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5 - Trait-mediated indirect interactions, density-mediated indirect interactions, and direct interactions between mammalian and insect herbivores

Published online by Cambridge University Press:  12 August 2009

By
José M. Gómez  and
Adela González-Megías
Edited by
Takayuki Ohgushi ,
Timothy P. Craig  and
Peter W. Price
José M. Gómez
Affiliation:
Universidad de Granada
Adela González-Megías
Affiliation:
Universidad de Granada
Takayuki Ohgushi
Affiliation:
Kyoto University, Japan
Timothy P. Craig
Affiliation:
University of Minnesota, Duluth
Peter W. Price
Affiliation:
Northern Arizona University
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Summary

Introduction

Ecologists have traditionally recognized the consequences that direct interactions between species have on the functioning of ecological communities and on the flow of energy through food webs (Pimm 2002). However, ecological communities are among the most complex natural systems, and thus the interactions between species are far from simple. In this respect, the importance of indirect effects (those effects transmitted from one species to another through one or more intermediate species) as a determinant of the structure and dynamics of ecological communities has been clearly acknowledged only in recent years (Wootton 1994, Abrams 1995, Abrams et al. 1996). Indirect effects are those transmitted from one species to another through one or more intermediate species. These indirect effects can be propagated through food webs as a consequence of changes in the density of the intervening species, a mechanism known as density-mediated indirect interaction (DMII) (Abrams 1995, Werner and Peacor 2003). Nevertheless, indirect effects can also occur through changes in the phenotypes of the interacting organisms, a mechanism known as trait-mediated indirect interaction (TMII) (Werner and Peacor 2003, Schmitz et al. 2004). Although DMIIs have been traditionally considered to be the main source of any variation in ecological communities, ecologists are progressively more conscious of the essential role played by TMIIs (Bolker et al. 2003, Dill et al. 2003, Luttbeg et al. 2003, Trussell et al. 2003, Werner and Peacor 2003; and chapters throughout this volume).

Type
Chapter
Information
Ecological Communities
Plant Mediation in Indirect Interaction Webs
 , pp. 104 - 123
Publisher: Cambridge University Press
Print publication year: 2007

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References

Abensperg-Traun, M., Smith, G. T., Arnold, G. W., and Steven, D. E.. 1996. The effects of habitat fragmentation and livestock grazing on animal communities in remnants of gimlet Eucalyptus salubris woodland in the Western Australian wheat belt. I. Arthropods. Journal of Applied Ecology 33:1281–1301.CrossRefGoogle Scholar
Abrams, P. A. 1995. Implications of dynamically variable traits for identifying, classifying and measuring direct and indirect effects in ecological communities. American Naturalist 146:112–134.CrossRefGoogle Scholar
Abrams, P. A., Menge, B. A., Mittelbach, G. G., Spiller, D. A., and Yodzis, P.. 1996. The role of indirect effects in food webs, pp. 371–395 in Polis, G. and Winemiller, K. (eds.) Food Webs: Dynamics and Structure. New York:Chapman and Hall.Google Scholar
Agrawal, A. A. 1999. Induced plant defense: evolution of induction and adaptive phenotypic plasticity, pp. 251–268 in Agrawal, A. A., Tuzun, S., and Bent, E. (eds.) Inducible Plant Defenses against Pathogens and Herbivores. St. Paul, MN: American Phytopathological Society Press.Google Scholar
Agrawal, A. A. 2000. Benefits and costs of induced plant defense for Lepidium virginicum (Brassicaceae). Ecology 81:1804–1813.CrossRefGoogle Scholar
