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Measuring the terminal velocity of tiny diaspores

Published online by Cambridge University Press:  08 July 2016

Gerhard Zotz ,
Tizian Weichgrebe ,
Harry Happatz  and
Helena J.R. Einzmann
Gerhard Zotz*
Affiliation:
Functional Ecology of Plants, Institute of Biology and Environmental Sciences, University of Oldenburg, PO Box 2503, D-26111 Oldenburg, Germany Smithsonian Tropical Research Institute, Apdo 08343-03092, Panama, Republic of Panama
Tizian Weichgrebe
Affiliation:
Functional Ecology of Plants, Institute of Biology and Environmental Sciences, University of Oldenburg, PO Box 2503, D-26111 Oldenburg, Germany
Harry Happatz
Affiliation:
Technical-Scientific Infrastructure Unit, Electronics Department, University of Oldenburg, PO Box 2503, D-26111 Oldenburg, Germany
Helena J.R. Einzmann
Affiliation:
Functional Ecology of Plants, Institute of Biology and Environmental Sciences, University of Oldenburg, PO Box 2503, D-26111 Oldenburg, Germany
*
*Correspondence Fax: +49 441 7983331 Email: [email protected]
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Abstract

Although it has long been acknowledged that seed characteristics are of major importance to the conquest of tree crowns by vascular epiphytes, there is surprisingly little quantitative evidence on the aerodynamic properties of their diaspores. We used a custom-built device to determine the terminal velocity (Vterm) of falling seeds, a parameter that has been shown to have high predictive power for the wind dispersal potential of diaspores under natural conditions. We determined Vterm of 45 species of epiphytic and terrestrial Orchidaceae, which almost doubles the currently available database for this family. Although varying by a factor of five with values of 0.09–0.4 m s−1, Vterm was invariably very slow compared to plants in general. For each species, we also took morphological data and determined seed mass. None of these parameters was linearly correlated with Vterm and neither did the average Vterm differ between species found in the two habitats, although seeds of terrestrial taxa were significantly larger and heavier. Finally, we demonstrate the potential of our device to measure Vterm of even smaller diaspores by successfully quantifying Vterm of fern spores. This tool has much potential for the quantitative study of dispersal of plants with tiny diaspores, particularly in a conservation context in fragmented landscapes.

Keywords

dispersaldust seedselatersepiphytesfernslife formOrchidaceaespores
Type
Research Papers
Information
Seed Science Research , Volume 26 , Issue 3 , September 2016 , pp. 222 - 230
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Copyright
Copyright © Cambridge University Press 2016 

