A mechanism of plant species coexistence: the negative density-dependent hypothesis

doi:10.3724/SP.J.1003.2009.09183

Abstract

Abstract:

The negative density-dependent hypothesis focuses mainly on conspecific interactions to explain the coexistence of diverse species in natural communities. The hypothesis describes the impairment of performance among conspecific individuals due to resource competition, predation of pests (e.g., pathogen, herbivore) and so on. Impairment of conspecific individuals decreases growth and increases mortality, thereby freeing space for other species, and thus promotes coexistence of diverse species. There are three main kinds of density dependent effects including distance-dependence of mortality and abundance of offspring near parents (Janzen-Connell hypothesis), density dependent thinning (random-mortality hypothesis), and community compensatory trends (CCT). Research has shown that density dependence among phylogenetically closely-related species results partially from competition for similar resources. This fact led to the proposal of species herd protection and phylodiversity dependence models. Density dependence has long history of study and the recent establishment of a global network of large-scale forest dynamic plots facilitates the detection of density dependence in natural communities. However, there are many challenges when testing for density dependence. For example, some previous studies can not disentangle density dependence from other confounding effects, and most studies focus exclusively on the tropical zone, seldom considering other zones. Therefore, though strong evidence to contrary does not exist, debate continues on the importance of density dependence in maintaining diverse-species coexistence.

Key words: density dependence, conspecific individuals, distance dependence, community compensatory trend (CCT), phylodiversity dependence

Yan Zhu, Xiangcheng Mi, Keping Ma. A mechanism of plant species coexistence: the negative density-dependent hypothesis[J]. Biodiv Sci, 2009, 17(6): 594-604.

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URL: https://www.biodiversity-science.net/EN/10.3724/SP.J.1003.2009.09183

