Book contents
- Frontmatter
- Contents
- Contributors
- Preface
- 1 Macroevolution for plant reproductive biologists
- 2 Pollination crisis, plant sex systems, and predicting evolutionary trends in attractiveness
- 3 Evolution and ecological implications of “specialized” pollinator rewards
- 4 Fig–fig wasp mutualism: the fall of the strict cospeciation paradigm?
- 5 Fossil bees and their plant associates
- 6 Pollen evidence for the pollination biology of early flowering plants
- 7 Pollinator mediated floral divergence in the absence of pollinator shifts
- 8 Animal pollination and speciation in plants: general mechanisms and examples from the orchids
- 9 Why are floral signals complex? An outline of functional hypotheses
- 10 A survey on pollination modes in cacti and a potential key innovation
- 11 Zygomorphy, area, and the latitudinal biodiversity gradient in angiosperms
- 12 Ambophily and “super generalism” in Ceratonia siliqua (Fabaceae) pollination
- 13 Structure and dynamics of pollination networks: the past, present, and future
- 14 Pollinators as drivers of plant distribution and assemblage into communities
- 15 Effects of alien species on plant–pollinator interactions: how can native plants adapt to changing pollination regimes?
- 16 Pollen resources of non-Apis bees in southern Africa
- 17 Advances in the study of the evolution of plant–pollinator relationships
- Index
- Plate section
- References
8 - Animal pollination and speciation in plants: general mechanisms and examples from the orchids
Published online by Cambridge University Press: 05 January 2012
Edited by
Book contents
- Frontmatter
- Contents
- Contributors
- Preface
- 1 Macroevolution for plant reproductive biologists
- 2 Pollination crisis, plant sex systems, and predicting evolutionary trends in attractiveness
- 3 Evolution and ecological implications of “specialized” pollinator rewards
- 4 Fig–fig wasp mutualism: the fall of the strict cospeciation paradigm?
- 5 Fossil bees and their plant associates
- 6 Pollen evidence for the pollination biology of early flowering plants
- 7 Pollinator mediated floral divergence in the absence of pollinator shifts
- 8 Animal pollination and speciation in plants: general mechanisms and examples from the orchids
- 9 Why are floral signals complex? An outline of functional hypotheses
- 10 A survey on pollination modes in cacti and a potential key innovation
- 11 Zygomorphy, area, and the latitudinal biodiversity gradient in angiosperms
- 12 Ambophily and “super generalism” in Ceratonia siliqua (Fabaceae) pollination
- 13 Structure and dynamics of pollination networks: the past, present, and future
- 14 Pollinators as drivers of plant distribution and assemblage into communities
- 15 Effects of alien species on plant–pollinator interactions: how can native plants adapt to changing pollination regimes?
- 16 Pollen resources of non-Apis bees in southern Africa
- 17 Advances in the study of the evolution of plant–pollinator relationships
- Index
- Plate section
- References
Summary
Introduction
Orchids have served as a model system for pollinator-driven evolution since Darwin’s milestone contribution on the fertilization of this plant family (Darwin 1862; van der Pijl 1966; Johnson 2006; Peakall 2007). Orchids represent a major component of angiosperm diversity, and besides their famous and often highly specialized pollination systems (van der Pijl 1966; Schiestl and Schlüter 2009; Tremblay 1992), they have evolved strikingly different lifestyles and thrive in various different habitats (Dressler 1981). Many different mechanisms have been invoked as drivers for orchid-species richness (van der Pijl 1966; Dressler 1981; Peakall 2007; Gravendeel et al. 2004). For example, Cozzolino and Widmer (2005b) suggested the evolution of deceptive pollination as a key trait for orchid diversity. Another study inferred epiphytic lifestyle as a main factor for orchid diversity (Gravendeel et al. 2004). For epiphytic taxa, which indeed represent a major component of orchid diversity, a combination of fine, dust-like seeds and specialized pollination has been attributed as the key factor for species richness (Gentry and Dodson 1987). Although my review focuses on pollination and its link to species richness, it is not the purpose to advocate pollination as the main mechanism driving speciation. Rather, I aim to better clarify its role among the undoubtedly many mechanisms that shape the incredible diversity in orchids and other plants.
