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Macroevolutionary Processes— Radiations

Macroevolutionary Processes— Radiations. Major Speciation Models. Ancestor B A Allopatric C B (island) A A’ Founder A A’ A” B Phyletic gradualism (ancestor dies out). Concepts Involving Radiations.

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Macroevolutionary Processes— Radiations

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  1. Macroevolutionary Processes— Radiations

  2. Major Speciation Models Ancestor B A Allopatric C B (island) A A’ Founder A A’ A” B Phyletic gradualism (ancestor dies out)

  3. Concepts Involving Radiations • Definition of “radiation”—relatively rapid diversification of an initial ancestral population into several derivatives (species) • Often associated with opening of a new geographic area or set of new niches (e.g., ecological, behavioral, nutritional) • Often accompanied or provoked by one or more novelties/innovations

  4. Concepts Involving Radiations • Character displacement—one species affects direction of evolution or at least local behavior, in one or more competitors, not often explicitly demonstrated but often implicitly invoked in studies of radiations • Parallelisms—multiple independent origins of similar traits within lineages or among closely related lineages is often compelling evidence of a radiation

  5. Coevolutionary Radiation • Intimate association with and parallel speciation in different organismal lineages • Must demonstrate closely correspondent diversification patterns between organism groups; often revealed by congruent molecular phylogenies and tight host-user relationships • Generally demands sole utilization of one host by an organism (no generalist behavior) • e.g., figs and fig wasps • e.g., yuccas and yucca moths

  6. Adaptive Radiation • “The rise of a diversity of ecological roles and attendant adaptations in different species within a lineage" (Givnish and Sytsma) • Term “adaptive radiation” has been recently loosely applied to all bursts of diversification; attempts being made to restrict definition • Does not always result in large species numbers or depend on a key innovation

  7. Adaptive Radiation • Correctly defined examples require empirical evidence: • Adaptive value of phenotypic traits • Comparative methods—distantly related, ecologically similar species show convergent form, physiology or behavior • Functional analyses—functional significance of traits (e.g., stomata) • Populational studies—phenotypic traits linked to survivorship and reproduction • Environmental sorting of different phenotypic forms, tracking of multiple new niches/adaptive zones by sister taxa; similar phenotypic traits and occupation of “equivalent” habitats by non-sister taxa

  8. Adaptive Radiation • Examined (or at least postulated) most intensively in oceanic islands • Could further subdivide examples • Diversification within one habitat—e.g., pollinator exploitation • Diversification across habitats—e.g., classic AR • Examples later on

  9. Adaptive Radiation • Adaptive radiation still commonly assumed prior to investigation; results then used to characterize “an example of adaptive radiation”—circular reasoning!! • Few studies have adequately demonstrated divergence in both phenotypic (e.g., morphological, anatomical) traits and ecological differentiation among sister taxa

  10. Adaptive Radiation • Few studies have adequately investigated the evolution of derivative taxa relative to the sister group (nearest relative[s]) • Extraordinarily few groups have been investigated intensively for comprehensive information on evolutionary processes, relevant speciation models, isolation mechanisms, microevolutionary (genetic) processes, etc. • Most studies have focused on island groups—easier to work with and get funded, sexier; but many of the same processes should hold for continental groups

  11. Molecular Data in AR Studies • Use of phenotypic traits to reconstruct phylogeny of a group and to interpret phenotypic changes is controversial, considered by many to be circular reasoning • Molecular markers provide a more "neutral" data set from which to generate a phylogeny • Molecular phylogeny can be used to infer relationship of morphological traits, ecological diversification, divergence in feeding behavior, etc., and can be used as starting point for investigating molecular/developmental basis of traits

  12. Evolution in African Cichlids • Several distinctive groups, many very different looking species in each, with divergent feeding strategies within lakes • Several hundred cichlid species in each lake, most endemic to one lake • Extreme phenotypic features among species within groups make interpretation of relationships difficult • Similar forms with similar mouth structures, feeding behavior and ecological niche grow in different lakes; are they related? Or parallel products of adaptive radiation?

