Abstract
Although one of the most widely studied hypotheses for high tree diversity in the tropics, the Janzen–Connell hypothesis (JC), and the community compensatory trend upon which it is based, have conflicting support from prior studies. Some of this variation could arise from temporal variation in seedling survival of common and rare species. Using 10 years of data from La Selva Biological Station in Costa Rica, we analyzed annual seedling survival and found that negative density-dependence (negative DD) was significantly stronger for rare species than for common species in 2 years and was significantly stronger for common species than for rare species in 4 years. This temporal variation in survival was correlated with climatic variables: in warmer and wetter years, common species had higher negative DD than rare species. The relationship between climate and variation in JC effects on seedling survival of common and rare species could have important consequences for the maintenance of tree species diversity in Central America, which is predicted to experience warmer and wetter years as global change proceeds.
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References
Altizer S et al (2013) Climate change and infectious diseases: from evidence to a predictive framework. Science 341:514–519
Augspurger CK, Kelly CK (1984) Pathogen mortality of tropical tree seedlings: experimental studies of the effects of dispersal distance, seedling density, and light conditions. Oecologia 61:211–217
Bachelot B, Kobe RK (2013) Rare species advantage? Richness of damage types due to natural enemies increases with species abundance in a wet tropical forest. J Ecol 101:846–856
Bagchi R et al (2014) Pathogens and insect herbivores drive rainforest plant diversity and composition. Nature 506:85–88
Bale JS et al (2002) Herbivory in global climate change research: direct effects of rising temperature on insect herbivores. Glob Change Biol 8:1–16
Bardgett RD, Wardle DA (2010) Aboveground–belowground linkages. Biotic interactions, ecosystem processes, and global change. Oxford University Press, New York
Bardgett RD et al (2008) Microbial contributions to climate change trhough carbon-cycle feedbacks. ISME J 2:805–814
Bever JD (2003) Host-specificity of AM fungal population growth rates can generate feedback on plant growth. Plant Soil 244:281–290
Boyce MS, Daley DJ (1980) Population tracking of fluctuating environments and natural selection for tracking ability. Am Nat 115:480–491
Brooks SP, Gelman A (1997) General methods for monitoring convergence of iterative simulations. J Comput Graph Stat 7:434–455
Chase JM et al (2002) The interaction between predation and competition: a review and synthesis. Science 5:302–315
Chaves LF et al (2012) Nonlinear impacts of climatic variability on the density-dependent regulation of an insect vector of disease. Glob Change Biol 18:457–468
Chesson PL (2000) Mechanisms of maintenance of species diversity. Annu Rev Ecol Syst 31:343–367
Chevin L-M, Lande R, Mace GM (2010) Adaptation, plasticity, and extinction in a changing environment: towards a predictive theory. PLoS Biol 8:e1000357
Clark DD, Clark DB (1984) Spacing dynamics of a tropical rain-forest tree—evaluation of the Janzen–Connell model. Am Nat 124:769–788
Clark DA et al (2003) Tropical rain forest tree growth and atmospheric carbon dynamics linked to interannual temperature variation during 1984–2000. Proc Natl Acad Sci USA 100:5852–5857
Clark DA et al (2013) Field-quantified responses of tropical rainforest aboveground productivity to increasing CO2 and climatic stress, 1997–2009. J Geophys Res Biogeosci 118:783–794
Coley P (1998) Possible effects of climate change on plant/herbivore interactions in moist tropical forests. Clim Change 39:455–472
Comita LS, Uriarte M, Thompson J, Jonckheere I, Canham CD, Zimmerman JK (2009) Abiotic and biotic drivers of seedling survival in a hurricane-impacted tropical forest. J Ecol 97:1346–1359
