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Species and Speciation

Species and Speciation. D. melanogaster. D. simulans. Species and Speciation I. Species Concepts. Species and Speciation I. Species Concepts How we define a species depends on the goal we have in mind. Species and Speciation I. Species Concepts

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Species and Speciation

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  1. Species and Speciation D. melanogaster D. simulans

  2. Species and Speciation I. Species Concepts

  3. Species and Speciation I. Species Concepts How we define a species depends on the goal we have in mind.

  4. Species and Speciation I. Species Concepts How we define a species depends on the goal we have in mind. Are we categorizing existing or fossil organisms?

  5. Species and Speciation I. Species Concepts How we define a species depends on the goal we have in mind. Are we categorizing existing or fossil organisms? Are we trying to understand correlates between populations adapting to different environments?

  6. Species and Speciation I. Species Concepts How we define a species depends on the goal we have in mind. Are we categorizing existing or fossil organisms? Are we trying to understand correlates between populations adapting to different environments? Are we trying to reconstruct phylogenies?

  7. Species and Speciation I. Species Concepts A. Morphological Species Concept

  8. Species and Speciation I. Species Concepts A. Morphological Species Concept - Categorical/'essential' in a platonic sense; based on morphological similarity to a 'type' specimen

  9. Species and Speciation I. Species Concepts A. Morphological Species Concept - Categorical/'essential' in a platonic sense; based on morphological similarity to a 'type' specimen - Useful, but many species are polymorphic and some sibling species are indistinguishable morphologically. H. erato D. melanogaster (M)

  10. Species and Speciation I. Species Concepts A. Morphological Species Concept - Categorical/'essential' in a platonic sense; based on morphological similarity to a 'type' specimen - Useful, but many species are polymorphic and some sibling species are indistinguishable morphologically. - Nonetheless, for dead or fossilized specimens, the phenotype is all we might have to analyze. As such, there are ways of quantifying the phenotype and defining "phenetic" species... by quantifying the within-group phenotypic variation, statistical analysis can ascertain whether a novel individual lies within that typical range. New Species!! old species

  11. Species and Speciation I. Species Concepts A. Morphological Species Concept - Categorical/'essential' in a platonic sense; based on morphological similarity to a 'type' specimen - Useful, but many species are polymorphic and some sibling species are indistinguishable morphologically. - Nonetheless, for dead or fossilized specimens, the phenotype is all we might have to analyze. As such, there are ways of quantifying the phenotype and defining "phenetic" species... by quantifying the within-group phenotypic variation, statistical analysis can ascertain whether a novel individual lies within that typical range. Problem... need a pretty good sample to describe within-group variation with confidence. old species New Species?

  12. Species and Speciation • I. Species Concepts • A. Morphological Species Concept • B. Biological Species Concept - Mayr 1942

  13. Species and Speciation • I. Species Concepts • A. Morphological Species Concept • B. Biological Species Concept - Mayr 1942 • "Groups of actually or potentially interbreeding populations that are reproductively isolated from other such groups"

  14. Species and Speciation • I. Species Concepts • A. Morphological Species Concept • B. Biological Species Concept - Mayr 1942 • "Groups of actually or potetially interbreeding populations that are reproductively isolated from other such groups" • - Biological units are genetically defined; reproductive isolation makes populations different from one another, creating new units. So, reproductive isolation is the key characteristic of a species.

  15. Species and Speciation • I. Species Concepts • A. Morphological Species Concept • B. Biological Species Concept - Mayr 1942 • "Groups of actually or potetially interbreeding populations that are reproductively isolated from other such groups" • - Biological units are genetically defined; reproductive isolation makes populations different from one another, creating new units. So, reproductive isolation is the key characteristic of a species. • - Limitations:

  16. Species and Speciation • I. Species Concepts • A. Morphological Species Concept • B. Biological Species Concept - Mayr 1942 • "Groups of actually or potetially interbreeding populations that are reproductively isolated from other such groups" • - Biological units are genetically defined; reproductive isolation makes populations different from one another, creating new units. So, reproductive isolation is the key characteristic of a species. • - Limitations: • - Process may be continuous - where do you draw the "line" of isolation?

