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Effects of canopy gap size on recruitment and invasion of the non-indigenous Rubus alceifolius in lowland tropical rain forest on Réunion

Published online by Cambridge University Press:  01 May 2008

Stéphane Baret ,
Laurent Cournac ,
Christophe Thébaud ,
Peter Edwards  and
Dominique Strasberg
Stéphane Baret*
Affiliation:
Peuplements Végétaux et Bioagresseurs en Milieu Tropical, UMR C53 CIRAD/Université, 7 chemin de l'Irat, Ligne Paradis, 97410 Saint-Pierre, la Réunion Conservatoire Botanique National de Mascarin, 2 rue du Père Georges F-97436 Saint-Leu, la Réunion, France
Laurent Cournac
Affiliation:
CEA Cadarache, DSV, IBEB, Laboratoire de Bioénergétique et Biotechnologie des Bactéries et Microalgues, UMR 6191, CEA, CNRS, Université de la Méditerranée, Saint-Paul-lez-Durance, F-13108 France
Christophe Thébaud
Affiliation:
UMR 5174 CNRS/UPS ‘Evolution & Diversité Biologique’, Bât. 4R3-B2, 118 route de Narbonne, 31062 Toulouse Cedex 4 France
Peter Edwards
Affiliation:
Institute of Integrative Biology, Swiss Federal Institute of Technology, Universitätsstrasse 16, ETH Zentrum, CHN, 8092 Zürich, Switzerland
Dominique Strasberg
Affiliation:
Peuplements Végétaux et Bioagresseurs en Milieu Tropical, UMR C53 CIRAD/Université, 7 chemin de l'Irat, Ligne Paradis, 97410 Saint-Pierre, la Réunion
*
1Corresponding author. Email: [email protected]
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Abstract:

An important challenge of invasion biology is to understand how interactions between species traits and ecosystem properties enable alien species to become invasive at particular locations. We investigated how gap dynamics in a tropical rain forest on the island of Réunion affected the invasiveness of alien plants. In the 12 000-m2 study area, alien plants occupied 24.9% of the area of gaps, which represented 5.62% of the forest area, but only 0.8% of the understorey area. The most abundant invasive species was Rubus alceifolius, which formed dense, monospecific stands in the largest gaps (> 25 m2). Although plants could persist in the shade, a germination experiment revealed that canopy openings were essential for seedling establishment. A cyclone that struck the study area in 2002 caused a temporary thinning of the canopy, increasing light levels to above the threshold needed for germination of R. alceifolius and also stimulating the growth of established plants. We conclude that the ability of this and other alien species to colonize intact lowland tropical rain forest is strongly influenced by the prevailing gap dynamics. Because gaps are also essential for the regeneration of many native trees in our study area, there is a real danger of the forest being progressively degraded by alien plants. There are no simple solutions to controlling species such as Rubus alceifolius, but efforts should be focused mainly upon the larger gaps where the species are most invasive.

