parts of the body – giving the body its form

  29. Evo-devo • Heterochrony – modification of allometric growth. Affects evolution by altering the rates of development of certain body parts • Example: differences in feet of salamanders that live on the ground vs. those that live in trees (timing of foot development)

  30. Evo-devo • Paedomorphosis – sexually mature stage of a species many retain body features that were juvenile structures

  31. Species Selection • Species that endure the longest and reproduce the most offspring, determine the direction of major evolutionary trends • Evolution is never-ending, it is still going on today • Evolution is a response to interactions between organisms and their current environments. If conditions change, an evolutionary trend may cease or even reverse itself.

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