OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

PLOS ONE 2007

Mast Fruiting Is a Frequent Strategy in Woody Species of Eastern South America

DOI: 10.1371/journal.pone.0001079

Natalia Norden, Jér？me Chave, Pierre Belbenoit, Adeline Caubère, Patrick Chatelet, Pierre-Michel Forget, Christophe Thébaud

Full-Text Cite this paper Add to My Lib

Abstract:

Background It is thought that mast seeding is a rare reproductive strategy in the tropics, since tropical climates are less variable, and fruit consumers tend to be more generalist in these regions. However, previous tests of this hypothesis were based on only few tropical datasets, and none from tropical South America. Moreover, reproductive strategies have been quantified based on the coefficient of variation of interannual seed production, an index that potentially confounds masting and high interannual variability in seed production. Methodology/Principal Findings We developed a new approach to model the monthly variability in seed production for 28 tree species, and 20 liana species monitored during 5 years in a tropical forest of Central French Guiana. We found that 23% of the species showed a masting pattern, 54% an annual fruiting pattern, and 23% an irregular fruiting pattern. The majority of masting species were trees (8 out of 11), most of them animal-dispersed. The classification into reproductive strategies based on the coefficient of variation was inconsistent with our results in nearly half of the cases. Conclusions/Significance Our study is the first to clearly evidence the frequency of the masting strategy in a tropical forest community of Eastern South America. The commonness of the masting strategy in tropical plants may promote species coexistence through storage dynamics.

