Summary
To explore principles of organismic design in fluctuating environments, morphological design of the leaf of the pitcher-plant, Sarracenia purpurea, was studied for a population in northern Michigan. The design criterion focused upon the leaf shape and minimum size which effectively avoids leaf desiccation (complete loss of fluid from the leaf cavity) in the face of fluctuating rainfall and meteorological conditions. Bowl- and pitcher-shaped leaves were considered. Simulations show that the pitcher geometry experiences less frequent desiccation than bowls of the same size. Desiccation frequency is inversely related to leaf size; the size distribution of pitcher leaves in the field shows that the majority of pitchers desiccate only 1–3 times per season on average, while smaller pitchers may average up to 8 times per season. A linear filter model of an organism in a fluctuating environment is presented, in which the organism selectively filters the temporal patterns of environmental input. General measures of rainfall predictability based upon information theory and spectral analysis are consistent with the model of a pitcher leaf as a low-pass (frequency) filter which avoids desiccation by eliminating high-frequency rainfall variability.
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References
Addicott JF (1974) Predation and prey community structure: an experimental study of the effect of mosquito larvae on the protozoan communities of pitcher plants. Ecology 55:475–92
Blackman RB, Tukey JW, (1958) The measurement of power spectra from the point of view of communications engineering. Dover, New York
Colwell RK (1974) Predictability, constancy, and contingency of periodic phenomena. Ecology 55:1148–53
Haldane JBS, Jayakar SD (1963) Polymorphism due to selection of varying direction. J Genet 58:237–42
Haughton PM, Sellen DB, Preston RD (1968) Dynamic properties of Nitella cell walls. J exp Bot 19:1–12
Hepburn JS (1927) Work of previous investigators on the biochemistry of Sarraceniaceae. Trans Wagner Free Institute of Science 11:3–23
Hubbell SP (1973) Populations and simple food webs as energy filters. I. One-species systems. Am Nat 107:94–121
Jenkins GM, Watts DG (1968) Spectral analysis and its applications. Holden-Day, San Francisco
Kingsolver JG (1979) Thermal and hydric aspects of environmental heterogeneity in the pitcher plant mosquito. Ecol Mono 49:357–376
Koehl MAR (1977a) Mechanical diversity of connective tissue of the body wall of sea anemones. J exp Biol 69:102–125
Koehl MAR (1977b) Mechanical organization of cantilever-like sessile organisms: sea anemones. J exp Biol 69:127–142
Levins R (1968) Evolution in changing environments. Princeton University Press, Princeton, NJ
Lloyd FW (1942) The carnivorous plants. Chronica Botanica Co. Waltham Mass
Monteith JL (1973) Principles of environmental physics. Edward Arnolds Ltd. London
Roughgarden J (1974) Population dynamics in a spatially varying environment; how population size “tracks” spatial variation in carrying capacity. Amer Nat 108:649–664
Roughgarden J (1975) A simple model for population dynamics in stochastic environments. Amer Nat 109:713–736
Wainwright SA, Biggs WD, Currey JD, Gosline JM (1976) Mechanical design in organisms. Halsted Press New York
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Kingsolver, J. The effect of environmental uncertainty on morphological design and fluid balance in Sarracenia purpurea L.. Oecologia 48, 364–370 (1981). https://doi.org/10.1007/BF00346496
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DOI: https://doi.org/10.1007/BF00346496