Abstract
The velamen radicum, a spongy, usually multiple epidermis of the roots, which at maturity consists of dead cells, is frequently described as an important adaptation of epiphytic orchids. Yet, quantitative evidence for the alleged functions, e.g., efficient water and nutrient uptake, nutrient retention, reduction of water loss, mechanical protection, or the avoidance of overheating, is rare or missing. We tested the notion originally put forward by Went in 1940 that the velamen allows plants to capture and immobilize the first solutions arriving in a rainfall, which are the most heavily charged with nutrients. In a series of experiments, we examined whether all necessary functional characteristics are given for this scenario to be realistic under ecological conditions. First, we show that the velamen of a large number of orchid species takes up solutions within seconds, while evaporation from the velamen takes several hours. Charged ions are retained in the velamen probably due to positive and negative charges in the cell walls, while uncharged compounds are lost to the external medium. Finally, we demonstrate that nutrient uptake follows biphasic kinetics with a highly efficient, active transport system at low external concentrations. Thus, our results lend strong support to Went’s hypothesis: the velamen fulfills an important function in nutrient uptake in the epiphytic habitat. Most of the other functions outlined above still await similar experimental scrutiny.
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References
Antibus RK, Lesica P (1990) Root surface acid phosphatase activities of vascular epiphytes of a Costa Rican rain forest. Plant Soil 128:233–240
Bates JW (1989) Retention of added K, Ca and P by Pseudoscleropodium purum growing under an oak canopy. J Bryol 15:589–605
Benzing DH (1990) Vascular epiphytes. General biology and related biota. Cambridge University Press, Cambridge
Benzing DH (1996) Aerial roots and their environments. In: Waisel Y, Eshel A, Kafkafi U (eds) Plant roots: the hidden half. Marcel Dekker, New York, pp 875–894
Benzing DH (2000) Bromeliaceae—profile of an adaptive radiation. Cambridge University Press, Cambridge
Benzing DH, Ott DW, Friedman WE (1982) Roots of Sobralia macrantha (Orchidaceae): structure and function of the velamen–exodermis complex. Am J Bot 69:608–614
Böttger M, Soll H, Gasche A (1980) Modification of the external pH by maize coleoptlies and velamen radicum of Vanilla planifolia. Z Pflanzenphysiol 48:81–96
Brundrett M (2009) Mycorrhizal associations and other means of nutrition of vascular plants: understanding the global diversity of host plants by resolving conflicting information and developing reliable means of diagnosis. Plant Soil 320:37–77
Capesius I, Barthlott W (1975) Isotopen-Markierungen und rasterelektronenmikroskopische Untersuchungen am Velamen radicum der Orchideen. Z Pflanzenphysiol 75:436–448
Dahlmann L, Persson J, Palmquist K, Näsholm T (2004) Organic and inorganic nitrogen uptake in lichens. Planta 129:459–467
Dycus AM, Knudson L (1957) The role of the velamen of the aerial roots of orchids. Bot Gaz 119:78–87
Gillet C, Lefebvre J (1980) Estimation of anion-exchange capacity of cell walls of Nitella flexilis. J Exp Bot 32:37–41
Goebel K (1921) Erdwurzeln mit Velamen. Flora 115:1–26
Goh CJ, Kluge M (1989) Gas exchange and water relations in epiphytic orchids. In: Lüttge U (ed) Vascular plants as epiphytes: evolution and ecophysiology, vol 76. Springer, Heidelberg, pp 139–166
Haas NF (1975) 32P, 22N, und 99Tc in Versuchen über den Wassertransport in Luftwurzeln von Vanda tricolor Lindl. Z Pflanzenphysiol 75:427–435
Haberlandt GFJ (1914) Physiological plant anatomy. Macmillan, London
Hájek T, Adamec L (2009) Mineral nutrient economy in competing species of Sphagnum mosses. Ecol Res 24:291–302