Agrawal, A. A., and Rutter, M. T.. 1998. Dynamic anti-herbivore defense in ant-plants: the role of induced responses. Oikos 83:227–236.CrossRefGoogle Scholar
Agrawal, A. A., and Zandt, P. A.. 2003. Ecological play in the coevolutionary theatre: genetic and environmental determinants of attack by a specialist weevil on milkweed. Journal of Ecology 91:1049–1059.CrossRefGoogle Scholar
Allcock, K. G., and Hik, D. S.. 2004. Survival, growth, and escape from herbivory are determined by habitat and herbivore species for three Australian woodland plants. Oecologia 138:231–241.CrossRefGoogle ScholarPubMed
Baines, D., Sage, R. B., and Baines, M. M.. 1994. The implications of red deer grazing to ground vegetation and invertebrate communities of Scottish native pinewoods. Journal of Applied Ecology 31:776–783.CrossRefGoogle Scholar
Bestelmeyer, R., and Wiens, J. A.. 1996. The effect of land use on the structure of ground-foraging ant communities in the Argentine Chaco. Ecological Applications 6:1225–1240.CrossRefGoogle Scholar
Bi, J. L., Murphy, J. B., and Felton, G. W.. 1997. Antinutritive and oxidative components as mechanisms of induced resistance in cotton to Helicoverpa zea. Journal of Chemical Ecology 23:97–117.CrossRefGoogle Scholar
Bolker, B., Holyoak, M., Krivan, V., Rowe, L., and Schmitz, O.. 2003. Connecting theoretical and empirical studies of trait-mediated interactions. Ecology 84:1101–1114.CrossRefGoogle Scholar
Brown, J. H., Davidson, D. W., Munger, J. C., and Inouye, R. S.. 1986. Experimental community ecology: the desert granivorous system, pp. 41–61 in Diamond, J. and Case, T. J. (eds.) Community Ecology. New York:Harper and Row.Google Scholar
Carson, W. P., and Root, R. B.. 2000. Herbivory and plant species coexistence: community regulation by an outbreaking phytophagous insect. Ecological Monographs 70:73–99.CrossRefGoogle Scholar
Christensen, K. M., and Whitham, T. G.. 1993. Impact of herbivores on competition between birds and mammals for pinyon pine seeds. Ecology 74:2270–2278.CrossRefGoogle Scholar
Cipollini, D. 2004. Stretching the limits of plasticity: can a plant defend against both competitors and herbivores?Ecology 85:28–37.CrossRefGoogle Scholar
Crawley, M. J. 1983. Herbivory. Oxford, UK: Blackwell Scientific Publications.Google Scholar
Crawley, M. J. 1997. Plant–herbivore dynamics, pp. 401–474 in Crawley, M. J. (ed.) Plant Ecology, 2nd edn. Oxford, UK: Blackwell Scientific Publications.Google Scholar
Crawley, M. J. 2000. Seed predators and plant population dynamics, pp. 167–182 in Fenner, M. (ed.) Seeds: The Ecology of Regeneration in Plant Communities, 2nd edn. Wallingford, UK: CAB International.Google Scholar
Cuartas, P., and García-González, R.. 1992. Quercus ilex browses utilization by Caprini in Sierra de Cazorla and Segura (Spain). Vegetatio 99/100:317–330CrossRefGoogle Scholar
Danell, K., and Bergström, R.. 2002. Mammalian herbivory in terrestrial environments, pp. 107–131 in Herrera, C. M. and Pellmyr, O. (eds.) Plant–Animal Interactions: An Evolutionary Approach. Oxford, UK: Blackwell Science.Google Scholar
Danell, K., and Hus-Danell, K.. 1985. Feeding by insects and hares on birches earlier affected by moose browsing. Oikos 44:75–81.CrossRefGoogle Scholar
Davidson, D. W., Inouye, R. S., and Brown, J. H.. 1984. Granivory in a desert ecosystem: experimental evidence for indirect facilitation of ants by rodents. Ecology 65:1780–1786.CrossRefGoogle Scholar
Davidson, D. W., Samson, D. A., and Inouye, R. S.. 1985. Granivory in the Chihuahuan desert: interactions within and between trophic levels. Ecology 66:486–502.CrossRefGoogle Scholar
Dennis, P., Young, M. R., Howard, C. L., and Gordon, I. J.. 1997. The response of epigeal beetles (Col.: Carabidae, Staphylinidae) to varied grazing regimes on upland Narduus stricta grasslands. Journal of Applied Ecology 34:433–443.CrossRefGoogle Scholar
