Abstract
Bracken,Pteridium aquilinum, exerts a strong dominance over associated plants throughout much of its worldwide range. Associated plants are often severely inhibited or even excluded from dense stands of the fern. This study investigated the various aspects of herb suppression in bracken stands and assessed the contribution of the various forms of interference between plants to the establishment and maintenance of bracken dominance. It was shown that competition for soil moisture, light, and nutrients could not account for the lack of herbs in bracken stands. Further, uniformity of soil pH, texture, water-holding capacity, and organic matter content ruled out variability in physical factors as a cause. Baiting and trapping experiments showed that the higher concentration of animal activity inside the bracken stands contributed significantly to the pattern of herb suppression, but only against select species. The maintenance of this pattern in the animal-free Santa Cruz Island stands indicates the importance of another factor, allelopathy. It was found that phytotoxins leached from the dead, standing bracken fronds with the first few rains of the wet season were largely responsible for herb suppression. These toxins were isolated in raindrip and from soil inside the fern stands. Removal of the fronds from the stand before the rains could leach them resulted in reinvasion by the herbs after several seasons, and, conversely, placing fronds over the herbs in the grassland brought about herb inhibition. A number of known allelopathic chemicals were tentatively identified from bracken leachates. The importance of the interaction of allelopathy with other factors of plant interference is illustrated by bracken.
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References
Bartholomew, Bruce. 1970. Bare zone between California shrub and grassland communities: The role of animals.Science 170:1210–1212.
Bear, F.E. (ed.). 1964. Chemistry of the Soil. Reinhold Publishing, New York, 515 pp.
Bills, Albin R. 1969. A study of the distribution and morphology of the mice of Santa Cruz Island: An example of divergence. M.A. thesis (unpublished). University of California, Santa Barbara.
Bohm, B.A., andTryon, R.M. 1967. Phenolic compounds in ferns. I. A survey of some ferns for cinnamic acid and benzoic acid derivatives.Can. J. Bot. 45:585–594.
Bouyoucos, G.J. 1936. Directions for making mechanical analyses of soils by the hydrometer method.Soil Sci. 42:225–230.
Braid, K.W. 1959. Bracken: A review of the literature.Commonw. Agric. Bur. Pub. 3/1959. 69 pp.
Cartledge, O., andCarnahan, J.A. 1971. Studies of austral bracken (Pteridium esculentum) in the vicinity of Canberra.New Phytol. 70:619–626.
Chapman, H.D., andPratt, P.F. 1961. Methods of analysis for soils, plants, and waters.Univ. Calif. Agric. Pub. 309 pp.
Dibblee, T.W., Jr. 1966. Geology of the Central Santa Ynez Mountains, Santa Barbara County, California.Calif. Div. Mines Geol. Bull. 186. 99 pp.
Gliessman, S.R. 1976. Allelopathy in a broad spectrum of environments as illustrated by bracken.Bot. J. Linn. Soc. 73:95–104.
Gliessman, S.R., andMuller, C.H. 1972. The phytotoxic potential of bracken (Pteridium aquilinum (L.) Kuhn.).Madroño 21:299–304.
Hais, I.M., andMacek, K. 1963. Paper chromatography.Czech. Acad. Sci. 955 pp. (cf. pp. 785–786).
Ingles, L.G. 1965. Mammals of the Pacific States. Stanford Univ. Press, Stanford. 506 pp. (cf. pp. 245–294).
Jackson, M.L. 1958. Soil Chemical Analysis. Prentice-Hall, New Jersey. 498 pp.
Jeffries, H. 1917. On the vegetation of four Durham coal-measure fells. III. On water-supply as an ecological factor.J. Ecol. 5:129–154.
McPherson, J.K., andMuller, C.H. 1969. Allelopathic effect ofAdenostoma fasciculatum, “chamise”, in the California chaparral.Ecol. Monogr. 39:177–198.
McPherson, J.K., Chou, C.-H., andMuller, C.H. 1971. Allelopathic constituents of the chaparral shrubAdenostoma fasciculatum.Phytochemistry 10:2925–2933.
Muller, C.H. 1969. Allelopathy as a factor in ecological process.Vegetatio 16:348–357.
Munz, P.A., andKeck, D.D. 1959. A California Flora. University of California Press, Berkeley. 1681 pp.
Russell, E.W. 1961. Soil Conditions and Plant Growth. Wiley, New York. 688 pp.
Stewart, R.E. 1975. Allelopathic potential of western bracken.J. Chem. Ecol. 1:161–169.
Watt, Alex S. 1945. Contributions to the ecology of bracken. (Pteridium aquilinum). III. Frond type and the makeup of the population.New Phytol. 44:156–178.
Watt, Alex S. 1947. Contributions to the ecology of bracken. (Pteridium aquilinum). IV. The structure of the community.New Phytol. 46:97–121.
Watt, Alex S. 1970. Contributions to the ecology of bracken. (Pteridium aquilinum). VII. Bracken and litter. 3. The cycle of change.New Phytol. 69:431–449.
Watt, Alex S. 1971. Contributions to the ecology of bracken. (Pteridium aquilinum). VIII. The marginal and the hinterland plant: A study in senescence.New Phytol. 70:967–986.
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This work was supported by an NDEA Fellowship to the first author and by NSF grants GB 4058 and GB 14891 to the second author. Thanks are due to Dr. N. Christensen for much help with the graphs and to Mr. R. Broder for aid in the identification of plants. We are obliged to Dr. R. Hanawalt for the soil mineral nutrient measurements. The second author thanks the Department of Botany of the University of Texas at Austin for manuscript preparation during his annual residence there.
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Gliessman, S.R., Muller, C.H. The allelopathic mechanisms of dominance in bracken (Pteridium aquilinum) in Southern California. J Chem Ecol 4, 337–362 (1978). https://doi.org/10.1007/BF00989342
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DOI: https://doi.org/10.1007/BF00989342