https://www.biodiversity-science.net/EN/Y2009/V17/I6/594

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References 82

[1]	Alvarez-Buylla ER (1994) Density dependence and patch dynamics in tropical rain forests: matrix models and applications to a tree species. The American Naturalist, 143, 155-191.
[2]	Alvarez-Buylla ER, García-Barrios R, Lara-Moreno C, Martinez-Ramos M (1996) Demographic and genetic models in conservation biology: applications and perspe- ctives for tropical rain forest tree species. Annual Review of Ecology and Systematics, 27, 387-421.
[3]	Augspurger CK (1983a) Offspring recruitment around tropical trees: changes in cohort distance with time. Oikos, 40, 189-196.
[4]	Augspurger CK (1983b) Seed dispersal of the tropical tree, Platypodium elegans, and the escape of its seedlings from fungal pathogens. Ecology, 65, 1705-1712.
[5]	Augspurger CK (1984) Seedling survival of tropical tree species: interactions of dispersal distance, light gaps, and pathogens. Journal of Ecology, 71, 759-771.
[6]	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. DOI URL PMID
[7]	Bell T, Freckleton RP, Lewis OT (2006) Plant pathogens drive density-dependent seedling mortality in a tropical tree. Ecology Letters, 9, 569-574. URL PMID
[8]	Black GA, Dobzhansky T, Pavan C (1950) Some attempts to estimate species diversity and population density of trees in Amazonian forests. Botanical Gazette, 111, 413-425.
[9]	Brown ND, Whitmore TC (1992) Do dipterocarp seedlings really partition tropical rain forest gaps? Philosophical Transactions of the Royal Society of London B, 335, 369-378.
[10]	Burkey TV (1994) Tropical tree species diversity: a test of the Janzen-Connell model. Oecologia, 97, 533-540. DOI URL PMID
[11]	Carson WP, Jill TA, Egbert GL, Schnitzer SA (2008) Challenges associated with testing and falsifying the Janzen-Connell hypothesis: a review and critique. In: Tropical Forest Community Ecology (eds Carson WP, Stefan AS), pp. 210-241. Wiley-Blackwell, West Sussex.
[12]	Clark DA, Clark DB (1984) Spacing dynamics of a tropical forest tree: evaluation of the Janzen-Connell model. The American Naturalist, 124, 769-788.
[13]	Clark DB, Clark DA, Read JM (1998) Edaphic variation and the mesoscale distribution of tree species in a neotropical rain forest. Journal of Ecology, 86, 101-112.
[14]	Comita LS, Hubbell SP (2009) Local neighborhood and species’ shade tolerance influence survival in a diverse seedling bank. Ecology, 90, 328-334. URL PMID
[15]	Condit R (1995) Research in large, long-term tropical forest plots. Trends in Ecology and Evolution, 10, 18-22. URL PMID
[16]	Condit R, Ashton PS, Baker P, Bunyavejchewin S, Gunatilleke S, Gunatilleke N, Hubbell SP, Foster RB, Itoh A, LaFrankie JV, Lee HS, Losos E, Manokaran N, Sukumar R, Yamakura T (2000) Spatial patterns in the distribution of tropical tree species. Science, 288, 1414-1418.
[17]	Condit R, Hubbell SP, Foster RB (1992) Recruitment near conspecific adults and the maintenance of tree and shrub diversity in a neotropical forest. The American Naturalist, 140, 261-286.
[18]	Condit R, Hubbell SP, Foster RB (1994) Density-dependence in two understory tree species in a neotropical forest. Ecology, 75, 671-680.
[19]	Connell JH (1971) On the role of natural enemies in preventing competitive exclusion in some marine animals and in rain forest trees. In: Dynamics of Populations (eds den Boer PJ, Gradwell GR), pp. 298-312. Center for Agricultural Publishing and Documentation, Wageningen, The Netherlands.
[20]	Connell JH, Tracey JG, Webb LJ (1984) Compensatory recruitment, growth, and mortality as factors maintaining rain forest tree diversity. Ecological Monographs, 54, 141-164.
[21]	Denslow JS (1987) Tropical rainforest gaps and tree species diversity. Annual Review of Ecology and Systematics, 18, 431-451.
[22]	Dieckmann U, O’Hara B, Weisser W (1999) The evolutionary ecology of dispersal. Trends in Ecology and Evolution, 14, 88-90.
[23]	Getzin S, Wiegand T, Wiegand K, He FL (2008) Heterogeneity influences spatial patterns and demographics in forest stands. Journal of Ecology, 96, 807-820.
[24]	Gilbert GS, De Steven D (1996) A canker disease of seedlings and saplings of Tetragastris panamensis (Burseraceae) caused by Botryosphaeria dothidea in a lowland tropical forest. Plant Disease, 80, 684-687.
[25]	Gilbert GS, Harms KE, Hamill DN, Hubbell SP (2001) Effects of seedling size, El Niño drought, seedling density, and distance to nearest conspecific adult on 6-year survival of Ocotea whitei seedlings in Panama. Oecologia, 127, 509-516. DOI URL PMID
[26]	Gilbert GS, Hubbell SP, Foster RB (1994) Density and distance-to-adult effects of a canker disease of trees in a moist tropical forest. Oecologia, 98, 100-108. DOI URL PMID
[27]	Gilbert GS, Webb CO (2007) Phylogenetic signal in plant pathogen-host range. Proceedings of the National Academy of Sciences, USA, 104, 4979-4983.