Denno, R. F., McClure, M. S., and Ott, J. R.. 1995. Interspecific interactions in phytophagous insects: competition reexamined and resurrected. Annual Review of Entomology 40:297–331.CrossRefGoogle Scholar
Denno, R. F., Peterson, M. A., Gratton, C., et al. 2000. Feeding-induced changes in plant quality mediate interspecific competition between sap-feeding herbivores. Ecology 81:1814–1827.CrossRefGoogle Scholar
DeWalt, S. J., Denslow, J. S., and Ickes, K.. 2004. Natural-enemy release facilitates habitat expansion of the invasive tropical shrub Clidemia hirta. Ecology 85:471–483.CrossRefGoogle Scholar
Dill, L. M., Heithaus, M. R., and Walters, C. J.. 2003. Behaviorally mediated indirect interactions in marine communities and their conservation implications. Ecology 84:1151–1157.CrossRefGoogle Scholar
Dolch, R., and Tscharntke, T.. 2000. Defoliation of alders (Alnus glutinosa) affects herbivory by leaf beetles on undamaged neighbours. Oecologia 125:504–511.CrossRefGoogle ScholarPubMed
Elligsen, H., Beinlich, B., and Plachter, H.. 1997. Effects of large-scale cattle grazing on populations of Coenonympha glycerion and Lasiommata megera (Lepidoptera: Satyridae). Journal of Insect Conservation 1:13–23.CrossRefGoogle Scholar
Faeth, S. H. 1992. Interspecific and intraspecific interactions via plant responses to folivory: an experimental field-test. Ecology 73:1802–1813.CrossRefGoogle Scholar
Faeth, S. H., and Wilson, D.. 1997. Induced responses in trees: mediator of interactions among macro- and micro-herbivores? pp. 201–215 in Gange, A. C. and Brown, V. K. (eds.) Multitrophic Interactions in Terrestrial Systems. Oxford, UK: Blackwell Science.Google Scholar
Ferrenberg, S. M., and Denno, R. F.. 2003. Competition as a factor underlying the abundance of an uncommon phytophagous insect, the salt-marsh planthopper Delphacodes penedetecta. Ecological Entomology 28:58–66.CrossRefGoogle Scholar
Fisher, A. E. I., Hartley, S. E., and Young, M.. 2000. Direct and indirect competitive effects of foliage feeding guilds on the performance of the birch leaf-miner Eriocrania. Journal of Animal Ecology 69:165–176.CrossRefGoogle Scholar
Goheen, J. R., Keesing, F., Allan, B. F., Ogada, D. L., and Ostfeld, R. S.. 2004. Net effects of large mammals on Acacia seedling survival in an African savanna. Ecology 85:1555–1561.CrossRefGoogle Scholar
Gómez, J. M. 2005. Ungulate effect on the performance, abundance and spatial structure of two montane herbs: a 7-yr experimental study. Ecological Monographs 75:231–258.CrossRefGoogle Scholar
Gómez, J. M., and González-Megías, A.. 2002. Asymmetrical interactions between ungulates and phytophagous insects: being different matters. Ecology 83:201–211.CrossRefGoogle Scholar
Gómez, J. M., and Zamora, R.. 2000a. Differential impact of vertebrate and invertebrate herbivores on Hormathophylla spinosa reproductive output. Ecoscience 7:299–306.CrossRefGoogle Scholar
Gómez, J. M., and Zamora, R.. 2000b. Spatial variation in the selective scenarios of Hormathophylla spinosa (Cruciferae). American Naturalist 155:657–668.CrossRefGoogle Scholar
Gómez, J. M., and Zamora, R.. 2002. Thorns as induced mechanical defense in a long-lived shrub (Hormathophylla spinosa, Cruciferae). Ecology 83:885–890.CrossRefGoogle Scholar
González-Megías, A., and Gómez, J. M.. 2003. Consequences of removing a keystone herbivore for the abundance and diversity of arthropods associated with a cruciferous shrub. Ecological Entomology 28:299–308.CrossRefGoogle Scholar
González-Megías, A., Gómez, J. M., and Piñero, F. Sanchez. 2004. Effects of ungulates on epigeal arthropods in Sierra Nevada National Park (southeast Spain). Biodiversity and Conservation 13:733–752.CrossRefGoogle Scholar
Hambäck, P. A., and Beckerman, A. P.. 2003. Herbivory and plant resource competition: a review of two interacting interactions. Oikos 101:26–37.CrossRefGoogle Scholar
