Summary
Quantitative predictions of reproductive allometry in iteroparous plants may be derived from two bodies of theory: biomechanics and optimal allocation theory. Biomechanical theory predicts allometric scaling exponents between reproductive (R) and vegetative (V) biomass in the range of 0.44–1.33, while very general models of life history evolution predictR–V exponents > 1 in all cases. These predictions are examined in light of allometric patterns of flower and fruit production in 32 species of Malaysian rain forest trees. Among these species the mean estimatedR–V exponents are in the range 1.8–2.0 for staminate flower, pistillate flower and fruit production. This range of exponent values provides unambiguous support for some of the general predictions of optimal allocation models, but not for biomechanical theory. Optimal allocation models also predict a positive relationship between species size andR–V slope and a positive relationship between species size andR–V intercept parameters. The latter, but not the former prediction is supported by the data.R–V allometries in sexes of dioecious species were also found to differ in intercept, though not slope, reflecting smaller sizes at reproductive onset in staminate trees. Further critical examinations of reproductive allometry are encouraged as a relatively unexplored avenue for increasing the contact of theory and data in studies of life history evolution in long-lived organisms such as tropical trees.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Alvarez-Buylla, E. R. and Martinez-Ramos, M. (1992) Demography and allometry ofCecropia obtusifolia, a neotropical pioneer tree — an evaluation of the climax-pioneer paradigm for tropical rain forests.J. Ecol. 80 275–90.
Assmann, E. (1970)The Principles of Forest Yield Study. Pergamon Press, Oxford.
Chapman, C. A., Chapman, L. J., Wrangham, R., Hunt, K., Gebo, D. and Gardner, L. (1992) Estimators of fruit abundance of tropical trees.Biotropica 24 527–31.
Chazdon, R. L. (1986) The costs of leaf support in understory palms: economy versus safety.Am. Nat. 127 9–30.
Chiariello, N. and Roughgarden, J. (1984) Storage allocation in seasonal races of an annual plant: optimal versus actual allocation.Ecology 65 1290–301.
Cohen, D. (1968) A general model of optimal reproduction in a randomly varying environment.J. Ecol. 56 219–28.
Cohen, D. (1971) Maximizing final yield when growth is limited by time or by limiting resources.J. Theor. Biol. 33 299–307.
Cohen, D. (1976) The optimal timing of reproduction.Am. Nat. 110 801–7.
Hara, T., Kawano, S. and Nagai, Y. (1988) Optimal reproductive strategy of plants, with special reference to the modes of reproductive resource allocation.Plant Species Biol. 31 43–59.
Hartnett, D. C. (1990) Size-dependent allocation to sexual and vegetative reproduction in four clonal composites.Oecologia 84 254–9.
Holbrook, N. M. and Putz, F. E. (1989) Influence of neighbors on tree form: effects of lateral shade and prevention of sway on the allometry ofLiquidamabar syraciflua (sweet gum).Am. J. Bot. 76 1740–9.
Hubbell, S. P. and Foster, R. B. (1986) Commonness and rarity in a neotropical forest: implications for tropical tree conservation. InConservation Biology: The Science of Scarcity and Diversity (M. Soulé, ed.), pp. 205–31. Sinauer Associates, Sunderland, MA.
Iwasa, Y. and Cohen, D. (1989) Optimal growth schedule of a perennial plant.Am. Nat. 133 480–505.
Kato, R., Tadaki, Y. and Ogawa, H. (1978) Plant biomass and growth increment studies in Pasoh Forest.Malayan Nat. J. 30 211–24.
Kawano, S. and Nagai, Y. (1986) Regulatory mechanisms of reproductive effort in plants. I. Plasticity in reproductive energy allocation and propagule output ofHelianthus annuus L. (Compositae) cultivated at varying densities and nitrogen levels.Plant Species Biol. 1 1–18.
Kawano, S., Hayashi, S., Arai, H., Yamamoto, M., Takasu, H. and Oritani, T. (1989) Regulatory mechanisms of reproductive effort in plants. III. Plasticity in reproductive energy allocation and propagule output of two grass species,Oryza sativa cv.Akihikari andCoix ma-yuen cultivated at varying densities and nitrogen levels, and the evolutionary-ecological implications.Plant Species Biol. 4 75–99.
King, D. A. (1981) Tree dimensions: maximizing the rate of height growth in dense stands.Oecologia 51 351–6.
King, D. A. (1987) Load bearing capacity of understory treelets of a tropical wet forest.Bull. Torrey Bot. Club 114 419–28.
King, D. A. (1990a) The adaptive significance of tree height.Am. Nat. 135 809–28.
King, D. A. (1990b) Allometry of saplings and understory trees of a Panamanian forest.Funct. Ecol. 4 27–32.
King, D. A. (1991) Tree allometry, leaf size and adult tree size in old-growth forests of western Oregon.Tree Physiol. 9 369–81.
King, D. A. and Roughgarden, J. (1982) Graded allocation between vegetative and reproductive growth for annual plants in growing season of random length.Theor. Pop. Biol. 22 1–16.
Kira, T. (1978) Community architecture and organic matter dynamics in tropical lowland rainforests of Southeast Asia with special reference to Pasoh Forest, West Malaysia. InTropical Trees as Living Systems (P. B. Tomlinson and M. H. Zimmermann, eds), pp. 561–90. Cambridge University Press, Cambridge.
Klinkhamer, P. G. L., Meelis, E., DeJong, T. J. and Weiner, J. (1992) On the analysis of size-dependent reproductive output in plants.Funct. Ecol. 6 308–16.