Despite little agreement on the definition of a species in general (Coyne and Orr 2004; Johnson 2006), most researchers acknowledge the importance of some degree of reproductive isolation between populations of incipient species (Rieseberg and Willis 2007; Grant 1981; Widmer et al. 2009). In plants, however, reproductive isolation can depend on various intrinsic and extrinsic factors that act at different levels of reproduction. For example, in two sister species of Mimulus, habitat and pollinator differences, as well as post-pollination and post-zygotic isolation work together to prevent interspecific geneflow almost totally (Ramsey et al. 2003). Early acting barriers (habitat, pollinators), however, contribute more to total isolation in this system, which is a common situation among angiosperm taxa (Rieseberg and Willis 2007; Widmer et al. 2009). Pollinator or floral isolation can be the by-product of adaptation to a pollination niche, i.e. the differential use of pollinator resources by plants (Grant 1949; Grant 1994; Johnson 2010; Levin 2004). Floral isolation can work through floral morphology (morphological isolation), allowing only certain pollinators access to rewards (e.g. through long floral spurs or tubes) or placement of pollen on different body parts of a pollinator (group). In ethological floral isolation, a specific (group of) pollinator(s) are attracted through innate preferences to given floral signals, or establishes floral constancy through learning of floral signals. Thus, floral isolation is the consequence of specialization to pollinators with specific morphology (e.g. long proboscis) or behavior (e.g. preferences for specific floral signals).
- Type
- Chapter
- Information
- Evolution of Plant-Pollinator Relationships , pp. 263 - 278Publisher: Cambridge University PressPrint publication year: 2011
References
1999 Phylogeny and evolution of Orchis and allied genera based on ITS DNA variation: morphological gaps and molecular continuityMolecular Phylogenetics & Evolution 13 67CrossRefGoogle ScholarPubMed
1979 Pollination of 2 species of Dalechampia (Euphorbiaceae) in Mexico by euglossine beesBiotropica 11 278CrossRefGoogle Scholar
2008 Adaptation from standing genetic variationTrends in Ecology & Evolution 23 38CrossRefGoogle ScholarPubMed
2003 Molecular phylogenetics and evolution of Orchidinae and eelected Habenariinae (Orchidaceae)Botanical Journal of the Linnean Society 142 1CrossRefGoogle Scholar
2003 Allele substitution at a flower colour locus produces a pollinator shift in MonkeyflowersNature 426 176CrossRefGoogle Scholar
2008 Pollinator shifts and the origin and loss of plant speciesAnnals of the Missouri Botanical Garden 95 264CrossRefGoogle Scholar
1997 Molecular Evolution and Adaptive RadiationCambridge, UK: Cambridge University PressGoogle Scholar
2005 The evolutionary basis of reproductive isolation in Mediterranean orchidsTaxon 54 977CrossRefGoogle Scholar
2005 Orchid diversity: an evolutionary consequence of deception?Trends in Ecology & Evolution 20 487CrossRefGoogle ScholarPubMed
2004 Evidence for reproductive isolate selection in Mediterranean orchids: karyotype differences compensate for the lack of pollinator specificityProceedings of the Royal Society of London Series B, Biological Sciences 271 S259CrossRefGoogle ScholarPubMed
2005 Evidence for pollinator sharing in Mediterranean nectar-mimic orchids: absence of premating barriers?Proceedings of the Royal Society B, Biological Sciences 272 1271CrossRefGoogle ScholarPubMed
1862 On the Various Contrivances by which British and Foreign Orchids Are Fertilised by InsectsLondon, UKJohn MurrayGoogle Scholar
2008 Molecular systematics and evolution in an African cycad–weevil interaction: Amorphocerini (Coleoptera:Curculionidae:Molytinae) weevils on EncephalartosMolecular Phylogenetics and Evolution 47 102CrossRefGoogle Scholar
1981 The Orchids: Natural History and ClassificationCambridge, MAHarvard University PressGoogle Scholar
2003 Conflicts between plants and pollinators that reproduce within inflorescences: evolutionary variations on a themeOikos 100 3CrossRefGoogle Scholar
2008 What, if anything, is sympatric speciation?Journal of Evolutionary Biology 21 1452CrossRefGoogle ScholarPubMed