Comita LS et al (2010) Asymmetric density dependence shapes species abundances in a tropical tree community. Science 329:330–332
Comita LS et al (2014) Testing predictions of the Janzen–Connell hypothesis: a meta-analysis of experimental evidence for distance-and density-dependent seed and seedling survival. J Ecol 102:845–856
Connell JH (1971) On the role of natural enemies in preventing competitive exclusion in some marine animals and in rain forest trees. Centre for Agricultural Publication and Documentation, Wageningen, pp 298–312
Connell JH, Green PT (2000) Seedling dynamics over thirsty-2 years in a tropical rain forest tree. Ecology 81:568–584
Connell JH et al (1984) Compensatory recruitment, growth, and mortality as factors maintaining rain-forest tree diversity. Ecol Monogr 54:141–164
Diffenbaugh NS, Scherer M (2011) Observational and model evidence of global emergence of permanent, unprecedented heat in the 20th and 21st centuries. Clim Change 107:615–624
Engelbrecht BMJ et al (2007) Drought sensitivity shapes species distribution patterns in tropical forests. Nature 447:80–82
Fenner N et al (2007) Elevated CO2 and warming cloud amplify DOC exports from peatland catchments. Environ Sci Technol 41:3146–3152
Garrett KA et al (2006) Climate change effects on plant disease: genomes to ecosystems. Annu Rev Phytopathol 44:489–509
Gelman A (2003) A Bayesian formulation of exploratory data analysis and goodness-of-fit testing. Int Stat Rev 71:369–382
Givnish TJ (1999) On the causes of gradients in tropical tree diversity. J Ecol 87:193–210
Grover JP (1990) Resource competition in a variable environment: phytoplankton growing according to Monod’s model. Am Nat 136:771–789
Grover JP (1997) Resource competition. Chapman and Hall, London
Grubb PJ (1977) The maintenance of species-richness in plant communities: the importance of the regeneration niche. Biol Rev 52:107–145
Harms KE et al (2000) Pervasive density-dependent recruitment enhances seedling diversity in a tropical forest. Nature 404:493–495
Haynes K (2013) Geographical variation in the spatial synchrony of a forest-defoliating insect: isolation of environmental and spatial drivers. Proc R Soc Lond B 280:20122373
Hays GC et al (2005) Climate change and marine plankton. Trends Ecol Evol 20:337–344
Heijden VDM et al (2008) Infestation of trees by lianas in a tropical forest in Amazonian Peru. J Veg Sci 19:747–756
Huston AH (1994) Biological diversity: the coexistence of species on changing landscapes. Cambridge University Press, New York
Janzen DH (1970) Herbivores and number of tree species in tropical forests. Am Nat 104:501–528
John R et al (2007) Soil nutrients influence spatial distributions of tropical tree species. Proc Natl Acad Sci USA 104:864–869
Johnson DJ et al (2012) Conspecific negative density dependence and forest diversity. Science 336:904–907
Kardol P et al (2007) Microbe-mediated plant–soil feedback causes historical contingency effects in plant community assembly. Ecol Monogr 77:147–162
Kelly D (1994) The evolutionary ecology of mast seedling. Trends Ecol Evol 9:465–470
Klironomos JN (2002) Feedback with soil biota contributes to plant rarity and invasiveness in communities. Nature 417:67–70
Kobe RK, Vriesendorp CF (2011) Conspecific density-dependence in seedlings varies with species shade tolerance in a wet tropical forest. Ecol Lett 14:503–510
Kriss AB et al (2012) Variability in fusarium head blight epidemics in relation to global climate fluctuations as represented by the El Niño-Southern Oscillation and other atmospheric patterns. Phytopathology 102:55–64
Kulmatiski A, Kardol P (2008) Getting plant–soil feedbacks out of the greenhouse: experimental and conceptual approaches. Progress in Botany 69. Springer, Berlin, pp 449–472
Kutz SJ et al (2005) Global warming is changing the dynamics of Arctic host–parasite systems. Proc R Soc Lond B 272:2571–2576
Mangan SA et al (2010) Negative plant—soil feedback predicts tree-species relative abundance in a tropical forest. Nature 466:752–756