Hawkes, C. V., and Sullivan, J. J.. 2001. The impact of herbivory on plants in different resource conditions: a meta-analysis. Ecology 82:2045–2058.CrossRefGoogle Scholar
Hjältén, J., and Price, P. W.. 1997. Can plants gain protection from herbivory by association with unpalatable neighbours? A field experiment in a willow–sawfly system. Oikos 78:317–322.CrossRefGoogle Scholar
Herms, D. A., and Mattson, W. J.. 1992. The dilemma of plants: to grow or defend. Quarterly Review of Biology 67:283–335.CrossRefGoogle Scholar
Hochberg, M. E., and Lawton, J. H.. 1990. Competition between kingdoms. Trends in Ecology and Evolution 5:367–371.CrossRefGoogle ScholarPubMed
Hulme, P. E. 1994. Seedling herbivory in grassland: relative impact of vertebrate and invertebrate herbivores. Journal of Ecology 82:873–880.CrossRefGoogle Scholar
Hulme, P. E. 1996. Herbivores and the performance of grassland plants: a comparison of arthropod, mollusc, and rodent herbivory. Journal of Ecology 84:43–51.CrossRefGoogle Scholar
Hunter, M. D. 1992. Interactions within herbivore communities mediated by the host plant: the keystone herbivore concept, pp. 287–325 in Hunter, M. D., Ohgushi, T., and Price, P. W. (eds.) Effect of Resource Distribution on Plant–Animal Interactions. San Diego, CA: Academic Press.Google Scholar
Huntzinger, M., Karban, R., Young, T. P., and Palmer, T. M.. 2004. Relaxation of induced indirect defenses of acacias following exclusion of mammalian herbivores. Ecology 85:609–614.CrossRefGoogle Scholar
Inouye, B., and Stinchcombe, J. R.. 2001. Relationships between ecological interaction modifications and diffuse coevolution: similarities, differences, and causal links. Oikos 95:353–360.CrossRefGoogle Scholar
Juenger, T., and Bergelson, J.. 2000. Factors limiting rosette recruitment in scarlet gilia, Ipomopsis aggregata: seed and disturbance limitation. Oecologia 123:358–363.CrossRefGoogle ScholarPubMed
Karban, R., and Baldwin, I. T.. 1997. Induced Responses to Herbivory. Chicago, IL:University of Chicago Press.CrossRefGoogle Scholar
Karban, R., and Myers, J. H.. 1989. Induced plant responses to herbivory. Annual Review of Ecology and Systematics 20:331–348.CrossRefGoogle Scholar
Kleijn, D., and Steiner, T.. 2002. Contrasting effects of grazing and hay cutting on the spatial and genetic population structure of Veratrum album, an unpalatable, long-lived, clonal plant species. Journal of Ecology 90:360–370.CrossRefGoogle Scholar
Kruess, A., and Tscharntke, T.. 2002a. Contrasting responses of plant and insect diversity to variation in grazing intensity. Biological Conservation 106:293–302.CrossRefGoogle Scholar
Kruess, A., and Tscharntke, T.. 2002b. Grazing intensity and the diversity of grasshoppers, butterflies, and trap-nesting bees and wasps. Conservation Biology 16:1570–1580.CrossRefGoogle Scholar
Louda, S. M., and Potvin, M. A.. 1995. Effect of inflorescence-feeding insects on the demography and lifetime fitness of a native plant. Ecology 76:229–245.CrossRefGoogle Scholar
Louda, S. M., and Rodman, J. E.. 1996. Insect herbivory as a major factor in the shade distribution of a native crucifer (Cardamine cordifolia A. Gray, bittercress). Journal of Ecology 84:229–237.CrossRefGoogle Scholar
Lucas, E., Coderre, D., and Brodeur, J.. 1998. Intraguild predation among aphid predators: characterization and influence of extraguild prey density. Ecology 79:1084–1092.CrossRefGoogle Scholar
Luttbeg, B., Rowe, L., and Mangel, M.. 2003. Prey state and experimental design affect relative size of trait- and density-mediated indirect effects. Ecology 84:1140–1150.CrossRefGoogle Scholar
Maron, J. L., and Gardner, S. N.. 2000. Consumer pressure, seed versus safe-site limitation, and plant population dynamics. Oecologia 124:260–269.CrossRefGoogle ScholarPubMed