  13. Evolution in African Cichlids

  14. Evolution in African Cichlids • mtDNA phylogeny reveals that cichlid species in different African lakes with equivalent body form and mouth-feeding structures are NOT sister species  rampant parallelism • phenotypically and ecologically divergent species typically are sisters extensive divergence in relatives Reinthal & Meyer (1997)

  15. Evolution in African Cichlids • Evolution in African cichlid fishes (cont.) • Ecologically equivalent species in different lakes occupy similar microhabitats, eat same food items  strong selection for similar phenotypes • Suggestion of sympatric speciation within individual lakes, accompanied by adaptive radiation based on mouthparts for feeding  reinforcement by competitive exclusion?

  16. Diversification in Brocchinia • e.g., “pitcher plants” (Brocchinia) on Venezuelan tepuis • About 20 species on tall, nutrient-poor (often boggy) sandstone mesas (tepuis) jutting up out of the Venezuelan lowland rainforest • Several growth habits and feeding strategies--"tank" habit and carnivory, epiphytes, tree forms, ant-plants Givnish et al. (1997)

  17. Diversification in Brocchinia

  18. Diversification in Brocchinia • “pitcher plants” (Brocchinia) on Venezuelan tepuis (cont.) • Morphological and anatomical traits related intimately to growth form and nutrition; tank habit found only at higher elevations • Divergent growth forms and feeding strategies obscure the relationships  chloroplast DNA phylogeny used to interpret morphological and ecological evolution • Two sister lineages occur primarily on tepuis in different geographic areas

  19. Diversification in Brocchinia • “pitcher plants” (Brocchinia) on Venezuelan tepuis (cont.)—parallelism of carnivorous traits Givnish et al. (1997)

  20. Diversification in Brocchinia stepwise evolution of traits for carnivorous habit Givnish et al. (1997)

  21. Evolution in Hawaiian Viola • Nine taxa, seven species distributed over most islands • Species occupy several different habitats across five islands • dry forest • dry cliff • mesic streambank • swamp (cloud) forest • open bog • Species growing in same habitat on different islands are almost identical morphologically, anatomically

  22. Evolution in Hawaiian Viola Hawaiian Islands Price, J. P. a. W. W. L. (2004).

  23. Evolution in Hawaiian Viola • Phylogenetic tree of Internal Transcribed Spacer (nrDNA) shows that Hawaiian taxa highly derived (i.e., advanced) in the genus • Nearest sister is an Arctic tundra bog violet, Viola langsdorffii, NOTtropical species Ballard & Sytsma (2000)

  24. Evolution in Hawaiian Viola Range of Viola langsdorffii • Arctic-breeding birds probably dispersed seeds to Hawaii • ca. 75 bird species breed in Arctic, overwinter in central or south Pacific • some (e.g., golden plover) arrive in Hawaii by the millions, feed in areas near tundra bogs before migration Ballard & Sytsma (2000)

  25. Evolution in Hawaiian Viola Bog (reclining herb or shrub) Dry Forest (treelet) Swamp forest (shrub) V. maviensis (Maui, Molokai, Hawaii) V. wailenalenae (Kauai) V. kauaensis (Kauai, Oahu) V. tracheliifolia (Kauai, Oahu, Maui, Molokai) V. robusta (Molokai)

  26. Evolution in Hawaiian Viola Bog Swamp Forest Dry Forest Prevailing Trade Winds Very Wet (Bog) Wet (Swamp Forest) Dry (Dry Forest) Havran (unpublished data)

  27. Evolution in Hawaiian Viola • Phylogenetic tree of ITS sequences, and mapping of islands and habitats onto it: • Modest radiation from Arctic tundra bog ancestor • Colonization first on Kauai, subsequent diversification and dispersal eastward • Parallel evolution in growth form, leaf morphology, leaf anatomy • Morphologically “analogous” species on different islands not close relatives

  28. Evolution in Hawaiian Viola Phylogenetic Tree Showing Leaf Traits of Hawaiian Viola

  29. Comparative Ecological Studies of “Evolutionary Replicates” Across Islands • Replicate sublineages studied intensively on two different islands, Kaui and Molokai • Replicates include: -1 dry forest species (V. tracheliifolia) across islands -2 swamp forest species (V. robusta or V. waialenalenae) -2 bog species (V. kauaensis or V. maviensis)

  30. Evolution in Hawaiian Viola Kauai Molokai V. kauaensis Bog V. maviensis V. wailenalenae Swamp Forest V. robusta V. tracheliifolia Dry Forest V. tracheliifolia Ecological research • Microhabitat parameters • Soil • Climate • Light Availability • Physiological Traits • Leaf Anatomy • Photosynthetic Physiology • Leaf Water Potential • Reproductive Biology • Breeding Systems • Isolation Mechanisms • Ethological • Temporal Havran (unpublished data)

