Book contents
- Ant-Plant Interactions
- Ant-Plant Interactions
- Copyright page
- Contents
- Contributors
- Preface
- Part I Landscape Mosaics, Habitat Fragmentation, and Edge Effects
- Part II Ant-Seed Interactions and Man-Induced Disturbance
- Part III Ant-Plant Protection Systems under Variable Habitat Conditions
- Part IV Effect of Invasive Ants on Plants and Their Mutualists
- 12 Playing the System: The Impacts of Invasive Ants and Plants on Facultative Ant-Plant Interactions
- 13 Biological Invasions and Ant-Flower Networks on Islands
- 14 Mutualisms and the Reciprocal Benefits of Comparing Systems with Native and Introduced Ants
- 15 Invasion Biology and Ant-Plant Systems in Australia
- Part V Applied Ant Ecology: Agroecosystems, Ecosystem Engineering, and Restoration
- Part VI Perspectives
- Index
- Plate section
- References
13 - Biological Invasions and Ant-Flower Networks on Islands
from Part IV - Effect of Invasive Ants on Plants and Their Mutualists
Published online by Cambridge University Press: 01 September 2017
Book contents
- Ant-Plant Interactions
- Ant-Plant Interactions
- Copyright page
- Contents
- Contributors
- Preface
- Part I Landscape Mosaics, Habitat Fragmentation, and Edge Effects
- Part II Ant-Seed Interactions and Man-Induced Disturbance
- Part III Ant-Plant Protection Systems under Variable Habitat Conditions
- Part IV Effect of Invasive Ants on Plants and Their Mutualists
- 12 Playing the System: The Impacts of Invasive Ants and Plants on Facultative Ant-Plant Interactions
- 13 Biological Invasions and Ant-Flower Networks on Islands
- 14 Mutualisms and the Reciprocal Benefits of Comparing Systems with Native and Introduced Ants
- 15 Invasion Biology and Ant-Plant Systems in Australia
- Part V Applied Ant Ecology: Agroecosystems, Ecosystem Engineering, and Restoration
- Part VI Perspectives
- Index
- Plate section
- References
- Type
- Chapter
- Information
- Ant-Plant InteractionsImpacts of Humans on Terrestrial Ecosystems, pp. 267 - 289Publisher: Cambridge University PressPrint publication year: 2017
References
Abbott, K. L. & Green, P. T.. (2007). Collapse of an ant-scale mutualism in a rainforest on Christmas Island. Oikos 116: 1238–1246.Google Scholar
Abbott, K. L., Green, P. T. & O’Dowd, D.. (2014). Seasonal shifts in macronutrient preferences in supercolonies of the invasive yellow crazy ant Anoplolepis gracilipes (Smith, 1857) (Hymenoptera: Formicidae) on Christmas Island, Indian Ocean. Austal Entomology 53: 337–346.Google Scholar
Altshuler, D. L. (1999). Novel interactions of non-pollinating ants with pollinators and fruit consumers in a tropical forest. Oecologia 119: 600–606.Google Scholar
Anderson, G. J., Bernardello, G., Stuessy, T. F. & Crawford, D. J.. (2001). Breeding system and pollination of selected plants endemic to Juan Fernández Islands. American Journal of Botany 88: 220–233.Google Scholar
Armbruster, W., Pelabon, C., Hansen, T. & Mulder, C.. (2004). Floral integration and modularity: distinguishing complex adaptations from genetic constraints. In Pigliucci, M. & Preston, K., eds. Phenotypic integration: studying the ecology and evolution of complex phenotypes. Oxford: Oxford University Press, pp. 23–49.CrossRefGoogle Scholar
Baker, H. G. (1967). Support for Baker’s law – as a rule. Evolution 21: 853–856.CrossRefGoogle Scholar
Barrett, S. C. H. (1996). The reproductive biology and genetics of island plants. Philosophical Transactions of the Royal Society of London Series B-Biological Sciences 351: 725–733.Google Scholar