1999 Floral isolation between Aquilegia formosa and Aquilegia pubescensProceedings of the Royal Society of London Series B, Biological Sciences 266 2247CrossRefGoogle Scholar
2010 Colour mimicry and sexual deception by Tongue orchids (Cryptostylis)Naturwissenschaften 97 97CrossRefGoogle Scholar
1987 Diversity and biogeography of neotropical vascular epiphytesAnnals of the Missouri Botanical Garden 74 205CrossRefGoogle Scholar
2003 Reproductive biology of Montrichardia arborescens (Araceae) in French GuianaJournal of Tropical Ecology 19 103CrossRefGoogle Scholar
1996 Phylogeny and speciation in Lapeirousia subgenus Lapeirousia (Iridaceae: Ixioideae)Annals of the Missouri Botanical Garden 83 346CrossRefGoogle Scholar
2002 Plant diversity of the Cape Region of southern AfricaAnnals of the Missouri Botanical Garden 89 281CrossRefGoogle Scholar
2006 Radiation of pollination systems in the iridaceae of sub-Saharan AfricaAnnals of Botany 97 317CrossRefGoogle ScholarPubMed
1991 Olfactory and visual attraction of (Cyclocephalini, Dynastinae) to the inflorescences of (Araceae)Biotropica 23 23CrossRefGoogle Scholar
1949 Pollination systems as isolating mechanisms in angiospermsEvolution 3 82CrossRefGoogle ScholarPubMed
1993 Origin of floral isolation between ornithophilous and sphingophilous plant speciesProceedings of the National Academy of Sciences USA 90 7729CrossRefGoogle ScholarPubMed
1994 Modes and origins of mechanical and ethological isolation in angiospermsProceedings of the National Academy of Sciences USA 91 3CrossRefGoogle ScholarPubMed
2004 Epiphytism and pollinator specialization: drivers for orchid diversity?Philosophical Transactions of the Royal Society of London Series B-Biological Sciences 359 1523CrossRefGoogle ScholarPubMed
2010 Floral biology and reproductive isolation by floral scent in three sympatric aroid species in French GuianaPlant Biology 12 587Google ScholarPubMed
2007 Single gene-mediated shift in pollinator attraction in PetuniaPlant Cell 19 779CrossRefGoogle ScholarPubMed
1994 Floral and ecological isolation between and Proceedings of the National Academy of Sciences USA 91 2493CrossRefGoogle Scholar
1997 Insect pollination and floral mechanisms in South African species of (Orchidaceae)Plant Systematic and Ecology 204 195CrossRefGoogle Scholar
2010 The pollination niche and its role in the diversification and maintenance of the southern African floraPhilosophical Transactions of the Royal Society B, Biological Sciences 365 499CrossRefGoogle ScholarPubMed
2000 Generalization versus specialization in plant pollination systemsTREE 15 140Google ScholarPubMed
2003 Specialized pollination systems in southern AfricaSouth African Journal of Science 99 345Google Scholar
1998 Phylogeny and Radiation of Pollination Systems in Disa (Orchidaceae)American Journal of Botany 85 402CrossRefGoogle Scholar
2009 The role of animal pollination in plant speciation: integrating ecology, geography, and geneticsAnnual Review of Ecology Evolution and Systematics 40 637CrossRefGoogle Scholar
2003 Pollinator assemblages and visitation rates for 11 species of neotropical Costus (Costaceae)Biotropica 35 198Google Scholar
2001 A phylogenetic analysis of Diurideae (Orchidaceae) based on plastid DNA sequence dataAmerican Journal of Botany 88 1903CrossRefGoogle ScholarPubMed
2005 Pollen limitation of plant reproduction: pattern and processAnnual Review of Ecology Evolution and Systematics 36 467CrossRefGoogle Scholar
2006 (Araceae) and (Coleoptera, Dynastinae): a well-established pollination system in the northern Atlantic Rainforest of Pernambuco, BrazilPlant Biology 8 529CrossRefGoogle ScholarPubMed
2005 Does selection on floral odor promote differentiation among populations and species of the sexually deceptive orchid genus ?Evolution 59 1449CrossRefGoogle ScholarPubMed
2005 Cuticular hydrocarbons as sex pheromone of the bee and the key to its mimicry by the sexually deceptive orchid, Journal of Chemical Ecology 31 1765CrossRefGoogle Scholar
1990 Responses of male Turner wasps to females and the sexually deceptive orchid it pollinatesFunctional Ecology 4 159CrossRefGoogle Scholar
2007 Speciation in the Orchidaceae: confronting the challengesMolecular Ecology 16 2834CrossRefGoogle ScholarPubMed
