Abstract
The capability of clonal plants to reproduce both sexually and vegetatively and their resulting hierarchical organisation into ramets and genets pose problems for the determination of fitness. We develop ramet-based measures of clonal plant fitness including both modes of reproduction. To this end we use simple population-dynamic equations accounting for limited space, limited dispersal, and disturbance. Neglecting interactions among ramets (r-selection regime) we derive an expression for initial growth rate r as a fitness measure. At higher densities interactions among ramets lead to density control (K-selection regime) and competitive exclusion of genotypes or species may occur. In this case we apply an invasibility criterion to derive an abundance fitness measure: competitiveness C. The optimum of C corresponds to an evolutionary stable strategy. C increases with the proportion of reproductive adults, with inverse module mortality, and with the sum of sexual and vegetative reproduction. The latter are defined as the product of the rate of module production and two correction factors accounting for juvenile mortality before establishment and for the efficiency of space exploitation by propagules. Thus C is equivalent to potential life-time offspring production, in contrast to realized life-time offspring production R0. Because the correction factor for space exploitation cannot be expressed analytically we obtain it from complementary spatially-explicit individual-based simulations. To illustrate an application of the fitness measure C we predict optimal allocation to vegetative and sexual reproduction. In a homogeneous habitat an intermediate allocation may maximize fitness only if there is a non-linear trade-off between the modes of reproduction. However even if this trade-off is linear, spatially heterogenous disturbances can lead to an intermediate optimum of allocation because seed dispersal with subsequent vegetative spread improves the utilization of available space for recruitment if the spatial extent of single disturbances is much larger than the distance of vegetative dispersal. Thus, our study underlines the importance of spatial features for fitness measures especially of clonal plants.
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References
Ågren, G. I. & Fagerström, T. 1984. Limiting dissimilarity in plants: randomness prevents exclusion of species with similar competitive abilities. Oikos 43: 369–375.
Caswell, H. & John, A. M. 1992. From the individual to the population in demographic models. Pp. 36–61. In: De Angelis, D. L. & Gross, L. J. (eds). Individual-based models and approaches in ecology. Chapman and Hall, New York.
Charlesworth, B. 1994. Evolution in age-structured populations. Cambridge University Press, Cambridge.
Fagerström, T. 1992. The meristem-meristem cycle as a basis for defining fitness in clonal plants. Oikos 63: 449–453.
Fagerström, T. & Ågren, G. I. 1979. Theory for coexistence of species differing in regeneration properties. Oikos 33: 1–10.
Fagerström, T. & Westoby, M. 1997. Population dynamics in sessile organisms: some general results from three seemingly different theory-lineages. Oikos 80: 588–594.
Gardner, S. N. 1997. Theoretical and empirical studies of plant lifehistory variation. Ph.D. dissertation, University of California, Davis.
Gardner, S. N. & Mangel, M. 1997. When can a clonal organism escape senescence? Am. Nat. 150: 462–490.
Geritz, S. A. H., Metz, J. A. J., Klinkhamer, P. G. L. & de Jong, T. J. 1988. Competition in safe-sites. Theor. Pop. Biol. 33: 161–180.
Harada, Y. & Iwasa, Y. 1994. Lattice population dynamics for plants with dispersing seeds and vegetative propagation. Res. Popul. Ecol. 36: 237–249.
Harada, Y. & Iwasa, Y. 1996. Analyses of spatial patterns and population processes of clonal plants. Res. Popul. Ecol. 38: 153–164.
Huston, M., De Angelis, D. & Post, W. 1988. New computer models unify ecological theory. BioScience 38: 682–691. 199
Koz?owski, J. 1980. Density dependence, the logistic equation, and r-and K-selection: a critique and an alternative approach. Evolut. Theory 5: 89–101.
Liljelund, L.-E., Ågren, G. I. & Fagerström, T. 1988. Succession in stationary environments generated by interspecific differences in life-history parameters. Ann. Zool. Fennici 25: 17–22.
Loehle, C. 1987. Partitioning of reproductive effort in clonal plants: a benefit-cost model. Oikos 49: 199–208.
Maynard Smith, J. 1989. Evolutionary genetics. Oxford University Press, Oxford.
Mylius, S. D. & Diekmann, O. 1995. On evolutionary stable life histories, optimization and the need to be specific about density dependence. Oikos 74: 218–224.
Pacala, S. W. 1997. Dynamics of plant communities. Pp. 532–555. In: Crawley, M. J. (ed.), Plant ecology, 2nd ed., Blackwell Scientific, London.
Pedersen, B. & Tuomi, J.1995. Hierarchical selection and fitness in modular and clonal organisms. Oikos 73: 167–180.
Pitelka, L. F. & Ashmun, J. W. 1985. Physiology and integration of ramets in clonal plants. Pp. 399–435.In: Jackson, J. B. C., Buss, L. W., Cook, R. E. (eds.), Population biology and evolution of clonal organisms. Yale Univ. Press, New Haven.
Rees, M. 1997. Biological control of Scotch broom: Modelling the determinants of abundance and the potential impact of introduced insect herbivores. J. Appl. Ecol. 34: 1203–1221.
Ronce, O. & Olivieri, I. 1997. Evolution of reproductive effort in a metapopulation with local extinction and ecological succession. Am. Nat. 150: 221–249.
Sackville Hamilton, N. R., Schmid, B. & Harper, J. L. 1987. Lifehistory concepts and the population biology of clonal organisms. Proc. R. Soc. Lond. B232: 35–57.
Schmid, B., Bazzaz, F. A. & Weiner, J. 1995. Size dependency of sexual reproduction and of clonal growth in two perennial plants. Can. J. Bot. 73: 1831–1837.
Skellam, J. G. 1951. Random dispersal in theoretical populations. Biometrika 38: 196–218.
Stearns, S. C. 1992. The evolution of life histories. Oxford University Press, Oxford.
Tilman, D. 1994.Competition and biodiversity in spatially structured habitats. Ecology 75: 2–16.
Tuomi, J. & Vuorisalo, T. 1989. What are the units of selection in modular organisms. Oikos 54: 227–233.
Wikberg, S. 1995. Fitness in clonal plants. Oikos: 72: 293–297.
Winkler, E. & Schmid, B. 1995. Clonal strategies of herbaceous plant species: a simulation study on population growth and competition. In: Oborny, B. & Podani, J. (eds), Clonality in plant communities. Proceedings of the 4th International Workshop on Clonal Plants. Abstracta Botanica 19: 17–28.
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Winkler, E., Fischer, M. Two fitness measures for clonal plants and the importance of spatial aspects. Plant Ecology 141, 191–199 (1999). https://doi.org/10.1023/A:1009843619713
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DOI: https://doi.org/10.1023/A:1009843619713