[28]	Grubb PJ (1977) The maintenance of species richness in plant communities: the importance of the regeneration niche. Biological Reviews, 52, 107-145.
[29]	Hamill DN, Wright SJ (1986) Testing the dispersion of juveniles relative to adults: a new analytic method. Ecology, 67, 952-957.
[30]	Hammond DS, Brown VK (1998) Disturbance, phenology and life-history characteristics: factors influencing distance/density-dependent attack on tropical seeds and seedlings. In: Dynamics of Tropical Communities (eds Newbery DM, Prins HHT, Brown N), pp. 51-78. Blackwell Science, Oxford.
[31]	Harms KE, Wright JS, Calderón O, Hernandez A, Herre EA (2000) Pervasive density-dependent recruitment enhances seedling diversity in a tropical forest. Nature, 404, 493-495. URL PMID
[32]	He FL, Duncan RP (2000) Density-dependent effects on tree survival in an old-growth douglas fir forest. Journal of Ecology, 88, 676-688.
[33]	He FL, Legendre P, LaFrankie JV (1997) Distribution patterns of tree species in a Malaysian tropical rain forest. Journal of Vegetation Science, 8, 105-114.
[34]	Hille Ris Lambers J, Clark JS, Beckage B (2002) Density-dependent mortality and the latitudinal gradient in species diversity. Nature, 417, 732-735. DOI URL PMID
[35]	Hou JH (侯继华), Ma KP (马克平) (2002) On mechanisms of species coexistence in plant communities. Acta Phytoe-cologica Sinica (植物生态学报), 26(Suppl.), 1-8. (in Chinese with English abstract)
[36]	Howe HF (1990) Survival and growth of juvenile Virola surinamensis in Panama: effects of herbivory and canopy closure. Journal of Tropical Ecology, 6, 259-280.
[37]	Howe HF, Smallwood J (1982) Ecology of seed dispersal. Annual Review of Ecology and Systematics, 13, 201-228.
[38]	Hubbell SP (1979) Tree dispersion, abundance, and diversity in a tropical dry forest. Science, 203, 1299-1309. URL PMID
[39]	Hubbell SP (1980) Seed predation and the coexistence of tree species in tropical forests. Oikos, 35, 214-229.
[40]	Hubbell SP (1997) A unified theory of biogeography and relative species abundance and its application to tropical rain forests and coral reefs. Coral Reefs, 16, S9-S21.
[41]	Hubbell SP (2001) The Unified Neutral Theory of Biodiversity and Biogeography. Princeton University Press, Princeton.
[42]	Hubbell SP, Ahumada JA, Condit R, Foster RB (2001) Local neighborhood effects on long-term survival of individual trees in a neotropical forest. Ecological Research, 16, 859-875.
[43]	Hubbell SP, Condit R, Foster RB (1990) Presence and absence of density dependence in a neotropical tree community. Philosophical Transactions of the Royal Society of London B, 330, 269-281.
[44]	Hubbell SP, Foster RB (1986a) Commonness and rarity in a neotropical forest: implications for tropical tree conservation. In: Conservation Biology: the Science of Scarcity and Diversity (ed. Soulé ME), pp. 205-231. Sinauer Associates, Inc., Sunderland, MA.
[45]	Hubbell SP, Foster RB (1986b) Biology, chance and history and the structure of tropical rain forest tree communities. In: Community Ecology (eds Diamond J, Case TJ), pp. 314-329. Harper and Row, New York.
[46]	Hyatt LA, Rosenberg MS, Howard TG, Bole G, Fang W, Anastasia J, Brown K, Grella R, Hinman K, Kurdziel JP, Gurevitch J (2003) The distance dependence prediction of the Janzen-Connell hypothesis: a meta-analysis. Oikos, 103, 590-602.
[47]	Janzen DH (1970) Herbivores and the number of tree species in tropical forests. The American Naturalist, 104, 501-528.
[48]	Kenkel NC, Hoskins JA, Hoskins WD (1989) Local competition in a naturally established jack pine stand. Canadian Journal of Botany, 67, 2630-2634.
[49]	Kochummen KM, LaFrankie JV, Manokaran N (1990) Floristic composition of the Pasoh Forest Reserve, a lowland rain forest in Peninsular Malaysia. Journal of Tropical Forest Science, 3, 1-13.
[50]	Leigh EG Jr, Davidar P, Dick CW, Puyravaud JP, Terborgh J, ter Steege H, Wright SJ (2004) Why do some tropical forests have so many species of trees? Biotropica, 36, 447-473.
[51]	Li RB, Yu SX, Wang YF, Staehelin C, Zang RG (2009) Distance-dependent effects of soil-derived biota on seedling survival of the tropical tree legume Ormosia semicastrata. Journal of Vegetation Science, 20, 527-534.
[52]	Ma KP (马克平) (2008) Large scale permanent plots: important platform for long term research on biodiversity in forest ecosystem. Chinese Journal of Plant Ecology (植物生态学报), 32, 237. (in Chinese)
[53]	Martínez-Ramos M, Sarukhán JK, Piñero DD (1988) The demography of tropical trees in the context of forest gap dynamics: the case of Astrocaryum mexicanum at Los Tuxtlas tropical rain forest. In: Plant Population Ecology (eds Davy DJ, Hutchings MJ, Watkinson AR), pp. 293-313. Blackwell, Oxford.
[54]	McCarthy-Neumann S, Kobe RK (2008) Tolerance of soil pathogens co-varies with shade tolerance across species of tropical tree seedlings. Ecology, 89, 1883-1892. DOI URL PMID