Bawa, K. S. (1982). Outcrossing and the incidence of dioecism in island floras. American Naturalist 119: 866–871.Google Scholar
Beattie, A. J. (2006). The evolution of ant pollination systems. Botanische Jahrbücher Systematik 127: 43–55.CrossRefGoogle Scholar
Bertelsmeier, C., Luque, G. M. & Courcham, F.. (2013). Global warming may freeze the invasion of big-headed ants. Biological Invasions 15: 1561–1572.Google Scholar
Bleil, R., Blüthgen, N. & Junker, R. R.. (2011). Ant-plant mutualism in Hawaii? Invasive ants reduce flower parasitism but also exploit floral nectar of the endemic shrub Vaccinium reticulatum (Ericaceae). Pacific Science 65: 291–300.CrossRefGoogle Scholar
Bond, W. & Slingsby, P.. (1984). Collapse of an ant-plant mutualism: the Argentine ant (Iridomyrmex humilis) and myrmeco-chorous Proteaceae. Ecology 65: 1031–1037.CrossRefGoogle Scholar
Boyer, A. G. & Jetz, W.. (2014). Extinctions and the loss of ecological function in island bird communities. Global Ecology and Biogeography 23: 679–688.Google Scholar
Brühl, C. A., Gunsalam, G. & Linsenmair, K. E.. (1998). Stratification of ants (Hymenoptera, Formicidae) in a primary rain forest in Sabah, Borneo. Journal of Tropical Ecology 14: 285–297.Google Scholar
Caujape-Castells, J., Tye, A., Crawford, D. J., Santos-Guerra, A. et al. (2010). Conservation of oceanic island floras: present and future global challenges. Perspectives in Plant Ecology, Evolution and Systematics 12: 107–129.Google Scholar
Chown, S. L., Gremmen, N. J. M. & Gaston, K. J.. (1998). Ecological biogeography of Southern Ocean Islands: species-area relationships, human impacts, and conservation. The American Naturalist 152: 562–575.Google Scholar
Cole, F. R., Medeiros, A. C., Loope, L. L. & Zuehlke, W. W.. (1992). Effects of the Argentine ant on arthropod fauna of Hawaiian high-elevation shrubland. Ecology 73: 1313–1322.Google Scholar
Cooling, M., Hartley, S., Sim, D. A. & Lester, P. J.. (2012). The widespread collapse of an invasive species: Argentine ants (Linepithema humile) in New Zealand. Biology Letters 8: 430–433.Google Scholar
Cooling, M. & Hoffmann, B. D.. (2015). Here today, gone tomorrow: declines and local extinctions of invasive ant populations in the absence of intervention. Biological Invasions 17: 3351–3357.Google Scholar
Czechowski, W., Marko, B., Erős, K. & Csata, E.. (2011). Pollenivory in ants (Hymenoptera: Formicidae) seems to be much more common than it was thought. Annales Zoologici 61: 519–525.Google Scholar
Daly, H. V. & Magnacca, K. N.. (2003). Insects of Hawaii. Honolulu, HI: University of Hawaii Press.Google Scholar
Davis, N. E., O’Dowd, D. J., Mac Nally, R. & Green, P. T.. (2009). Invasive ants disrupt frugivory by endemic island birds. Biology Letters: rsbl20090655.Google Scholar
Denslow, J. S. (2003). Weeds in paradise: thoughts on the invasibility of tropical islands. Annals of the Missouri Botanical Garden 90: 119–127.CrossRefGoogle Scholar
Drescher, J., Feldhaar, H. & Blüthgen, N.. (2011). Interspecific aggression, resource monopolization and ecological dominance of Anoplolepis gracilipes within an ant community in Malaysian Borneo. Biotropica 43: 93–99.Google Scholar
Dupont, Y. L., Hansen, D. M. & Olesen, J. M.. (2003). Structure of a plant-flower-visitor network in the high-altitude sub-alpine desert of Tenerife, Canary Islands. Ecography 26: 301–310.CrossRefGoogle Scholar
