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Evolution of Armor Plating in Three-spined Sticklebacks

Evolution of Armor Plating in Three-spined Sticklebacks . EEB 440: Biology of Fish Isaac Fine, Allie Leitch, Karen Baweja, Meagan Crofoot. Three Spined Stickleback Gasterosteus aculeatus. Frequent the Northern Hemisphere Typically 4-6cm long Have at least 3 dorsal spines

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Evolution of Armor Plating in Three-spined Sticklebacks

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  1. Evolution of Armor Plating in Three-spined Sticklebacks EEB 440: Biology of Fish Isaac Fine, Allie Leitch, Karen Baweja, Meagan Crofoot

  2. Three Spined SticklebackGasterosteusaculeatus Frequent the Northern Hemisphere Typically 4-6cm long Have at least 3 dorsal spines Known for their unique trait of Armor Plating

  3. Armor Plating Bony Plating in place of scales Existence of the armor plating is dependent on if the fish are marine or freshwater dwellers Marine sticklebacks are typically fully-armored (about 30 bony plates) Freshwater sticklebacks are typically low-armored (about 10 bony plates) (Smith 2009)

  4. Evolutionary Benefits of Armor Loss When a stickleback gives up body armor, it gains agility and speed More beneficial in an environment such as a lake Freshwater environments lack an abundance diversity of predators compared to marine (Smith 2009)

  5. Evolutionary Benefits of Armor Loss Marine three-spined sticklebacks rely on their full armor plating to protect them from predators It is not uncommon for freshwater sticklebacks to have fewer spines because of the decreased amount of predators (Smith 2009).

  6. Life history Many sticklebacks are anadromous, and the low-armored individuals tend to survive more in the freshwater environments The rate at which this transition occurs is surprising and uncommon: the change can be seen in as little as 1-3 generations

  7. Review Amount of Lateral plate armor is heritable and under selection (Bell 2001) Major Locus Ectodysplasin-Eda (Colosimo et al. 2005) Minor Loci 5 unnamed Semi-Additive (Colosimo et al. 2005)

  8. Review Continued Additional selection on Eda (Low Armor Allele) Due to the correlation between decreased armor and increased growth rate Differences between marine and freshwater sticklebacks (Barrett 2010) Flexible-Stem model of Evolution (Wund et al. 2008)

  9. Applications Model Organism: an extensively studied species used to help understand the biological processes of other species. quick generation time rapid evolution ability to adapt to new environments well studied

  10. Lake Washington Reverse Evolution: evolving back to a more primitive form resulting in a loss of diversity over time. Involves the collapse of a phenotypically diverse population into a single form. (Kitano et al. 2008)

  11. The Great Lakes! By the 1960s several Lake Michigan herring species had disappeared, most catches were of a single form. Lake Huron was dominated by 2 herring species in the past, recent data indicate they have become a single hybrid form. Seehausen 2006

  12. Conservation Genetics Humans are playing a huge role in the loss of fish biodiversity Turning natural systems into managed systems leading to homogenous environments invasive species, overfishing, pollution By using the threespine stickleback to come to a better understanding of these processes we can promote new diversity and prevent future loss in species throughout the world

  13. Future Work Speciation Sexual Selection Imprinted/Learned Behavior Reproductive Isolation Ecological Factors Model Generation

  14. Future Work Sexual Imprinting Learning mate choice early in life Paternal Nest Gluing Know it happens but not the mechanism If tied to ecologically divergent traits, sexual isolation

  15. Future Work Stickleback examples Body Size Foraging niche dependant Nuptial Color Adaptation to signaling and sensory systems in different light environments Odor Difference Diet difference, habitat, and immune system genes determined by local parasites Kozak, Head and Boughman 2011

  16. Questions?

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