Keywords

canopy heterogeneitycyclonedisturbanceIndian OceaninvasioninvasibilityinvasivenessLeaf Area IndexMascarene archipelago
Type
Research Article
Information
Journal of Tropical Ecology , Volume 24 , Issue 3 , May 2008 , pp. 337 - 345
Copyright
Copyright © Cambridge University Press 2008

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References

LITERATURE CITED

ALPERT, P., BONE, E. & HOLZAPFEL, C. 2000. Invasiveness, invasibility and the role of environmental stress in the spread of non-native plants. Perspectives in Plant Ecology 3:5266.CrossRefGoogle Scholar
AMOR, R. L. 1974. Ecology and control of blackberry (Rubus fruticosus L. agg.). II Reproduction. Weed Research 14:231238.Google Scholar
AMSELLEM, L. 2000. Comparaison entre aires d'origine et d'introduction de quelques traits biologiques chez Rubus alceifolius Poir. (Rosaceae), plante envahissante dans les îles de l'Océan Indien. PhD thesis, University of Montpellier II, France.Google Scholar
BACHELERY, P., BLUM, P. A., CHEMINEE, J. L., CHEVALLIER, L., GAULON, R., GIRARDIN, N., JUAPART, C., LALANNE, F., LE MOUEL, J. L., RUEGG, J. C. & VINCENT, P. 1982. Eruption at Le Piton de la Fournaise volcano on 3 February 1981. Nature 297:395397.CrossRefGoogle Scholar
BARET, S. & STRASBERG, D. 2005. The effects of opening trails on exotic plant invasion in protected areas on La Réunion Island (Mascarene archipelago, Indian Ocean). Revue d'Ecologie (Terre et Vie) 60:325332.Google Scholar
BARET, S., NICOLINI, E., LE BOURGEOIS, T. & STRASBERG, D. 2003a. Developmental patterns of the invasive bramble (Rubus alceifolius Poiret, Rosaceae) in Réunion Island: an architectural and morphometric analysis. Annals of Botany (London) 91:3948.Google Scholar
BARET, S., NICOLINI, E., HUMEAU, L., LE BOURGEOIS, T. & STRASBERG, D. 2003b. Use of architectural and morphometric analysis to predict the flowering pattern of the invasive Rubus on Réunion island (Indian Ocean). Canadian Journal of Botany 81:12931301.Google Scholar
BARET, S., MAURICE, S., LE BOURGEOIS, T. & STRASBERG, D. 2004. Altitudinal variation in fertility and vegetative growth in the invasive plant Rubus alceifolius Poiret (Rosaceae), on Réunion island. Plant Ecology 172:265273.Google Scholar
BARET, S., LE BOURGEOIS, T. & STRASBERG, D. 2005a. Comment Rubus alceifolius, une espèce exotique envahissante, pourrait-elle progressivement coloniser la totalité d'une forêt tropicale humide? Canadian Journal of Botany 83:219226.Google Scholar
BARET, S., RADJASSEGARANE, S., LE BOURGEOIS, T. & STRASBERG, D. 2005b. Does the growth rate of different reproductive modes of an introduced plant cause invasiveness? International Journal of Botany 1:511.CrossRefGoogle Scholar
BARET, S., ROUGET, M., RICHARDSON, D. M., LAVERGNE, C., EGOH, B., DUPONT, J. & STRASBERG, D. 2006. Current distribution and potential extent of the most invasive alien plant species on La Réunion (Indian Ocean, Mascarene islands). Austral Ecology 31:747758.Google Scholar
BELLINGHAM, P. J., TANNER, E. V. J. & HEALEY, J. R. 1994. Sprouting of trees in Jamaican montane forests after a hurricane. Journal of Ecology 82:747758.Google Scholar
BELLINGHAM, P. J., TANNER, E. V. J. & HEALEY, J. R. 1995. Damage and responsiveness of Jamaican tree species after disturbance by hurricane. Ecology 76:25622580.Google Scholar
BELLINGHAM, P. J., TANNER, E. V. J., RICH, P. M. & GOODLAND, T. C. R. 1996. Changes in light below the canopy of a Jamaican montane rain forest after hurricane. Journal of Tropical Ecology 12:699722.Google Scholar