Dupont, Y. L., Hansen, D. M., Valido, A. & Olesen, J. M.. (2004). Impact of introduced honey bees on native pollination interactions of the endemic Echium wildpretii (Boraginaceae) on Tenerife, Canary Islands. Biological Conservation 118: 301–311.CrossRefGoogle Scholar
Economo, E. P. & Sarnat, E. M.. (2012). Revisiting the ants of Melanesia and the taxon cycle: historical and human-mediated invasions of a tropical archipelago. The American Naturalist 180: E1–E16.CrossRefGoogle ScholarPubMed
Edwards, P. J., Fleischer-Dogley, F. & Kaiser-Bunbury, C. N.. (2015). The nutrient economy of Lodoicea maldivica, a monodominant palm producing the world’s largest seed. New Phytologist 206: 990–999.Google Scholar
Emerson, B. C. & Kolm, N.. (2005). Species diversity can drive speciation. Nature 434: 1015–1017.Google Scholar
Fisher, B. L. (1997). Biogeography and ecology of the ant fauna of Madagascar (Hymenoptera: Formicidae). Journal of Natural History 31: 269–302.Google Scholar
Gaigher, R. & Samways, M. J.. (2013). Strategic management of an invasive ant-scale mutualism enables recovery of a threatened tropical tree species. Biotropica 45: 128–134.Google Scholar
Galen, C. & Cuba, J.. (2001). Down the tube: pollinators, predators, and the evolution of flower shape in the Alpine Skypilot, Polemonium viscosum. Evolution 55: 1963–1971.Google Scholar
Galen, C., Kaczorowski, R., Todd, S. L., Geib, J., et al. (2011). Dosage-dependent impacts of a floral volatile compound on pollinators, larcenists, and the potential for floral evolution in the Alpine Skypilot Polemonium viscosum. The American Naturalist 177: 258–272.Google Scholar
Gaume, L., Zacharias, M. & Borges, R. M.. (2005). Ant-plant conflicts and a novel case of castration parasitism in a myrmecophyt. Evolutionary Ecology Research 7: 435–452.Google Scholar
Gillespie, R. G. & Roderick, G. K.. (2002). Arthropods on islands: colonization, speciation, and conservation. Annual Review of Entomology 47: 595–632.Google Scholar
Giraud, T., Pedersen, J. S. & Keller, L.. (2002). Evolution of supercolonies: the Argentine ants of southern Europe. Proceedings of the National Academy of Sciences of the United States of America 99: 6075–6079.Google Scholar
Gonzalvez, F. G., Santamaria, L., Corlett, R. T. & Rodriguez-Girones, M. A.. (2013). Flowers attract weaver ants that deter less effective pollinators. Journal of Ecology 101: 78–85.Google Scholar
Gorb, E. & Gorb, S.. (2011). How a lack of choice can force ants to climb up waxy plant stems. Arthropod-Plant Interactions 5: 297–306.Google Scholar
Gruber, M. A. M., Burne, A. R., Abbott, K. L., Pierce, R. J. et al. (2013). Population decline but increased distribution of an invasive ant genotype on a Pacific atoll. Biological Invasions 15: 599–612.Google Scholar
Haber, W. A., Frankie, G. W., Baker, H. G., Baker, I. et al. (1981). Ants like flower nectar. Biotropica 13: 211–214.CrossRefGoogle Scholar
Haines, I. H. & Haines, J. B.. (1978a). Colony structure, seasonality and food-requirements of crazy ant. Ecological Entomology 3: 109–118.CrossRefGoogle Scholar
Haines, I. H. (1978b). Pest status of the crazy ant, Anoplolepis longipes (Jerdon) (Hymenoptera: Formicidae), in the Seychelles. Bulletin of Entomological Research 68: 627–638.Google Scholar
Hanna, C., Foote, D. & Kremen, C.. (2013). Invasive species management restores a plant-pollinator mutualism in Hawaii. Journal of Applied Ecology 50: 147–155.Google Scholar