Helbsing S, Riederer M, Zotz G (2000) Cuticles of vascular epiphytes: efficient barriers for water loss after stomatal closure? Ann Bot 86:765–769
Inselsbacher E, Cambui CA, Richter A, Stange CF, Mercier H, Wanek W (2007) Microbial activities and foliar uptake of nitrogen in the epiphytic bromeliad Vriesea gigantea. New Phytol 175:311–320
Jordan PW, Nobel PS (1984) Thermal and water relations of roots of desert succulents. Ann Bot 54:705–717
Läuchli A, Epstein E (1970) Transport of potassium and rubidium in plant roots: the significance of calcium. Plant Physiol 45:639–641
Link HF (1824) Elementa philosophiae botanicae. Haude & Spenersche, Berlin
Lüttge U (1997) Physiological ecology of tropical plants. Springer, Berlin
Mulay BN, Deshpande BU, Williams HP (1958) Study of velamen in some epiphytic and terrestrial orchids. J Indian Bot Soc 37:123–127
Porembski S, Barthlott W (1995) On the occurrence of a velamen radicum in Cyperaceae and Velloziaceae. Nordic J Bot 15:625–629
Pridgeon AM (1987) The velamen and exodermis of orchid roots. In: Arditti J (ed) Orchid biology. Reviews and perspectives IV. Cornell University Press, Ithaca, pp 139–192
R Development Core Team (2010) R: a language and environment for statistical computing. R Foundation for Statistical Computing, Vienna
Richardson BA, Rogers C, Richardson MJ (2000) Nutrients, diversity and community structure of two phytotelm systems in a lower montane forest, Puerto Rico. Ecol Entomol 25:348–356
Richter C, Dainty J (1989) Ion behavior in plant cell walls. I. Characterization of the Sphagnum russowii cell wall ion exchanger. Can J Bot 67:451–459
Roth-Nebelsick A (2009) Pull, push and evaporate. The role of surfaces in plant water transport. In: Gorb S (ed) Functional surfaces in biology. Little structures with big effects, vol 1. Springer, Berlin, pp 141–162
Sanford WW, Adanlawo FLS, Adanlawo I (1973) Velamen and exodermis characters of west African epiphytic orchids in relation to taxonomic grouping and habitat tolerance. Bot J Linn Soc 66:307–321
Tsavkelova EA, Lobakova ES, Kolomeitseva GL, Cherdyntseva TA, Netrusov AI (2003) Associative cyanobacteria isolated from the roots of epiphytic orchids. Microbiology 72:92–97
Wallach A (1939) Beiträge zur Kenntnis der Wasseraufnahme durch die Luftwurzeln tropischer Orchideen. Z Bot 33:433–468
WCSP (2012) World checklist of selected plant families. Facilitated by the Royal Botanic Gardens, Kew. http://apps.kew.org/wcsp/. Retrieved 2 Feb 2012
Went FW (1940) Soziologie der Epiphyten eines tropischen Regenwaldes. Ann Jard Bot Buitenzorg 50:1–98
Winkler U, Zotz G (2009) Highly efficient uptake of phosphorus in epiphytic bromeliads. Ann Bot 103:477–484
Winkler U, Zotz G (2010) “And then there were three”: highly efficient uptake of potassium by foliar trichomes of epiphytic bromeliads. Ann Bot 106:421–427
Yen W-Y, Chang Y-CA, Wang Y-T (2011) The acidification of Sphagnum moss substrate during Phalaenopsis cultivation. Hortscience 46:1022–1026
Zotz G, Hietz P (2001) The physiological ecology of vascular epiphytes: current knowledge, open questions. J Exp Bot 52:2067–2078
Acknowledgments
We thank Inga Schul and Niels Plump (both University Oldenburg) for technical help. Constructive comments of two anonymous reviewers on an earlier version helped to improve the clarity of the paper. We acknowledge permits to export plant material from Panama.
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Communicated by Russell Monson.
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Zotz, G., Winkler, U. Aerial roots of epiphytic orchids: the velamen radicum and its role in water and nutrient uptake. Oecologia 171, 733–741 (2013). https://doi.org/10.1007/s00442-012-2575-6
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DOI: https://doi.org/10.1007/s00442-012-2575-6