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What pollinates Lantana camara in the mountains of Costa Rica?

Published online by Cambridge University Press:  12 April 2012

Christopher A. Hamm*
Affiliation:
Department of Entomology, Michigan State University, 243 Natural Sciences, East Lansing, Michigan 48824, USA; Program in Ecology and Evolutionary Biology, Michigan State University, Michigan, USA
*

Extract

Lantana camara L. (Verbenaceae) is a shrub of Neotropical origin that has spread to at least 60 countries (Day et al. 2003), and its ability to rapidly occupy disturbed habitat has led to it being named one of the ten worst weeds on the planet (Cronk & Fuller 1995, Sharma et al. 2005). A number of traits may have contributed to its success as an invasive species. For example, L. camara increases the available soil nitrogen in otherwise nitrogen-poor ecosystems (Sharma & Raghubanshi 2009), it is extremely resilient to disturbance (Gentle & Guggin 1997a, Hiremath & Sundram 2005), it is allelopathic to native plants (Achhireddy & Singh 1984, Gentle & Duggin 1997b) and its fruits are dispersed by a variety of birds (Mandon-Dalger et al. 2004, Swarbrick et al. 1998). A potentially unappreciated aspect of L. camara biology that may also contribute to its invasiveness relates to pollination ecology.

Type
Short Communication
Copyright
Copyright © Cambridge University Press 2012

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References

LITERATURE CITED

ACHHIREDDY, N. R. & SINGH, M. 1984. Allelopathic effects of lantana (Lantana camara L.). Weed Science 32:757761.CrossRefGoogle Scholar
ADLER, L. S. & IRWIN, R. E. 2006. Comparison of pollen transfer dynamics by multiple floral visitors: experiments with pollen and fluorescent dye. Annals of Botany (London) 97:141150.CrossRefGoogle ScholarPubMed
BARROWS, E. 1976. Nectar robbing and pollination of Lantana camara (Verbenaceae). Biotropica 8:132135.CrossRefGoogle Scholar
COX, P. A. 1991. Abiotic pollination: an evolutionary escape for animal-pollinated angiosperms [and discussion]. Philosophical Transactions of the Royal Society B: Biological Sciences 333:217224.Google Scholar
CRONK, Q. C. B. & FULLER, J. L. 1995. Plant invaders. Chapman & Hall, London. 241 pp.Google Scholar
DAY, M. D., WILEY, C. J., PLAYFORD, J. & ZALUCKI, M. P. 2003. Lantana: current management status and future prospects. Australian Centre for International Agricultural Research, Canberra. 128 pp.Google Scholar
DRONAMRAJU, K. R. 1960. Selective visits of butterflies to flowers: a possible factor in sympatric speciation. Nature 186:178.CrossRefGoogle Scholar
FAEGRI, K. & VAN DER PIJL, L. 1971. The principles of pollination ecology. (Second edition). Pergamon Press, Oxford. 242 pp.Google Scholar
FENSTER, C. B., HASSLER, C. L. & DUDASH, M. R. 1996. Fluorescent dye particles are good pollen analogs for hummingbird-pollinated Silene virginica (Caryophyllaceae). Canadian Journal of Botany 74:189193.CrossRefGoogle Scholar
FISHBEIN, M. & VENABLE, D. 1996. Diversity and temporal change in the effective pollinators of Asclepias tuberosa. Ecology 77:10611073.CrossRefGoogle Scholar
GENTLE, C. & DUGGIN, J. 1997a. Lantana camara L. invasions in dry rainforest–open forest ecotones: the role of disturbances associated with fire and cattle grazing. Australian Journal of Ecology 22:298306.CrossRefGoogle Scholar
GENTLE, C. & DUGGIN, J. 1997b. Allelopathy as a competitive strategy in persistent thickets of Lantana camara L. in three Australian forest communities. Plant Ecology 132:8595.CrossRefGoogle Scholar