Kohyama, T. (1987) Significance of architecture and allometry in saplings.Funct. Ecol. 1 399–404.
Kohyama, T. and Hotta, M. (1990) Significance of allometry in tropical saplings.Funct. Ecol. 4 515–21.
Kozlowski, J. and Uchmanski, J. (1987) Optimal individual growth and reproduction in perennial species with indeterminate growth.Evol. Ecol. 1 214–30.
McMahon, T. (1973) Size and shape in biology.Science 179 1201–4.
McMahon, T. A. and Kronauer, R. E. (1976) Tree structures: deducing the principle of mechanical design.J. Theor. Biol. 59 443–66.
Mäkelä, A. (1985) Differential games in evolutionary theory: height growth strategies of trees.Theor. Pop. Biol. 27 239–67.
Manokaran, N., LaFrankie, J. V., Kochummen, K. M., Quah, E. S., Klahn, J., Ashton, P. S. and Hubbell, S. P. (1990)Methodology for the 50-ha Research Plot at Pasoh Forest Reserve. Research Pamphlet, Forest Research Institute of Malaysia, Kepong, Malaysia.
Nagai, Y. and Kawano, S. (1986) Regulatory mechanisms of reproductive effort in plants. II. Plasticity in reproductive energy allocation and propagule output ofGlycine max Merr. (Leguminosae) cultivated at varying densities and nitrogen levels.Plant Species Biol. 1 181–94.
Niklas, K. J. (1992)Plant Biomechanics. University of Chicago Press, Chicago, IL.
Niklas, K. J. (1993) The allometry of plant reproductive biomass and stem diameter.Am. J. Bot. 80 461–7.
Niklas, K. J. (1994)Plant Allometry: The Scaling of Form and Process. University of Chicago Press, Chicago, IL.
Ogawa, H., Yoda, K., Ogino, K. and Kira, T. (1965) Comparative ecological studies on three main types of forest vegetation in Thailand. II. Plant biomass.Nat. Life Southeast Asia 4 49–80.
Peters, R., Cloutier, S., Dubé, D., Evans, A., Hastings, P., Kaiser, H., Kohn, D. and Sarwer-Foner, B. (1988) The allometry of the weight of fruit on trees and shrubs in Barbados.Oecologia 74 612–16.
Rees, M. and Crawley, M. (1989) Growth, reproduction and population dynamics.Funct. Ecol. 3 645–53.
Rice, W.R. (1989) Analyzing tables of statistical tests.Evolution 43, 223–225.
Ricker, W. E. (1984) Computation and uses of central trend lines.Can. J. Zool. 62 1897–905.
Roff, D. A. (1992)The Evolution of Life Histories. Chapman & Hall, New York, NY.
Samson, D. A. and Werk, K. S. (1986) Size-dependent effects in the analysis of reproductive effort in plants.Am. Nat. 127 667–80.
Seim, E. and Sæther, B. -E. (1983) On rethinking allometry: which regression model to use?J. Theor. Biol. 104 161–8.
Shipley, B. and Dion, J. (1992) The allometry of seed production in herbaceous angiosperms.Am. Nat. 139 467–83.
Sokal, R. R. and Rohlf, F. J. (1981)Biometry, 2nd edn. Freeman, New York, NY.
Thomas, S. C. (1993) Interspecific allometry in Malaysian rain forest trees. PhD dissertation, Harvard University, Cambridge, MA.
Thomas, S. C. (1996) Asymptotic height as a predictor of growth and allometric characteristics of Malaysian rain forest trees.Am. J. Bot. 83, 556–566.
Thomas, S. C. (in press) Relative size at onset of maturity in rain forest trees: a comparative analysis of 37 Malaysian species.Oikos.
Thomas, S. C. and Ickes, K. (1995) Ontogenetic changes in leaf size in Malaysian rain forest trees.Biotropica 27, 427–434.
Thomas, S. C. and LaFrankie, J. V. (1993) Sex, size, and interyear variation in flowering among dioecious trees of the Malayan rain forest.Ecology 74 1529–37.
Thomas, S. C. and Weiner, J. (1989) Growth, death, and size distribution change in a population ofImpatiens pallida.J. Ecol. 77 524–36.
Thompson, B. K., Weiner, J. and Warwick, S. I. (1991) Size-dependent reproductive output in agricultural weeds.Can. J. Bot. 69 442–6.
Weiner, J. (1988) The influence of competition on plant reproduction. InReproductive Ecology of Plants: Patterns and Strategies (J. Lovett-Doust and L. Lovett-Doust, eds), pp. 228–45. Oxford University Press, New York, NY.
Weiner, J. and Thomas, S. C. (1988) Competition and allometry in three species of annual plants.Ecology 73 648–56.
White, P. (1983) Corner's rules in eastern deciduous trees: allometry and its implications for the adaptive architecture of trees.Bull. Torrey Bot. Club 110 203–12.
Wilson, B. F. and Archer, R. R. (1979) Tree design: some biological solutions to mechanical problems.Bioscience 29 293–8.
Wootton, R. J. (1979) Energy costs of egg production and environmental determinants of fecundity in teleost fishes.Symp. Zool. Soc. Lond. 44 133–59.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Thomas, S.C. Reproductive allometry in Malaysian rain forest trees: Biomechanics versus optimal allocation. Evol Ecol 10, 517–530 (1996). https://doi.org/10.1007/BF01237882
Issue Date:
DOI: https://doi.org/10.1007/BF01237882