Maron, J. L., and Simms, E. L.. 2001. Rodent-limited establishment of bush lupine: field experiments on the cumulative effect of granivory. Journal of Ecology 89:578–588.CrossRefGoogle Scholar
Maron, J. L., Combs, J. K., and Louda, S. M.. 2002. Convergent demographic effects of insect attack on related thistles in coastal vs. continental dunes. Ecology 83:3382–3392.CrossRefGoogle Scholar
Marquis, R. J. 1992. The selective impact of herbivores, pp. 301–325 in Fritz, R. S. and Simms, E. L. (eds.) Plant Resistance to Herbivores and Pathogens: Ecology, Evolution and Genetics. Chicago, IL:University of Chicago Press.Google Scholar
Martinsen, G. D., Driebe, E. M., and Whitham, T. G.. 1998. Indirect interactions mediated by changing plant chemistry: beaver browsing benefits beetles. Ecology 79:192–200.CrossRefGoogle Scholar
Master, G. J., and Brown, V. K.. 1997. Host-plant mediated interactions between spatially separated herbivores: effects on community structure, pp. 217–328 in Ganges, A. C. and Brown, V. K. (eds.) Multitrophic Interactions in Terrestrial Systems. Oxford, UK: Blackwell Science.Google Scholar
Palmisano, S., and Fox, L. R.. 1997. Effects of mammal and insect herbivory on population dynamics of a native Californian thistle, Cirsium occidentale. Oecologia 111:413–421.CrossRefGoogle ScholarPubMed
Passos, L., and Oliveira, P. S.. 2002. Ants affect the distribution and performance of seedlings of Clusia criuva, a primarily bird-dispersed rain forest tree. Journal of Ecology 90:517–528.CrossRefGoogle Scholar
Pimm, S. L. 2002. Food Webs, 2nd edn. Chicago, IL:University of Chicago Press.Google Scholar
Prittinen, K., Pusenius, J., Koivunoro, K., Rousi, M., and Roininen, H.. 2003. Mortality in seedling populations of silver birch: genotype variation and herbivore effects. Functional Ecology 17:658–663.CrossRefGoogle Scholar
Quesada, M., Bollman, K., and Stephenson, A. G.. 1995. Leaf damage decreases pollen production and hinders pollen performance in Cucurbita texana. Ecology 76:437–443.CrossRefGoogle Scholar
Raimondi, P. T., Forde, S. E., Delph, L. F., and Lively, C. M.. 2000. Processes structuring communities: evidence for trait-mediated indirect effects through induced polymorphisms. Oikos 91:353–361.CrossRefGoogle Scholar
Rambo, J. L., and Faeth, S. H.. 1999. Effect of vertebrate grazing on plant and insect community structure. Conservation Biology 13:1047–1054.CrossRefGoogle Scholar
Retamosa, E. C. 1997. Efecto de los herbívoros sobre Iberis contracta en el Parque Nacional de Doñana. Ph.D. dissertation, University of Córdoba, Spain.Google Scholar
Reznik, S. Y. 1991. The effects of feeding damage in ragweed Ambrosia artemisiifolia (Asteraceae) on populations of Zygogramma suturalis (Coleoptera, Chrysomelidae). Oecologia 88:204–210.CrossRefGoogle Scholar
Roche, B. M., and Fritz, R. S.. 1997. Genetics of resistance of Salix sericea to a diverse community of herbivores. Evolution 51:1490–1498.CrossRefGoogle ScholarPubMed
Schmitz, O., Krivan, V., and Ovadia, O.. 2004. Trophic cascades: the primacy of trait-mediated indirect interactions. Ecology Letters 7:153–163.CrossRefGoogle Scholar
Schoonhoven, L. M., Jermy, T., and Loon, J. J. A.. 1998. Insect–Plant Biology: From Physiology to Evolution. London:Chapman and Hall.CrossRefGoogle Scholar
Sessions, L. A., and Kelly, D.. 2001. Heterogeneity in vertebrate and invertebrate herbivory and its consequences for New Zealand mistletoes. Austral Ecology 26:571–581.CrossRefGoogle Scholar
Seymour, C. L., and Dean, W. R. J.. 1999. Effects of heavy grazing on invertebrate assemblages in the Succulunt Karoo, South Africa. Journal of Arid Environment 43:267–286.CrossRefGoogle Scholar
Speight, M. R., Hunter, M. D., and Watt, A. D.. 1999. Ecology of Insects: Concepts and Applications. Oxford, UK: Blackwell Scientific Publications.Google Scholar