References

[1]	Kelly D, Sork VL (2002) Mast seeding in perennial plants: Why, how, where? Annu Rev Ecol Syst 33: 427–447.
[2]	Shibata M, Nakashizuka T (1995) Seed and seedling demography of four co-occuring Carpinus species in a temperate deciduous forest. Ecology 76: 1099–1108.
[3]	Connell JH, Green PT (2000) Seedling dynamics over thirty-two years in a tropical rain forest tree. Ecology 81: 568–584.
[4]	Curran LM, Webb CO (2000) Experimental tests of the spatiotemporal scale of seed predation in mast-fruiting Dipterocarpaceae. Ecol Monogr 70: 129–148.
[5]	Wright SJ, Muller-Landau HC, Calderón O, Hernández A (2005) Annual and spatial variation in seedfall and seedling recruitment in a neotropical forest. Ecology 86: 848–860.
[6]	Chesson PL, Warner RR (1981) Environmental variability promotes coexistence in lottery competitive-systems. Am Nat 117: 923–943.
[7]	Chesson PL (2000) Mechanisms of maintenance of species diversity. Annu Rev Ecol Syst 31: 343–366.
[8]	Sakai S (2001) Phenological diversity in tropical forests. Pop Ecol 43: 77–86.
[9]	Janzen DH (1974) Tropical black water rivers, animals, and mast fruiting by the Dipterocarpaceae. Biotropica 62: 69–103.
[10]	Ashton PS, Givnish TJ, Appanah S (1988) Staggered flowering in the dipterocarpaceae new insights into floral induction and the evolution of mast fruiting in the aseasonal tropics. Am Nat 132: 44–66.
[11]	Curran LM, Caniago I, Paoli GD, Astianti D, Kusneti M, et al. (1999) Impact of El Nino and logging on canopy tree recruitment in Borneo. Science 286: 2184–2188.
[12]	Sakai S (2002) General flowering in lowland mixed dipterocarp forests of South–East Asia. Biol J Linn Soc 75: 233–247.
[13]	Koenig WD, Knops JMH (2000) Patterns of annual seed production by Northern Hemisphere trees: A global perspective. Am Nat 155: 59–69.
[14]	Kelly D (1994) The evolutionary ecology of mast seeding. Trends Ecol Evol 9: 465–470.
[15]	Herrera CM, Jordano P, Guitian J, Traverset A (1998) Annual variability in seed production by woody plants and the masting concept: Reassessment of principles and relationship to pollination and seed dispersal. Am Nat 152: 576–594.
[16]	Koenig WD, Kelly D, Sork VL, Duncan RP, Elkinton JS, et al. (2003) Dissecting components of population-level variation in seed production and the evolution of masting behavior. Oikos 102: 581–591.
[17]	Schauber EM, Kelly D, Turchin P, Simon C, Lee WG, et al. (2002) Masting by eighteen New Zealand plant species: the role of temperature as a synchronizing cue. Ecology 83: 1214–1225.
[18]	Shibata M, Tanaka H, Iida S, Abe S, Masaki T, et al. (2002) Synchronized annual seed production by 16 principal tree species in a temperate deciduous forest, Japan. Ecology 83: 1727–1742.
[19]	Bongers F, Charles-Dominique P, Forget PM, Théry M, editors. (2001) Nouragues: Dynamics and Plant Animal Interactions in a Neotropical Rainforest. Dordrecht: Kluwer Academic Publishers.
[20]	Mori SA, Cremers G, Gracie C, de Granville JJ, Heald SV, et al. (2002) Guide to the vascular plants of central French Guiana. Part 2. Dicotyledons. New York: New York Botanical Garden Press.
[21]	Sabatier D (1985) Saisonnalité et déterminisme du pic de fructification en forêt guyanaise. Rev Ecol Terre-Vie 40: 289–320.
[22]	Norden N, Chave J, Caubère A, Chatelet P, Ferroni N, et al. (2007) Is temporal variation in seedling communities determined by environment or by seed arrival? A test in a neotropical forest. J Ecol 95: 507–516.
[23]	Van Roosemalen MGM (1985) Fruits of the Guianan Flora. Utrecht: Utrecht University, Institute of Systematic Botany.
[24]	Boggan J, Funk V, Kelloff C, Hoff M, Cremers G, et al. (1997) Checklist of the plants of the Guianas (Guyana, Surinam, French Guiana). 2nd Edition.
[25]	Burnham KP, Anderson DR (1998) Model Selection and Multimodel Inference: A Practical Information-Theoretic Approach. New York: Springer.
[26]	Dalling JW, Muller-Landau HC, Wright SJ, Hubbell SP (2002) Role of dispersal in the recruitment limitation of neotropical pioneer species. J Ecol 90: 714–727.
[27]	R Development Core Team (2006) R: A language and environment for statistical computing. Vienna, Austria: R Foundation for Statistical Computing.
[28]	Gentry AH (1974) Flowering phenology and diversity in tropical Bignoniaceae. Biotropica 6: 64–68.
[29]	Frankie GW, Baker HG, Opler PA (1974) Comparative phenological studies of trees in tropical wet and dry forests in lowlands of Costa Rica. J Ecol 62: 881–919.
[30]	Augspurger CK (1983) Seed dispersal of the tropical tree, Platypodium elegans, and the escape of its seedlings from fungal pathogens. J Ecol 71: 759–771.
[31]	Sarmiento G, Monasterio M (1983) Life forms and phenology. In: Boulière F, editor. Ecosystems of the World, vol 14 B: tropical savannas. pp. 219–240.
[32]	Newstrom LE, Frankie GW, Baker HG (1994) A new classification for plant phenology based on flowering patterns in lowland tropical rainforest trees at La Selva, Costa Rica. Biotropica 26: 141–159.
[33]	ter Steege H, Persaud CA (1991) The phenology of Guyanese timber species: a compilation of a century of observations. Vegetatio 95: 177–198.
[34]	Ratiarison S (2003) Stratégies de fructification et de consommation des fruits dans la canopée d'une forêt tropicale？: une étude comparative en Guyane fran？aise. Ph.D. Université Pierre et Marie Curie. Paris VI.
[35]	Burgess PF (1972) Studies on the regeneration of the hill forests of the Malay Peninsula. The phenology of dipterocarps. Malaysian Forester 35: 103–123.
[36]	Chan TT, Appanah S (1980) Reproductive biology of some Malaysian dipterocarps I. Flowering biology. Malaysian Forester 43: 132–143.
[37]	Croat T (1978) The flora of Barro Colorado Island. Standford: Standford University.
[38]	Jones FA, Chen J, Weng GJ, Hubbell SP (2005) A genetic evaluation of seed dispersal in a neotropical tree Jacaranda copaia (Bignoniaceae). Am Nat 166: 543–555.
[39]	Feer F, Forget PM (2002) Spatio-temporal variations in post-dispersal seed fate. Biotropica 34: 555–562.
[40]	Chauvet S, Feer F, Forget PM (2004) Seed fate of two Sapotaceae species in a Guianan rain forest in the context of escape and satiation hypothesis. J Trop Ecol 20: 1–9.
[41]	Sun IF, Chen YY, Hubbell SP, Wright SJ, Noor NSM (2007) Seed predation during general flowering events of varying magnitude in a Malaysian rain forest. J Ecol 95: 818–827.
[42]	Henkel TW, Mayor JR, Woolley LP (2005) Mast fruiting and seedling survival of the ectomycorrhizal, monodominant Dicymbe corymbosa (Caesalpiniaceae) in Guyana. New Phyt 167: 543–556.
[43]	Newbery DM (2005) Ectomychorrhizas and mast fruiting in trees: Linked by climate-driven tree resources? New Phyt 167: 324–326.
[44]	Newbery DM, Chuyong GB, Zimmermann L (2006) Mast fruiting of large ectomycorrhizal African rain forest trees: importance of dry season intensity, and the resource-limitation hypothesis. New Phyt 170: 561–579.
[45]	Curran LM, Leighton M (2000) Vertebrate responses to spatiotemporal variation in seed production of mast-fruiting Dipterocarpaceae. Ecol Monogr 70: 101–128.
[46]	Forget PM, Kitajima K, Foster RB (1999) Pre- and post-dispersal seed predation in Tachigali versicolor (Caesalpinaceae): effects of timing or fruiting and variation among trees. J Trop Ecol 15: 61–81.
[47]	Brearley FQ, Proctor J, Suriantata , Nagy L, Dalrymple G, et al. (2007) Reproductive phenology over 10-year period in a lowland evergreen rain forest of central Borneo. J Ecol 95: 828–839.
[48]	Hamann A (2004) Flowering and fruiting phenology of a Philippine submontane rain forest: climatic factors as proximate and ultimate causes. J Ecol 92: 24–31.
[49]	Wright SJ, Calderón O (2006) Seasonal, El Ni？o and longer term changes in flower and seed production in a moist tropical forest. Ecol Lett 9: 35–44.
[50]	Ropelewski CF, Halpert MS (1996) Quantifying Southern Oscillation–precipitation relationship. J Clim 9: 1043–1059.
[51]	Malhi Y, Wright J (2004) Spatial patterns and recent trends in the climate of tropical rainforest regions. Philos Trans R Soc Lond B Biol Sci 359: 311–329.
[52]	Sakai S, Harrison RD, Momose K, Kuraji K, Nagamasu H, et al. (2006) Irregular droughts trigger mass flowering in aseasonal tropical forests in Asia. Am J Bot 93: 1134–1139.

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133