[55]	Pacala SW, Canham CD, Saponara J, Silander JA, Kobe RK, Ribbens E (1996) Forest models defined by field measurements: estimation, error analysis and dynamics. Ecological Monographs, 66, 1-43.
[56]	Packer A, Clay K (2000) Soil pathogens and spatial patterns of seedling mortality in a temperate tree. Nature, 404, 278-281. URL PMID
[57]	Petermann JS, Fergus AJF, Turnbull LA, Schmid B (2008) Janzen-Connell effects are widespread and strong enough to maintain diversity in grasslands. Ecology, 89, 2399-2406. DOI URL PMID
[58]	Peters HA (2003) Neighbour-regulated mortality: the influence of positive and negative density dependence on tree populations in species-rich tropical forests. Ecology Letters, 6, 757-765.
[59]	Pires JM, Dobzhansky T, Black GA (1953) An estimate of the number of species of trees in an Amazonian forest community. Botanical Gazette, 114, 467-477.
[60]	Queenborough SA, Burslem DFRP, Garwood NC, Valencia R (2007) Neighborhood and community interactions determine the spatial pattern of tropical tree seedling survival. Ecology, 88, 2248-2258. DOI URL PMID
[61]	Ridley HA (1930) The dispersal of plants throughout the world. Lovell, Reeve, Ashford, Kent.
[62]	Schupp EW (1988) Seed and early seedling predation in the forest understory and in treefall gaps. Oikos, 51, 71-78.
[63]	Schupp EW (1992) The Janzen-Connell model for tropical tree diversity: population implication and the importance of spatial scale. The American Naturalist, 140, 526-530.
[64]	Silva Matos DM, Freckleton RP, Watkinson AR (1999) The role of density dependence in the population dynamics of a tropical palm. Ecology, 80, 2635-2650.
[65]	Stoll P, Newberry DM (2005) Evidence of species-specific neighborhood effects in the Dipterocarpaceae of a Bornean rain forest. Ecology, 86, 3048-3062.
[66]	Taylor DR, Aaressen LW, Loehle C (1990) On the relationship between r/K selection and environmental carrying capacity: a new habitat templet for plant life history strategies. Oikos, 58, 239-250.
[67]	Tilman D (1982) Resource Competition and Community Structure. Princeton University Press, Princeton.
[68]	Uriarte M, Condit R, Canham CD, Hubbell SP (2004) A spatially explicit model of sapling growth in a tropical forest: does the identity of neighbours matter? Journal of Ecology, 92, 348-360.
[69]	Volkov I, Banavar JR, He F, Hubbell SP, Maritan A (2005) Density dependence explains tree species abundance and diversity in tropical forests. Nature, 438, 658-661. DOI URL PMID
[70]	Webb CO, Gilbert GS, Donoghue MJ (2006) Phylodiversity- dependent seedling mortality, size structure, and disease in a Bornean rain forest. Ecology, 87, S123-S131. URL PMID
[71]	Webb CO, Peart DR (1999) Seedling density dependence promotes coexistence of Bornean rain forest trees. Ecology, 80, 2006-2017.
[72]	Welden CW, Hewett SW, Hubbell SP, Foster RB (1991) Sapling survival, growth, and recruitment: relationship to canopy height in a neotropical forest. Ecology, 72, 35-50.
[73]	Wills C (1996a) Plagues: Their Origin, History, and Future. Harper-Collins, New York.
[74]	Wills C (1996b) Safety in diversity. New Scientist, 149, 38-42.
[75]	Wills C, Condit R (1999) Similar non-random processes maintain diversity in two tropical rainforests. Proceedings of the Royal Society of London Series B, 266, 1445-1452. DOI URL PMID
[76]	Wills C, Condit R, Foster RB, Hubbell SP (1997) Strong density- and diversity-related effects help to maintain tree species diversity in a neotropical forest. Proceedings of the National Academy of Sciences,USA, 94, 1252-1257.
[77]	Wills C, Green DR (1995) A genetic herd-immunity model for the maintenance of MHC polymorphism. Immunology Review, 143, 263-292.
[78]	Wills C, Harms KE, Condit R, King D, Thompson J, He FL, Muller-Landau HC, Ashton P, Losos E, Comita L, Hubbell S, LaFrankie J, Bunyavejchewin S, Dattaraja HS, Davies S, Esufali S, Foster R, Gunatilleke N, Gunatilleke S, Hall P, Itoh A, John R, Kiratiprayoon S, de Lao SL, Massa M, Nath C, Noor MNS, Kassim AR, Sukumar R, Suresh HS, Sun IF, Tan S, Yamakura T, Zimmerman E (2006) Nonrandom processes maintain diversity in tropical forests. Science, 311, 527-531. URL PMID
[79]	Wright SJ (1999) Plant diversity in tropical forests, In: Handbook of Functional Plant Ecology (eds Pugnaire FI, Valladares F), pp. 449-472. Marcel Dekker, New York.
[80]	Wright SJ (2002) Plant diversity in tropical forests: a review of mechanisms of species coexistence. Oecologia, 130, 1-14. DOI URL PMID
[81]	Zimmerman JK, Thompson J, Brokaw N (2008) Large tropical forest dynamics plots: testing explanations for the maintenance of species diversity. In: Tropical Forest Community Ecology (eds Carson WP, Stefan AS), pp. 98-117. Wiley-Blackwell, West Sussex.
[82]	Zhu Y, Mi XC, Ren HB, Ma KP (2009) Density dependence is prevalent in a heterogeneous subtropical forest. Oikos, doi: 10.1111/j.1600-0706.2009.017758.x. DOI URL PMID