Hanna, C., Naughton, I., Boser, C., Alarcon, R. et al. (2015). Floral visitation by the Argentine ant reduces bee visitation and plant seed set. Ecology 96: 222–230.Google Scholar
Hansen, D. M. (2015). Non-native megaherbivores: the case for novel function to manage plant invasions on islands. AoB Plants 7: plv085; doi:10.1093/aobpla/plv085.CrossRefGoogle ScholarPubMed
Hansen, D. M. & Müller, C. B.. (2009). Invasive ants disrupt gecko pollination and seed dispersal of the endangered plant Roussea simplex in Mauritius. Biotropica 41: 202–208.Google Scholar
Hansen, D. M., Olesen, J. M. & Jones, C. G.. (2002). Trees, birds and bees in Mauritius: exploitative competition between introduced honey bees and endemic nectarivorous birds? Journal of Biogeography 29: 721–734.CrossRefGoogle Scholar
Harley, R. (1991). The greasy pole syndrome. In Huxley, C. R. & Cutler, D. F., eds. Ant-plant interactions. Oxford: Oxford University Press, pp. 430–433.Google Scholar
Harper, G. A. & Bunbury, N.. (2015). Invasive rats on tropical islands: their population biology and impacts on native species. Global Ecology and Conservation 3: 607–627.CrossRefGoogle Scholar
Hee, J. J., Holway, D. A., Suarez, A. V. & Case, T. J.. (2000). Role of propagule size in the success of incipient colonies of the invasive Argentine ant. Conservation Biology 14: 559–563.Google Scholar
Herrera, C. M., Herrera, J. & Espadaler, X.. (1984). Nectar thievery by ants from southern Spanish insect-pollinated flowers. Insectes Sociaux 31: 142–154.Google Scholar
Hickman, J. C. (1974). Pollination by ants – low-energy system. Science 184: 1290–1292.Google Scholar
Hill, M., Holm, K., Vel, T., Shah, N. J. et al. (2003). Impact of the introduced yellow crazy ant Anoplolepis gracilipes on Bird Island, Seychelles. Biodiversity and Conservation 12: 1969–1984.Google Scholar
Hingston, A. B. & McQuillan, P. B.. (1999). Displacement of Tasmanian native megachilid bees by the recently introduced bumblebee Bombus terrestris (Linnaeus, 1758) (Hymenoptera: Apidae). Australian Journal of Zoology 47: 59–65.Google Scholar
Hölldobler, B. & Wilson, E. O.. (1990). The ants. Cambridge, MA: Harvard University Press.Google Scholar
Holway, D. A. 1999. Competitive mechanisms underlying the displacement of native ants by the invasive Argentine ant. Ecology 80: 238–251.Google Scholar
Holway, D. A., Lach, L., Suarez, A. V., Tsutsui, N. D. et al. (2002). The causes and consequences of ant invasions. Annual Review of Ecology and Systematics 33: 181–233.CrossRefGoogle Scholar
Janicki, J., Narula, N., Ziegler, M., Guénard, B. et al. (2016). Visualizing and interacting with large-volume biodiversity data using client-server web-mapping applications: the design and implementation of antmaps.org. Ecological Informatics 32: 185–193.Google Scholar
Junker, R. R. (2016). Multifunctional and diverse floral scents mediate biotic interactions embedded in communities. In Blande, J. D. & Glinwood, R. T., eds. Deciphering chemical language of plant communication. Heidelberg: Springer, pp. 257–282.Google Scholar
Junker, R. R., Bleil, R., Daehler, C. C. & Blüthgen, N.. (2010). Intra-floral resource partitioning between endemic and invasive flower visitors: consequences for pollinator effectiveness. Ecological Entomology 35: 760–767.CrossRefGoogle Scholar
Junker, R. R. & Blüthgen, N.. (2008). Floral scents repel potentially nectar-thieving ants. Evolutionary Ecology Research 10: 295–308.Google Scholar