BOOSE, E. R., FOSTER, D. R. & FLUET, M. 1994. Hurricane impacts to tropical and temperate forest landscapes. Ecological Monograph 64:369432.Google Scholar
BORY DE SAINT-VINCENT, J.-B.-G.-M. 1804. Voyage dans les quatre principales îles des mers d'Afrique: fait par ordre du gouvernement pendant les années neuf et dix de la république (1801–1802), Tome II (3 vols). Buisson, Paris. 431 pp.Google Scholar
BROKAW, N. V. L. 1982. The definition of treefall gap and its effect on measures of forest dynamics. Biotropica 14:158160.CrossRefGoogle Scholar
BROKAW, N. V. L. 1985. Gap-phase regeneration in a tropical forest. Ecology 66:682687.Google Scholar
BROKAW, N. V. L. & WALKER, L. R. 1991. Summary of the effects of Caribbean hurricanes on vegetation. Biotropica 23:442447.Google Scholar
CADET, T. 1977. La végétation de l'île de La Réunion. PhD thesis, University of Aix-Marseille, France.Google Scholar
COURNAC, L., DUBOIS, M. A., CHAVE, J. & RIÉRA, B. 2002. Fast determination of light availability and leaf area index in tropical forests. Journal of Tropical Ecology 18:295302.CrossRefGoogle Scholar
CRAWLEY, M. J. 1987. What makes a community invasible? Pp. 429453 in Gray, A. J., Crawley, M. J. & Edwards, P. J. (eds). Colonization, succession, and stability. Blackwell Scientific Publications, Oxford.Google Scholar
D'ANTONIO, C. M. 1993. Mechanisms controlling invasion of coastal plant communities by the alien succulent Carpobrotus edulis. Ecology 74:8395.Google Scholar
D'ANTONIO, C. M. & KARK, S. 2002. Impacts and extent of biotic invasions in terrestrial ecosystems. Trends in Ecology and Evolution 17:202204.Google Scholar
DAVIS, M. A., PERGL, J., TRUSCOTT, A.-M., KOLLMANN, J., BAKKER, J. P., DOMENECH, R., PRACH, K., PRIEUR-RICHARD, A.-H., VEENEKLAAS, R. M., PYŠEK, P., DEL MORAL, R., HOBBS, R. J., COLLINS, S. L., PICKETT, S. T. A. & REICH, P. B. 2005. Vegetation change: a reunifying concept in plant ecology. Perspectives in Plant Ecology, Evolution and Systematics 7:6976.Google Scholar
DE CORDEMOY, E. J. 1895. Flore de l'île de la Réunion. Paul Klincksieck, Paris, 574 p.Google Scholar
DENSLOW, J. S. 1980. Gap partitioning among tropical rainforest trees. Biotropica 12 (Suppl.):4755.CrossRefGoogle Scholar
DENSLOW, J. S. 1987. Tropical rainforest gaps and tree species diversity. Annual Review of Ecology and Systematics 18:431451.Google Scholar
EVERHAM, E. M. & BROKAW, N. V. L. 1996. Forest damage and recovery from catastrophic wind. Botanical Review 62:113173.Google Scholar
EPPSTEIN, M. J. & MOLOFSKY, J. 2007. Invasiveness in plant communities with feedbacks. Ecology Letters 10:253263.Google Scholar
FERNANDEZ, D. S. & FETCHER, N. 1991. Changes in light availability following Hurricane Hugo in a subtropical montane forest in Puerto Rico. Biotropica 23:393399.Google Scholar
FINE, P. V. A. 2002. The invasibility of tropical forests by exotic plants. Journal of Tropical Ecology 18:687705.Google Scholar
FOSBERG, F. R. 1983. The human factor in the biogeography of oceanic islands. Comptes Rendus sommaires des Séances de la Société de Biogéographique 59:147190.Google Scholar
FRECKLETON, R. P. 2004. The problems of prediction and scale in applied ecology: the example of fire as management tool. Journal of Applied Ecology 41:599603.Google Scholar
FRITTS, T. H. & RODDA, G. H. 1998. The role of introduced species in the degradation of island ecosystems. Annual Review of Ecology and Systematics 29:113140.Google Scholar
GARWOOD, N. C. 1983. Seed germination in a seasonal tropical forest in Panama: a community study. Ecological Monograph 53:159181.CrossRefGoogle Scholar