  17. Species and Speciation • I. Species Concepts • A. Morphological Species Concept • B. Biological Species Concept - Mayr 1942 • "Groups of actually or potetially interbreeding populations that are reproductively isolated from other such groups" • - Biological units are genetically defined; reproductive isolation makes populations different from one another, creating new units. So, reproductive isolation is the key characteristic of a species. • - Limitations: • - not applicable to asexual species

  18. Species and Speciation • I. Species Concepts • A. Morphological Species Concept • B. Biological Species Concept - Mayr 1942 • "Groups of actually or potetially interbreeding populations that are reproductively isolated from other such groups" • - Biological units are genetically defined; reproductive isolation makes populations different from one another, creating new units. So, reproductive isolation is the key characteristic of a species. • - Limitations: • - not applicable to asexual species • - hybridization occurs in nature, even between otherwise 'good' species. Natural variability is not strictly discontinuous, so pigeon-holing on any grounds will be wrong in some cases. It becomes a matter of degree. The best example are "Ring Complexes"...series of species which breed with neighboring species but the 'end' species do not. Salamanders in California, Gulls in circumpolar regions.

  19. Ring Species Divergence that correlates with geographical distance can create interesting patterns on a spherical globe, or around a geographical feature.

  20. Ring Species Divergence that correlates with geographical distance can create interesting patterns on a spherical globe, or around a geographical feature.

  21. Ring Species Divergence that correlates with geographical distance can create interesting patterns on a spherical globe, or around a geographical feature.

  22. Species and Speciation • I. Species Concepts • A. Morphological Species Concept • B. Biological Species Concept - Mayr 1942 • "Groups of actually or potetially interbreeding populations that are reproductively isolated from other such groups" • - Biological units are genetically defined; reproductive isolation makes populations different from one another, creating new units. So, reproductive isolation is the key characteristic of a species. • - Limitations: • - not applicable to asexual species • - hybridization occurs in nature, even between otherwise 'good' species. Natural variability is not strictly discontinuous, so pigeon-holing on any grounds will be wrong in some cases. It becomes a matter of degree. The best example are "Ring Complexes"...series of species which breed with neighboring species but the 'end' species do not. Salamanders in California, Gulls in circumpolar regions. • - Allopatric populations: Potential interbreeding means that populations that are spatially separated and morphologically/genetically distinct may be in the same species.

  23. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation A. Pre-Zygotic Barriers

  24. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation A. Pre-Zygotic Barriers 1. Geographic Isolation (large scale or habitat)

  25. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation A. Pre-Zygotic Barriers 1. Geographic Isolation (large scale or habitat) 2. Temporal Isolation

  26. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation A. Pre-Zygotic Barriers 1. Geographic Isolation (large scale or habitat) 2. Temporal Isolation 3. Behavior Isolation - don't recognize one another as mates

  27. Species and Speciation I. Species Concepts II. Recognizing Species III. Making Species - Reproductive Isolation A. Pre-Zygotic Barriers 1. Geographic Isolation (large scale or habitat) 2. Temporal Isolation 3. Behavior Isolation - don't recognize one another as mates 4. Mechanical isolation - genitalia don't fit

  28. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation A. Pre-Zygotic Barriers 1. Geographic Isolation (large scale or habitat) 2. Temporal Isolation 3. Behavior Isolation - don't recognize one another as mates 4. Mechanical isolation - genitalia don't fit 5. Gametic Isolation - gametes transfered but sperm can't fertilize egg

  29. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation A. Pre-Zygotic Barriers 1. Geographic Isolation (large scale or habitat) 2. Temporal Isolation 3. Behavior Isolation - don't recognize one another as mates 4. Mechanical isolation - genitalia don't fit 5. Gametic Isolation - gametes transfered but sperm can't fertilize egg B. Post-Zygotic Isolation

  30. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation A. Pre-Zygotic Barriers 1. Geographic Isolation (large scale or habitat) 2. Temporal Isolation 3. Behavior Isolation - don't recognize one another as mates 4. Mechanical isolation - genitalia don't fit 5. Gametic Isolation - gametes transfered but sperm can't fertilize egg B. Post-Zygotic Isolation 1. Genomic Incompatibility - zygote dies

  31. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation A. Pre-Zygotic Barriers 1. Geographic Isolation (large scale or habitat) 2. Temporal Isolation 3. Behavior Isolation - don't recognize one another as mates 4. Mechanical isolation - genitalia don't fit 5. Gametic Isolation - gametes transfered but sperm can't fertilize egg B. Post-Zygotic Isolation 1. Genomic Incompatibility - zygote dies 2. Hybrid Inviability - F1 has lower survival

  32. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation A. Pre-Zygotic Barriers 1. Geographic Isolation (large scale or habitat) 2. Temporal Isolation 3. Behavior Isolation - don't recognize one another as mates 4. Mechanical isolation - genitalia don't fit 5. Gametic Isolation - gametes transfered but sperm can't fertilize egg B. Post-Zygotic Isolation 1. Genomic Incompatibility - zygote dies 2. Hybrid Inviability - F1 has lower survival 3. Hybrid Sterility - F1 has reduced reproductive success