Stewart, A. J. A. 1996. Interspecific competition reinstated as an important force structuring insect herbivore communities. Trends in Ecology and Evolution 11:233–234.CrossRefGoogle ScholarPubMed
Strand, M., and Merritt, R. W.. 1999. Impact of livestock grazing activities on stream insect communities and the riverine environment. American Entomologist 45:13–27.CrossRefGoogle Scholar
Strauss, S. Y. 1997. Floral characters link herbivores, pollinators, and plant fitness. Ecology 78:1640–1645.CrossRefGoogle Scholar
Strauss, S. Y., and Agrawal, A. A.. 1999. The ecology and evolution of plant tolerance to herbivory. Trends in Ecology and Evolution 14:179–185.CrossRefGoogle ScholarPubMed
Strauss, S. Y., Conner, J. K., and Rush, S.. 1996. Foliar herbivory affects floral characters and plant attractiveness to pollinators: implications for male and female plant fitness. American Naturalist 147:1098–1107.CrossRefGoogle Scholar
Strong, D. R., Lawton, J. H., and Southwood, T. R. E.. 1984. Insects on Plants: Community Patterns and Mechanisms. Oxford, UK: Blackwell Scientific Publications.Google Scholar
Suominen, O., Danell, K., and Bergström, R.. 1999a. Moose, trees, and ground-living invertebrates: indirect interactions in Swedish pine forest. Oikos 84:215–226.CrossRefGoogle Scholar
Suominen, O., Danell, K., and Bryant, J. P.. 1999b. Indirect effects of mammalian browsers on vegetation and ground-dwelling insects in an Alaskan floodplain. Ecoscience 6:505–510.CrossRefGoogle Scholar
Takabayashi, J., and Dicke, M.. 1996. Plant–carnivore mutualisms through herbivore-induced carnivore attractants. Trends in Plant Science 1:109–113.CrossRefGoogle Scholar
Trussell, G. C., Ewanchuk, P. J., and Bertness, M. D.. 2003. Trait-mediated effects in rocky intertidal food chains: predator risk cues alter prey feeding rates. Ecology 84:629–640.CrossRefGoogle Scholar
Tscharntke, T. 1997. Vertebrate effects on plant–invertebrate food webs, pp. 277–297 in A. C. Ganges and V. K. Brown (eds.) Multitrophic Interactions in Terrestrial Systems. Oxford, UK: Blackwell Science.Google Scholar
Tscharntke, T., and Greiler, H. J.. 1995. Insect communities, grasses, and grasslands. Annual Reviews of Entomology 40:535–558.CrossRefGoogle Scholar
WallisDeVries, M. F., Laca, E. A., and Demment, M. W.. 1999. The importance of scale patchiness for selectivity in grazing herbivores. Oecologia 121:355–363.CrossRefGoogle ScholarPubMed
Werner, E. E., and Peacor, S. D.. 2003. A review of trait-mediated indirect interactions in ecological communities. Ecology 84:1083–1100.CrossRefGoogle Scholar
Wootton, J. T. 1994. The nature and consequences of indirect effects in ecological communities. Annual Review of Ecology and Systematics 25:443–466.CrossRefGoogle Scholar
Young, T. P., and Okello, B. D.. 1998. Relaxation of an induced defense after exclusion of herbivores: spines on Acacia drepanolobium. Oecologia 115:508–513.CrossRefGoogle ScholarPubMed
Young, T. P., Stanton, M. L., and Christian, C. E.. 2003. Effects of natural and simulated herbivory on spine lengths of Acacia drepanolobium in Kenya. Oikos 101:171–179.CrossRefGoogle Scholar
Zamora, R., and Gómez, J. M.. 1993. Vertebrate herbivores as predators of insect herbivores: an asymmetrical interaction mediated by size differences. Oikos 66:223–228.CrossRefGoogle Scholar
Zamora, R., Hódar, J. A., and Gómez, J. M.. 1999. Plant–herbivore interaction: beyond a binary vision, pp. 677–718 in F. Valladares and Pugnaire, F. I. (eds.) Handbook of Plant Functional Ecology. New York: Marcel Dekker.Google Scholar
Zamora, R., Gómez, J. M., Hódar, J. A., Castro, J., and García, D.. 2001. Effect of browsing by ungulates on sapling growth of Scots pine in a Mediterranean environment: consequences for forest regeneration. Forest Ecology and Management 144:33–42.CrossRefGoogle Scholar

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