  31. V. waialenalenae V. kauaensis

  32. Soil moisture & related traits (e.g., C) differentiate spp. N & pH also important, Ca not very important (distinguish bog species) Light etc. contribute little WATER IS KEY! Evolution in Hawaiian Viola Examined % canopy openness, soil moisture, pH, N, C & several micronutrients in populations of 4 spp. Havran (unpublished data)

  33. Evolution in Hawaiian Viola Climate - Humidity Kauai Molokai Havran (unpublished data)

  34. Evolution in Hawaiian Viola Soil Water Kauai Molokai Bog Swamp Dry Forest Havran (unpublished data)

  35. Evolution in Hawaiian Viola Photosynthetic Efficiency in V. robusta and V. maviensis Swamp forest violet outperforms bog violet at all light levels!? Havran (unpublished data)

  36. Leaf Anatomy - Bog Violets Evolution in Hawaiian Viola V. maviensis • Thick upper and lower epidermis • Palisade cells 1 layer thick V. kauaensis Havran (unpublished data)

  37. Evolution in Hawaiian Viola Leaf Anatomy - Swamp Violets • Thick upper epidermis, thin lower epidermis • Palisade cells 2 layers thick • Druses present V. robusta V. wailenalenae Havran (unpublished data)

  38. Evolution in Hawaiian Viola Morphologically and anatomically similar species on different islands are not phylogenetic “sister” species Morphologically and anatomically similar species on different islands occupy similar ecological niches soil moisture mainly drives local species distributions in different habitats; anatomy linked to habitats Surprisingly, Swamp Violet (V. wailenalenae) is more photosynthetically efficient at high light levels than Bog Violet (V. kauaensis), but restriction to lower soil moisture prevents it from invading bog! Leaf anatomy appears linked to habitat  Hawaiian violets = adaptive radiation

  39. Review • A “radiation” is a relatively rapid burst of speciation, producing multiple species from a recent common ancestor • Not all lineage radiations are adaptive; researchers must demonstrate a link between environmental selection (habitat) and phenotypes (morphology) • Molecular data are valuable to provide a basis for inferring morphological evolution

  40. Review • Adaptive radiations common on oceanic islands but probably overlooked on continents • Two consequences of AR are common and often concurrent: • Non-sister species inhabiting similar ecological zones are phenotypically convergent • Sister species in different adjacent habitats are phenotypically divergent

  41. Bibliography • Ballard, H. E., Jr. and K. J. Sytsma. 2000. Evolution and biogeography of the woody Hawaiian violets (Viola, Violaceae): Arctic origins, herbaceous ancestry, and bird dispersal. Evolution 54:1521-1532. • Givnish, T. J. and K. J. Sytsma (eds.). 1997. Molecular evolution and adaptive radiation. Cambridge University Press, Cambridge, United Kingdom. 621 pp. • Givnish, T. J., K. J. Sytsma, J. F. Smith, W. J. Hahn, D. H. Benzing, and E. M. Burkhardt. 1997. Molecular evolution and adaptive radiation in Brocchinia (Bromeliaceae: Pitcairnioideae) atop tepuis of the Guayana shield. In: Givnish, T. J. and K. J. Sytsma (eds.), Molecular evolution and adaptive radiation. Cambridge University Press, Cambridge, United Kingdom. pp. 259-311. • Niklas, K. J. 1997. The evolutionary biology of plants. University of Chicago Press, Chicago, Illinois. 449 pp.

  42. Bibliography • Nitecki, M. H. (ed.). 1990. Evolutionary innovations. University of Chicago Press, Chicago, Illinois. 304 pp. • Reinthal, P. N. and A. Meyer. 1997. Molecular phylogenetic tests of speciation models in Lake Malawi cichlid fishes. In: Givnish, T. J. and K. J. Sytsma (eds.), Molecular evolution and adaptive radiation. Cambridge University Press, Cambridge, United Kingdom. pp. 376-390. • Schluter, D. and J. D. McPhail. 1993. Character displacement and replicate adaptive radiation. Trends in Ecology and Evolution 8:197-200.

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