GOODWIN, B. J., MCALLISTER, A. J. & FAHRIG, L. 1999. Predicting invasiveness of plant species based on biological information. Conservation Biology 13:422426.Google Scholar
HARRINGTON, R. A., FOWNES, J. H., SCOWCROFT, P. G. & VANN, C. S. 1997. Impact of Hurricane Iniki on native Hawaiian Acacia koa forests: damage and two-year recovery. Journal of Tropical Ecology 13:539558.Google Scholar
HOBBS, R. & HUMPHRIES, S. E. 1995. An integrated approach to the ecology and the management of plant invasions. Conservation Biology 9:761770.CrossRefGoogle Scholar
HORVITZ, C., PASCARELLA, J., MCMANN, S., FREEDMAN, A. & HOFSETTER, R. H. 1998. Functional roles of invasive non-indigenous plants in hurricane-affected subtropical hardwood. Ecological Application 8:947974.Google Scholar
HUBBELL, S. P. & FOSTER, R. B. 1986. Canopy gaps and the dynamics of a Neotropical forest. Pp. 7796 in Crawley, M. J. (ed.). Plant ecology. Blackwell Scientific Publications, Oxford.Google Scholar
KELL, S. 1997. Alien plant invasions in Rodrigues island, Indian Ocean. Aliens Newsletter 5:1314.Google Scholar
KING, S. E. & GRACE, J. B. 2000. The effects of gap size and disturbance type on invasion of wet pine savanna by cogongrass, Imperata cylindrica (Poaceae). American Journal of Botany 87:12791286.Google Scholar
KOIKE, F. & SYAHBUDDIN, 1993. Canopy structure of a tropical rain forest and the nature of an unstratified upper layer. Functional Ecology 7:230235.Google Scholar
KOLAR, C. S. & LODGE, D. M. 2001. Progress in invasion biology: predicting invaders. Trends in Ecology and Evolution 16:199204.Google Scholar
LAVERGNE, C., RAMEAU, J. C. & FIGIER, J. 1999. The invasive woody weed Ligustrum robustum subsp. walkeri threatens native forests on La Réunion. Biological Invasion 1:377392.Google Scholar
LEE, R. 1978. Forest microclimatology. Columbia University Press, New York. 276 pp.Google Scholar
LEVINE, J. M. 2000. Species diversity and biological invasions: relating local process to community pattern. Science 288:852854.Google Scholar
LIEBERMAN, M., LIEBERMAN, D. & PERALTA, R. 1989. Forests are not just Swiss cheese: canopy stereogeometry of non-gaps in tropical forests. Ecology 70:550552.Google Scholar
LORENCE, D. H. & SUSSMAN, R. W. 1986. Exotic species invasion into Mauritius wet forest remnants. Journal of Tropical Ecology 2:147162.Google Scholar
LORENCE, D. H. & SUSSMAN, R. W. 1988. Diversity, density and invasion in a Mauritius wet forest. Monographs in Systematic Botany from the Missouri Botanical Garden 25:187204.Google Scholar
LUGO, A. E., APPLEFIELD, M., POOL, D. J. & MCDONALD, R. B. 1983. The impact of Hurricane David on the forests of Dominica. Canadian Journal of Forest Research 13:201211.Google Scholar
MACDONALD, I. A. W., THÉBAUD, C., STRAHM, W. A. & STRASBERG, D. 1991. Effects of alien plant invasions on native vegetation remnants on La Réunion (Mascarene Islands, Indian Ocean). Environmental Conservation 18:5161.Google Scholar
MARKS, P. L. 1983. On the origin of field plants of the northeatern United States. American Naturalist 122:210228.Google Scholar
MUELLER-DOMBOIS, D. & LOOPE, L. L. 1990. Some unique ecological aspects of oceanic island ecosystems. Monographs in Systematic Botany from the Missouri Botanical Garden 32:2128.Google Scholar
MYERS, N., MITTERMEIER, R. A., MITTERMEIER, C. G., DA FONSECA, G. A. B. & KENT, J. 2000. Biodiversity hotspots conservation priorities. Nature 403:853858.Google Scholar
OTT, R. A. & JUDAY, G. P. 2002. Canopy gap characteristics and their implications for management in the temperate rainforests of southeast Alaska. Forest Ecology and Management 159:271291.Google Scholar