Junker, R. R. (2010a). Dependency on floral resources determines the animals’ responses to floral scents. Plant Signaling and Behavior 5: 1014–1016.Google Scholar
Junker, R. R. (2010b). Floral scents repel facultative flower visitors, but attract obligate ones. Annals of Botany 105: 777–782.Google Scholar
Junker, R. R., Daehler, C. C., Dötterl, S., Keller, A. et al. (2011a). Hawaiian ant-flower networks: nectar-thieving ants prefer undefended native over introduced plants with floral defenses. Ecological Monographs 81: 295–311.Google Scholar
Junker, R. R., Gershenzon, J. & Unsicker, S. B.. (2011b). Floral odour bouquet loses its ant repellent properties after inhibition of terpene biosynthesis. Journal of Chemical Ecology 37: 1323–1331.Google Scholar
Kaiser-Bunbury, C. & Blüthgen, N.. (2015). Integrating network ecology with applied conservation: a synthesis and guide to implementation. AoB Plants 7: plv076.Google Scholar
Kaiser-Bunbury, C. N., Cuthbert, H., Fox, R., Birch, D. et al. (2014). Invasion of yellow crazy ant Anoplolepis gracilipes in a Seychelles UNESCO palm forest. Neobiota 22: 43–57.CrossRefGoogle Scholar
Kaiser-Bunbury, C. N., Traveset, A. & Hansen, D. M.. (2010). Conservation and restoration of plant-animal mutualisms on oceanic islands. Perspectives in Plant Ecology Evolution and Systematics 12: 131–143.Google Scholar
Kaiser-Bunbury, C. N., Valentin, T., Mougal, J., Matatiken, D. et al. (2011). The tolerance of island plant-pollinator networks to alien plants. Journal of Ecology 99: 202–213.Google Scholar
Kalinganire, A., Harwood, C. E., Slee, M. U. & Simons, A. J.. (2001). Pollination and fruit-set of Grevillea robusta in western Kenya. Austral Ecology 26: 637–648.Google Scholar
Karnauskas, K. B., Donnelly, J. P. & Anchukaitis, K. J.. (2016). Future freshwater stress for island populations. Nature Climate Change: doi:10.1038/nclimate2987.Google Scholar
Kato, M. & Kawakita, A.. (2004). Plant-pollinator interactions in New Caledonia influenced by introduced honey bees. American Journal of Botany 91: 1814–1827.Google Scholar
Kato, M., Shibata, A. & Yasui, T.. (1999). Impact of introduced honeybees, Apis mellifera, upon native bee communities in the Bonin (Ogasawara) Islands. Research of Population Ecology 41: 217–228.Google Scholar
Kier, G., Kreft, H., Lee, T. M., Jetz, W. et al. (2009). A global assessment of endemism and species richness across island and mainland regions. Proceedings of the National Academy of Sciences 106: 9322–9327.Google Scholar
Knudsen, J. T., Eriksson, R., Gershenzon, J. & Stahl, B.. (2006). Diversity and distribution of floral scent. Botanical Review 72: 1–120.CrossRefGoogle Scholar
Kreft, H., Jetz, W., Mutke, J., Kier, G. et al. (2008). Global diversity of island floras from a macroecological perspective. Ecology Letters 11: 116–127.Google Scholar
Kruckeberg, A. R. & Rabinowitz, D.. (1985). Biological aspects of endemism in higher plants. Annual Review of Ecology and Systematics 16: 447–479.Google Scholar
Krushelnycky, P. D. & Gillespie, R. G.. (2008). Compositional and functional stability of arthropod communities in the face of ant invasions. Ecological Applications 18: 1547–1562.Google Scholar
Krushelnycky, P. D., Holway, D. & LeBrun, E. G.. (2010). Invasion process and causes of success. In Lach, L., Parr, C. L. & Abbott, K. L., eds. Ant ecology. Oxford: Oxford University Press, pp. 115–136.Google Scholar