McDade LA, Hartshorn GS (1994) La Selva Biological Station. In: McDade LA, Bawa KS, Hespenheide HA, Hartshorn GS (eds) La Selva: ecology and natural history of a neotropical rain forest. University of Chicago Press, Chicago, pp 6–14
Metz MR et al (2010) Widespread density-dependent seedling mortality promotes species coexistence in a highly diverse Amazonian rain forest. Ecology 91:3675–3685
Miriti MN et al (1998) Spatial pat-terns of mortality in a Colorado desert plant community. Plant Ecol 136:41–51
Murphy GI (1968) Pattern in life history and the environment. Am Nat 102:390–404
Pacala SW, Crawley MJ (1992) Herbivores and plant diversity. Am Nat 140:243–260
Parmesan C (2006) Ecological and evolutionary responses to recent climate change. Annu Rev Ecol Evol Syst 37:637–669
Piutti E, Cescatti A (1997) A quantitative analysis of the interactions between climatic response and intraspecific competition in European beech. Can J For Res 27:277–284
Plummer M (2005) JAGS: just another gibbs sampler version 103 retrieved 15 January 2009, from http://www.fisiarcfr/martyn/software/jag
Pyke CR et al (2001) Floristic composition across a climatic gradient in a neotropical lowland forest. J Veg Sci 12:553–566
Rosenzweig C et al (2001) Climate change and extreme weather events—implications for food production, plant diseases, and pests. Glob Change Hum Health 2:90–104
Sale PF (1977) Maintenancc of high diversity in coral reel fish communities. Am Nat 3:337–359
Selås V (1997) Cyclic population fluctuations of herbivores as an effect of cyclic seed cropping of plants: the mast depression hypothesis. Oikos 80:257–268
Silvertown JW (1980) The evolutionary ecology of mast seeding in trees. Biol J Linn Soc 14:235–250
Suzuki RO et al (2003) Spatial and temporal variations in mortality of the biennial plant, Lysimachia rubida: effects of intraspecific competition and environmental heterogeneity. J Ecol 91:114–125
Swinfield T et al (2012) Consequences of changing rainfall for fungal pathogen-induced mortality in tropical tree seedlings. Ecol Evol 2:1408–1413
Visser M, Both C (2005) Shifts in phenology due to global climate change: the need for a yardstick. Proc R Soc Lond B 272:2561–2569
Webb CO, Peart DR (2000) Habitat associations of trees and seedlings in a Bornean rain forest. J Ecol 88:464–478
Whitfield S et al (2007) Amphibian and reptile declines over 35 years at La Selva, Costa Rica. Proc Natl Acad Sci USA 104:8352–8356
Wright SJ (2002) Plant diversity in tropical forests : a review of mechanisms of species coexistence. Oecologia 130:1–14
Acknowledgments
We are grateful to NSF (DEB 0075472, 0640904, 0743609) for funding a large part of this project. We would like to thank Ademar Hurtado Flores and Ralph Garcia Robleto who are responsible for the long-term censuses being conducted at La Selva. We also would like to thank Liza Comita and Maria Uriarte for their comments and ideas pertaining to the study. We thank Rachael Eaton, Dr. Katherine Gross, and anonymous reviewers for help editing this manuscript. Finally, the study complies with the current laws of Costa Rica in which the study was performed.
Author contribution statements
BB and RKK developed the study question. RKK and CV established the long-term transects and are in charge of the long-term transects. BB analyzed the data. BB wrote the first draft of the manuscript. RKK contributed to subsequent drafts.
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Communicated by Walt Carson.
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Bachelot, B., Kobe, R.K. & Vriesendorp, C. Negative density-dependent mortality varies over time in a wet tropical forest, advantaging rare species, common species, or no species. Oecologia 179, 853–861 (2015). https://doi.org/10.1007/s00442-015-3402-7
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DOI: https://doi.org/10.1007/s00442-015-3402-7
Keywords
- Janzen–Connell hypothesis
- Negative density-dependence
- Community compensatory trend
- Global change
- Tropical lowland rainforest