PIERSON, E. A. & MACK, R. N. 1990. The population biology of Bromus tectorum in forests: effect of disturbance, grazing and litter on seedling establishment and reproduction. Oecologia 84:526533.Google Scholar
PYŠEK, P., RICHARDSON, D. M. & WILLIAMSON, M. 2004. Predicting and explaining plant invasions through analysis of source area floras: some critical consideration. Diversity and Distributions 10:179187.Google Scholar
RESTREPO, C. & VITOUSEK, P. M. 2001. Landslides, alien species, and the diversity of a Hawaiian montane mesic ecosystem. Biotropica 33:409420.Google Scholar
REJMÁNEK, M. & RICHARDSON, D. M. 1996. What attributes make some plant species more invasive? Ecology 77:16551661.Google Scholar
RICHARDSON, D. M., PYŠEK, P., REJMÁNEK, M., BARBOUR, M. G., PANETTA, F. D. & WEST, C. J. 2000. Naturalization and invasion of alien plants – concepts and definitions. Diversity and Distribution 6:93107.Google Scholar
RUNKLE, J. R. 1982. Patterns of disturbance in some old-growth mesic forests of eastern North America. Ecology 63:15331546.Google Scholar
SCHNITZER, S. A., DALLING, J. W. & CARSON, W. P. 2000. The impact of lianas on tree regeneration in tropical forest canopy gaps: evidence for an alternative pathway of gap-phase regeneration. Journal of Ecology 88:655666.Google Scholar
SCOTT, D. H. & DRAPER, D. A. 1967. Light in relation to seed germination of Blueberries, Strawberries, and Rubus. HortScience 2:107108.Google Scholar
SMITH, M. D. & KNAPP, A. K. 1999. Exotic plant species in a C4-dominated grassland: invasibility, disturbance and community structure. Oecologia 120:605612.Google Scholar
STRASBERG, D. 1995. Processus d'invasion par les plantes introduites à La Réunion et dynamique de la végétation sur les coulées volcaniques. Ecologie 26:169180.Google Scholar
STRASBERG, D., ROUGET, M., RICHARDSON, D. M., BARET, S., DUPONT, J. & COWLING, R. M. 2005. An assessment of habitat diversity, transformation and threats to biodiversity on Reunion Island (Mascarene Islands, Indian Ocean) as a basis for conservation planning. Biodiversity and Conservation 14:30153032.Google Scholar
SUDING, K. N. & GOLDBERG, D. 2001. Do disturbances alter competitive hierarchies? Mechanisms of change following gap creation. Ecology 82:21332149.Google Scholar
TANNER, E. V. J., KAPOS, V. & HEALEY, J. R. 1991. Hurricane effects on forest ecosystems in the Caribbean. Biotropica 23:513521.Google Scholar
THÉBAUD, C., FINZI, A. C., AFFRE, L., DEBUSSCHE, M. & ESCARRE, J. 1996. Assessing why two introduced Conyza differ in their ability to invade Mediterranean old fields. Ecology 77:791804.Google Scholar
TURTON, S. M. 1992. Understorey light environments in a north-east Australian rain forest before and after a tropical cyclone. Journal of Tropical Ecology 8:241252.Google Scholar
VANDERMEER, J., MALLONA, M. A., BOUCHER, D., YIH, K. & PERFECTO, I. 1995. Three years of ingrowth following catastrophic hurricane damage on the Caribbean coast of Nicaragua: evidence in support of the direct generation hypothesis. Journal of Tropical Ecology 11:465471.Google Scholar
VITOUSEK, P. 1988. Diversity and biological invasions on oceanic islands. Pp. 181189 in Wilson, E. O. (ed.). Biodiversity. National Academy Press, Washington DC.Google Scholar
VITOUSEK, P. M., D'ANTONIO, C. M., LOOPE, L. L. & WESTBROOKS, R. 1996. Biological invasions as global environmental change. American Scientist 84:218228.Google Scholar
WHITMORE, T. C. 1989. Canopy gaps and the two major groups of forest trees. Ecology 70:536538.Google Scholar
WILLIAMSON, M. H. & FITTER, A. 1996. The characters of successful invaders. Biological Conservation 78:163170.Google Scholar