Krushelnycky, P. D., Loope, L. L. & Reimer, N. J.. (2005). The ecology, policy, and management of ants in Hawaii. Proceedings of the Hawaiian Entomological Society 37: 1–25.Google Scholar
Lach, L. (2008a). Argentine ants displace floral arthropods in a biodiversity hotspot. Diversity and Distributions 14: 281–290.Google Scholar
Lach, L. (2008b). Floral visitation patterns of two invasive ant species and their effects on other hymenopteran visitors. Ecological Entomology 33: 155–160.Google Scholar
Lach, L & Hooper-Bui, L. M.. (2010). Consequences of ant invasions. In Lach, L., Parr, C. L. & Abbott, K. L., eds. Ant ecology. Oxford: Oxford University Press, pp. 261–286.Google Scholar
Langkilde, T. (2009). Invasive fire ants alter behavior and morphology of native lizards. Ecology 90: 208–217.Google Scholar
LeBrun, E. G., Jones, N. T. & Gilbert, L. E.. (2014). Chemical warfare among invaders: a detoxification interaction facilitates an ant invasion. Science 343: 1014–1017.Google Scholar
Llusia, J., Penuelas, J., Sardans, J., Owen, S. M. et al. (2010). Measurement of volatile terpene emissions in 70 dominant vascular plant species in Hawaii: aliens emit more than natives. Global Ecology and Biogeography 19: 863–874.Google Scholar
Lord, J. M. (2015). Patterns in floral traits and plant breeding systems on Southern Ocean Islands. AoB Plants 7.Google Scholar
Lubin, Y. D. (1984). Changes in the native fauna of the Galapagos Islands following invasion by the little red fire ant, Wasmannia auropunctata. Biological Journal of the Linnean Society 21: 229–242.CrossRefGoogle Scholar
MacArthur, R. H. & Wilson, E. O.. (1967). The theory of island biogeography. Princeton: Princeton University Press.Google Scholar
Magnacca, K. N. (2007). Conservation status of the endemic bees of Hawai’i, Hylaeus (Nesoprosopis) (Hymenoptera: Colletidae). Pacific Science 61: 173–190.Google Scholar
McGlynn, T. P. (1999). The worldwide transfer of ants: geographical distribution and ecological invasions. Journal of Biogeography 26: 535–548.Google Scholar
Medeiros, A. C., Loope, L. L. & Cole, F. R.. (1986). Distribution of ants and their effects on endemic biota of Haleakala and Hawaii Volcanoes National Park: a preliminary assessment. In Smith, C. W. & Stone, C. P., eds. Proceedings 6th conference in natural sciences. Hawaii Volcanoes National Park. Honolulu. Honolulu, HI: University of Hawaii, pp. 39–52.Google Scholar
Medina, F. M., Bonnaud, E., Vidal, E., Tershy, B. R. et al. (2011). A global review of the impacts of invasive cats on island endangered vertebrates. Global Change Biology 17: 3503–3510.Google Scholar
Moller, H. (1996). Lessons for invasion theory from social insects. Biological Conservation 78: 125–142.Google Scholar
Mooney, H. A., Mack, R. N., McNeely, J. A., Neville, L. E. et al. (eds.) (2005). Invasive alien species. Washington, Covelo, London: Island Press.Google Scholar
Morrison, L. W. 2012. Biological control of Solenopsis fire ants by Pseudacteon parasitoids: theory and practice. Psyche: A Journal of Entomology : 2012: Article ID 424817, http://dx.doi.org/10.1155/2012/424817.Google Scholar
Myers, N., Mittermeier, R. A., Mittermeier, C. G., da Fonseca, G. A. B. et al. (2000). Biodiversity hotspots for conservation priorities. Nature 403: 853–858.Google Scholar
Ness, J. H. (2006). A mutualism’s indirect costs: the most aggressive plant bodyguards also deter pollinators. Oikos 113: 506–514.Google Scholar
Ness, J. H. & Bronstein, J. L.. (2004). The effects of invasive ants on prospective ant mutualists. Biological Invasions 6: 445–461.Google Scholar