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References

Arditti, J. (1992) Fundamentals of orchid biology. New York, Wiley-Liss.Google Scholar
Arditti, J. and Ghani, A.K.A. (2000) Numerical and physical properties of orchid seeds and their biological implications. New Phytologist 145, 367421.CrossRefGoogle ScholarPubMed
Askew, A.P., Corker, D., Hodkinson, D.J. and Thompson, K. (1997) A new apparatus to measure the rate of fall of seeds. Functional Ecology 11, 121125.CrossRefGoogle Scholar
Benzing, D.H. (2000) Bromeliaceae – profile of an adaptive radiation. Cambridge, Cambridge University Press.CrossRefGoogle Scholar
Burgeff, H. (1936) Samenkeimung der Orchideen und Entwicklung ihrer Keimpflanzen. Jena, Gustav Fischer.Google Scholar
Gamarra, R., Galan, P., Pedersen, H.A., Ortunez, E. and Sanz, E. (2015) Seed micromorphology in Dactylorhiza Necker ex Nevski (Orchidaceae) and allied genera. Turkish Journal of Botany 39, 298309.CrossRefGoogle Scholar
Gandawijaja, D. and Arditti, J. (1983) The orchids of Krakatau: evidence for a mode of transport. Annals of Botany 52, 127130.CrossRefGoogle Scholar
Hallé, N. (1986) Les elateres des Sarcanthinae et additions aux Orchidaceae de la Nouvelle-Caledonie. Bulletin du Museum national d'Histoire naturelle, Paris, 4e ser., 8, section B, Adansonia 3, 215239.Google Scholar
Hintze, C., Heydel, F., Hoppe, C., Cunze, S., König, A. and Tackenberg, O. (2013) D3: the dispersal and diaspore database – baseline data and statistics on seed dispersal. Perspectives in Plant Ecology, Evolution and Systematics 15, 180192.CrossRefGoogle Scholar
Murren, C.J. and Ellison, A.M. (1998) Seed dispersal characteristics of Brassavola nodosa (Orchidaceae). American Journal of Botany 85, 675680.CrossRefGoogle ScholarPubMed
Nathan, R., Katul, G.G., Bohrer, G., Kuparinen, A., Soons, M.B., Thompson, S.E., Trakhtenbrot, A. and Horn, H.S. (2011) Mechanistic models of seed dispersal by wind. Theoretical Ecology 4, 113132.CrossRefGoogle Scholar
Poltz, K. and Zotz, G. (2011) Vascular epiphytes on isolated pasture trees along a rainfall gradient in the lowlands of Panama. Biotropica 43, 165172.CrossRefGoogle Scholar
Prillieux, M.E. (1857) Observations sur la déhiscence des Orchidées. Bulletin de la Société Botanique de France 4, 803809.CrossRefGoogle Scholar
R Development Core Team (2014) R: A language and environment for statistical computing, Vienna, Austria, R Foundation for Statistical Computing.Google Scholar
Schäfer, M. (2002) Realitätsbezogener Mechanikunterricht durch Beiträge der Strömungsphysik. Göttingen, Deutsches Zentrum für Luft- und Raumfahrt e.V. Google Scholar
Schimper, A.F.W. (1888) Die epiphytische Vegetation Amerikas. Jena, Gustav Fischer.Google Scholar
Tackenberg, O. (2003) Modeling long-distance dispersal of plant diaspores by wind. Ecological Monographs 73, 173189.CrossRefGoogle Scholar
Tackenberg, O., Poschlod, P. and Bonn, S. (2003) Assessment of wind dispersal potential in plant species. Ecological Monographs 73, 191205.CrossRefGoogle Scholar
The Plant List (2013) Version 1.1. Available at http://www.theplantlist.org/ (accessed 10 December 2015).Google Scholar
Tsutsumi, C., Yukawa, T., Lee, N.S., Lee, C.S. and Kato, M. (2007) Phylogeny and comparative seed morphology of epiphytic and terrestrial species of Liparis (Orchidaceae) in Japan. Journal of Plant Research 120, 405412.CrossRefGoogle ScholarPubMed
Weiher, E., van der Werf, A., Thompson, K., Roderick, M., Garnier, E. and Eriksson, O. (1999) Challenging Theophrastus: a common core list of plant traits for functional ecology. Journal of Vegetation Science 10, 609620.CrossRefGoogle Scholar
Werner, F.A. and Gradstein, S.R. (2008) Seedling establishment of vascular epiphytes on isolated and enclosed forest trees in an Andean landscape, Ecuador. Biodiversity and Conservation 17, 31953207.CrossRefGoogle Scholar
Yoder, J.A., Imfeld, S.M., Heydinger, D.J., Hart, C.E., Collier, M.H., Gribbins, K.M. and Zettler, L.W. (2010) Comparative water balance profiles of Orchidaceae seeds for epiphytic and terrestrial taxa endemic to North America. Plant Ecology 211, 717.CrossRefGoogle Scholar
Zhang, F.-P., Zhang, J.-J., Yan, N., Hu, H. and Zhang, S.-B. (2015) Variations in seed micromorphology of Paphiopedilum and Cypripedium (Cypripedioideae, Orchidaceae). Seed Science Research 25, 395401.CrossRefGoogle Scholar
Zotz, G. (2005) Vascular epiphytes in the temperate zones – a review. Plant Ecology 176, 173183.CrossRefGoogle Scholar
Zotz, G. (2013) The systematic distribution of vascular epiphytes – a critical update. Botanical Journal of the Linnean Society 171, 453481.CrossRefGoogle Scholar
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