  33. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation A. Pre-Zygotic Barriers 1. Geographic Isolation (large scale or habitat) 2. Temporal Isolation 3. Behavior Isolation - don't recognize one another as mates 4. Mechanical isolation - genitalia don't fit 5. Gametic Isolation - gametes transfered but sperm can't fertilize egg B. Post-Zygotic Isolation 1. Genomic Incompatibility - zygote dies 2. Hybrid Inviability - F1 has lower survival 3. Hybrid Sterility - F1 has reduced reproductive success 4. F2 breakdown - F1's survive but F2's have incompatible combo's of genes

  34. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation III. Speciation

  35. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation III. Speciation Speciation is not a goal, or a selective product of adaptation. It is simply a consequence of genetic changes that occurred for other reasons (selection, drift, mutation, etc.).

  36. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation III. Speciation A. Modes:

  37. Species and Speciation I. Species Concepts II. Making Species - Reproductive Isolation III. Speciation A. Modes: 1. Allopatric: Divergence in geographically separate populations - Vicariance - range divided by new geographic feature A B C

  38. III. Speciation A. Modes: 1. Allopatric: Divergence in geographically separate populations - Vicariance - range divided by new geographic feature - Peripatric - divergence of a small migrant population A B

  39. III. Speciation A. Modes: 1. Allopatric: Divergence in geographically separate populations - Vicariance - range divided by new geographic feature - Peripatric - divergence of a small migrant population 2. Parapatric - neighboring populations diverge, even with gene flow

  40. III. Speciation A. Modes: 1. Allopatric: Divergence in geographically separate populations - Vicariance - range divided by new geographic feature - Peripatric - divergence of a small migrant population 2. Parapatric - neighboring populations diverge, even with gene flow

  41. 2. Parapatric - neighboring populations diverge, even with gene flow Hybrid Backcross?? Hybrid

  42. III. Speciation A. Modes: 1. Allopatric: Divergence in geographically separate populations - Vicariance - range divided by new geographic feature - Peripatric - divergence of a small migrant population 2. Parapatric - neighboring populations diverge, even with gene flow 3. Sympatric: Divergence within a single population

  43. 3. Sympatric: Divergence within a single population Maynard Smith (1966) - hypothesized this was possible if there was disruptive selection within a population - perhaps as a specialist herbivore/parasite colonized and adapted to a new host.

  44. 3. Sympatric: Divergence within a single population Maynard Smith (1966) - hypothesized this was possible if there was disruptive selection within a population - perhaps as a specialist herbivore/parasite colonized and adapted to a new host. Example: Hawthorn/Apple Maggot Fly (Rhagoletis pomonella) Hawthorn maggot fly is a native species that breeds on Hawthorn (Crataegus sp.)

  45. 3. Sympatric: Divergence within a single population Maynard Smith (1966) - hypothesized this was possible if there was disruptive selection within a population - perhaps as a specialist herbivore/parasite colonized and adapted to a new host. Example: Hawthorn/Apple Maggot Fly (Rhagoletis pomonella) Europeans brought apples to North America. They are in the same plant family (Rosaceae) as Hawthorn.

  46. 3. Sympatric: Divergence within a single population Maynard Smith (1966) - hypothesized this was possible if there was disruptive selection within a population - perhaps as a specialist herbivore/parasite colonized and adapted to a new host. Example: Hawthorn/Apple Maggot Fly (Rhagoletis pomonella) Europeans brought apples to North America. They are in the same plant family (Rosaceae) as Hawthorn. In 1864, apple growers noticed infestation by Apple Maggot flies...which were actually just "hawthorn flies"...

  47. 3. Sympatric: Divergence within a single population Maynard Smith (1966) - hypothesized this was possible if there was disruptive selection within a population - perhaps as a specialist herbivore/parasite colonized and adapted to a new host. Example: Hawthorn/Apple Maggot Fly (Rhagoletis pomonella) races breed on their own host plant, and have adapted to the different seasons of fruit ripening. Only a 4-6% hybridization rate. Temporal, not geographic, isolation.

  48. III. Speciation A. Modes B. Speciation Rate Some characteristics should increase the chances that a species radiates.... - high dispersal capacity (increase geographic isolation) - small (more likely to become isolated) - produce lots of offspring (more successful colonists) INSECTS in general, and Beetles in particular.... they fly (disperse), but poorly (don't return...isolation). And they are tough as nails, so they can survive to wherever they disperse.

  49. III. Speciation A. Modes B. Speciation Rate

  50. III. Speciation A. Modes B. Speciation Rate Some characteristics should increase the chances that a species radiates....

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