Newstrom, L. & Robertson, A.. (2005). Progress in understanding pollination systems in New Zealand. New Zealand Journal of Botany 43: 1–59.Google Scholar
O’Dowd, D. J., Green, P. T. & Lake, P. S.. (2003). Invasional ‘meltdown’ on an oceanic island. Ecology Letters 6: 812–817.Google Scholar
Philipp, M., Bocher, J., iegismund, H. R. & Nielsen, L. R.. (2006). Structure of a plant-pollinator network on a pahoehoe lava desert of the Galapagos Islands. Ecography 29: 531–540.Google Scholar
Quilichini, A. & Debussche, M.. (2000). Seed dispersal and germination patternsin a rare Mediterranean island endemic (Anchusa crispa Viv., Boraginaceae). Acta Oecologica 21: 303–313.Google Scholar
Rambuda, T. D. & Johnson, S. D.. (2004). Breeding systems of invasive alien plants in South Africa: does Baker’s rule apply? Diversity & Distributions 10: 409–416.Google Scholar
Rodriguez-Girones, M. A., Gonzalvez, F. G., Llandres, A. L., Corlett, R. T. et al. (2013). Possible role of weaver ants, Oecophylla smaragdina, in shaping plant-pollinator interactions in South-East Asia. Journal of Ecology 101: 1000–1006.Google Scholar
Sakai, A. K., Wagner, W. L., Ferguson, D. M. & Herbst, D. R.. (1995). Biogeographical and ecological correlates of dioecy in the Hawaiian flora. Ecology 76: 2530–2543.Google Scholar
Sarnat, E. M. & Economo, E. P.. (2012). The ants of Fiji. Berkeley: University of California Press.Google Scholar
Simberloff, D. & Gibbons, L.. (2004). Now you see them, now you don’t! – population crashes of established introduced species Biological Invasions 6: 161–172.Google Scholar
Stang, M., Klinkhamer, P. G. & Van Der Meijden, E.. (2006). Size constraints and flower abundance determine the number of interactions in a plant-flower visitor web. Oikos 112: 111–121.Google Scholar
Taylor, C. M. & Hastings, A.. (2005). Allee effects in biological invasions. Ecology Letters 8: 895–908.Google Scholar
Traveset, A. & Richardson, D. M.. (2006). Biological invasions as disruptors of plant reproductive mutualisms. Trends in Ecology & Evolution 21: 208–216.Google Scholar
Tsuji, K., Hasyim, A., Harlion, & Nakamura, K.. (2004). Asian weaver ants, Oecophylla smaragdina, and their repelling of pollinators. Ecological Research 19: 669–673.Google Scholar
Tsutsui, N. D. & Suarez, A. V.. 2003. The colony structure and population biology of invasive ants. Conservation Biology 17: 48–58.Google Scholar
Vogel, V., Pederson, J. S., d’Ettorre, P., Lehmann, L. et al. (2009). Dynamics and genetic structure of Argentine ant supercolonies in their native range. Evolution 63: 1627–1639.Google Scholar
Vogel, V., Pederson, J. S., Giraud, T., Krieger, M. et al. (2010). The worldwide expansion of the Argentine ant. Diversity and Distributions 16: 170–186.Google Scholar
Webb, C. J. & Kelly, D.. (1993). The reproductive biology of the New Zealand flora. Trends in Ecology & Evolution 8: 442–447.Google Scholar
Whittaker, R. J. & Fernández-Palacios, J. M.. (2007). Island biogeography: ecology, evolution, and conservation. Oxford: Oxford University Press.Google Scholar
Willmer, P. G., Nuttman, C. V., Raine, N. E., Stone, G. N. et al. (2009). Floral volatiles controlling ant behaviour. Functional Ecology 23: 888–900.Google Scholar
Wilson, E. O. (1961). The nature of the taxon cycle in the Malanesian ant fauna. The American Naturalist 95: 169–193.Google Scholar
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