GOULSON, D. & DERWENT, L. C. 2004. Synergistic interactions between an exotic honeybee and an exotic weed: pollination of Lantana camara in Australia. Weed Research 44:195202.CrossRefGoogle Scholar
HESSING, M. 1988. Geitonogamous pollination and its consequences in Geranium caespitosum. American Journal of Botany 75:13241333.CrossRefGoogle Scholar
HILJE, L. 1985. Insectos visitadores y eficiencia reproductiva de Lantana camara L. (Verbenaceae). Brenesia 23:293300.Google Scholar
HIREMATH, A. J. & SUNDRAM, B. 2005. The fire–Lantana cycle hypothesis in Indian forests. Conservation and Society 3:2642.Google Scholar
JANZEN, D. H. 1983. Costa Rica natural history. University of Chicago Press, Chicago. 823 pp.CrossRefGoogle Scholar
KAY, K. & SCHEMSKE, D. 2003. Pollinator assemblages and visitation rates for 11 species of neotropical Costus (Costaceae). Biotropica 35:198207.Google Scholar
LEDUC, N., DOUGLAS, G. C. & MONNIER, M. 1992. Methods for the non-stigmatic pollination in Trifolium repens (Papilionaceae): seed set with self- and cross-pollinations in vitro. Theoretical and Applied Genetics 83:912918.CrossRefGoogle ScholarPubMed
LEVIN, D. & BERUBE, D. 1972. Phlox and colias: the efficiency of a pollination system. Evolution 26:242250.Google ScholarPubMed
LLOYD, D. & SCHOEN, D. 1992. Self- and cross-fertilization in plants. I. Functional dimensions. International Journal of Plant Sciences 153:358369.CrossRefGoogle Scholar
MANDON-DALGER, I., CLERGEAU, P., TASSIN, J., RIVIERA, J. N. & GATTI, S. 2004. Relationships between alien plants and an alien bird species on Reunion Island. Journal of Tropical Ecology 20:635642.CrossRefGoogle Scholar
MATHER, G. & MOHAN RAM, H. Y. 1978. Significance of petal colour in thrips-pollinated Lantana camara L. Annals of Botany 42:14731476.CrossRefGoogle Scholar
MOHAN RAM, H. Y. & MATHUR, G. 1984. Flower colour changes in Lantana camara. Journal of Experimental Botany 35:16561662.Google Scholar
SAHLI, H. F. & CONNER, J. K. 2007. Visitation, effectiveness, and efficiency of 15 genera of visitors to wild radish, Raphanus raphanistrum (Brassicaceae). American Journal of Botany 94:203209.CrossRefGoogle ScholarPubMed
SCHEMSKE, D. W. 1976. Pollinator specificity in Lantana camara and L. trifolia (Verbenaceae). Biotropica 8:260264.CrossRefGoogle Scholar
SCHEMSKE, D. W. & BRADSHAW, H. D. 1999. Pollinator preference and the evolution of floral traits in monkeyflowers (Mimulus). Proceedings of the National Academy of Sciences USA 96:1191011915.CrossRefGoogle ScholarPubMed
SCHEMSKE, D. W. & HORVITZ, C. C. 1984. Variation among floral visitors in pollination ability: a precondition for mutualism speciation. Science 225:519521.CrossRefGoogle Scholar
SHARMA, G. P. & RAGHUBANSHI, A. 2009. Lantana invasion alters soil nitrogen pools and processes in the tropical dry deciduous forest of India. Applied Soil Ecology 42:134140.CrossRefGoogle Scholar
SHARMA, G. P., RAGHUBANSHI, A. S. & SINGH, J. S. 2005. Lantana invasion: an overview. Weed Biology and Management 5:157165.CrossRefGoogle Scholar
SWARBRICK, J. T., WILSON, W. W. & HANNAN-JONES, M. A. 1998. Lantana camara L. Pp. 119136 in Panetta, F. D., Groves, R. H. & Shepherd, R. C. H. (eds.). The biology of Australian weeds, Volume 2. R. G. & F. J. Richardson, Melbourne.Google Scholar
WEBSTER, A. D. 1887. Fertilization of Epipactis latifolia. The Botanical Gazette 11:104109.CrossRefGoogle Scholar
WINDER, J. A. 1980. Factors affecting the growth of Lantana in Brazil. Department of Agriculture and Horticulture, University of Reading, UK.Google Scholar