2004 A mark-recapture study of male Colletes cunicularius bees: implications for pollination by sexual deceptionBehavioral Ecology and Sociobiology 56 579CrossRefGoogle Scholar
2003 Components of reproductive isolation between the monkeyflowers and (Phrymaceae)Evolution 57 1520CrossRefGoogle Scholar
2004 Integration of populations and differentiation of speciesNew Phytologist 161 59CrossRefGoogle ScholarPubMed
1993 The perfume flowers of Cyphomandra (Solanaceae): pollination by euglossine bees, bellow mechanism, osmophors, and volatilesPlant Systematic and Evolution 187 51CrossRefGoogle Scholar
1999 Pollinator Preference and the Evolution of Floral Traits in Monkeyflowers (Mimulus)Proceedings of the National Academy of Sciences USA 96 11910CrossRefGoogle Scholar
2005 On the success of a swindle: pollination by deception in orchidsNaturwissenschaften 92 255CrossRefGoogle ScholarPubMed
2002 Do changes in floral odor cause speciation in sexually deceptive orchids?Plant Systematics and Evolution 234 111CrossRefGoogle Scholar
2009 Floral isolation, specialized pollination, and pollinator behavior in orchidsAnnual Review of Entomology 54 425CrossRefGoogle ScholarPubMed
2004 Chemical communication in the sexually deceptive orchid genus Botanical Journal of the Linnean Society 144 199CrossRefGoogle Scholar
2008 Molecular mechanisms of floral mimicry in orchidsTrends in Plant Science 13 228CrossRefGoogle ScholarPubMed
2011 Stearoyl-ACP desaturases are associated with floral isolation in sexually deceptive orchidsProceedings of the National Academy of Sciences 108 5696CrossRefGoogle Scholar
2010 Pollination efficiency and the evolution of specialized deceptive pollination systemsThe American Naturalist 175 98CrossRefGoogle ScholarPubMed
2007 Patterns of reproductive isolation in Mediterranean deceptive orchidsEvolution 61 2623CrossRefGoogle ScholarPubMed
2009 A key role for floral scent in a wasp-pollination system in Eucomis (Hyacinthaceae)Annals of Botany 103 715CrossRefGoogle Scholar
1997 Negative frequency-dependent selection by pollinators on artificial flowers without rewardsEvolution 51 715CrossRefGoogle ScholarPubMed
2009 Pollen limitation and reproduction varies with population size in experimental populations of Sabatia angularis (Gentianaceae)Botany-Botanique 87 330CrossRefGoogle Scholar
2009 Speciation in sexually deceptive orchids: pollinator-driven selection maintains discrete odour phenotypes in hybridizing speciesBiological Journal of the Linnean Society 98 439CrossRefGoogle Scholar
2009 Perfume-collecting male euglossine bees as pollinators of a basal angiosperm: the case of Unonopsis stipitata (Annonaceae)Plant Biology 11 29CrossRefGoogle Scholar
1992 Trends in the pollination ecology of the orchidaceae: evolution and systematicsCanadian Journal of Botany 70 642CrossRefGoogle Scholar
2002 Molecular phylogeny of cycads inferred from rbcL sequencesNaturwissenschaften 89 221CrossRefGoogle ScholarPubMed
2009 Patterns of plant speciation in the Cape floristic regionMolecular Phylogenetics and Evolution 51 85CrossRefGoogle ScholarPubMed
2006 Macroevolutionary data suggest a role for reinforcement in pollination system shiftsEvolution 60 1596CrossRefGoogle ScholarPubMed
1966 Orchid Flowers: Their Pollination and EvolutionCoral Gables, FLUniversity of Miami PressGoogle Scholar
1963 Das sexuelle Anlockungsprinzip der Catasetinen- und Stanhopeen- Blüten und die wahre Funktion ihres sogenannten FuttergewebesÖsterreichische botanische Zeitschrift 110 308CrossRefGoogle Scholar
1966 Parfümsammelnde Bienen als Bestäuber von Orchidaceen und GloxiniaÖsterreichische botanische Zeitschrift 113 302CrossRefGoogle Scholar
2010 Large-range movements of neotropical orchid bees observed via radio telemetryPLoS ONE 5CrossRefGoogle ScholarPubMed
2000 Subtribal and generic relationship of Maxillarieae (Orchidaceae) with emphasis on Stanhopeinae: combined molecular evidenceAmerican Journal of Botany 87 1842CrossRefGoogle Scholar
2007 Molecular phylogenetics of Maxillaria and related genera (Orchidaceae:Cymbidieae) based on combined molecular data setsAmerican Journal of Botany 94 1860CrossRefGoogle ScholarPubMed
2010 Are landscape structures insurmountable barriers for foraging bees? A mark-recapture study with two solitary pollen specialist speciesApidologie 41 497CrossRefGoogle Scholar
- 2
- Cited by