Abstract
Although desiccation tolerance is common in non-vascular plants, this adaptive trait is very rare in vascular plants. Desiccation-tolerant vascular plants occur particularly on rock outcrops in the tropics and to a lesser extent in temperate zones. They are found from sea level up to 2800 m. The diversity of desiccation-tolerant species as measured by number of species is highest in East Africa, Madagascar and Brazil, where granitic and gneissic outcrops, or inselbergs, are their main habitat. Inselbergs frequently occur as isolated monoliths characterized by extreme environmental conditions (i.e., edaphic dryness, high degrees of insolation). On tropical inselbergs, desiccation-tolerant monocotyledons (i.e., Cyperaceae and Velloziaceae) dominate in mat-like communities which cover even steep slopes. Mat-forming desiccation-tolerant species may attain considerable age (hundreds of years) and size (several m in height, for pseudostemmed species). Both homoiochlorophyllous and poikilochlorophyllous species occur. In their natural habitats, both groups survive dry periods of several months and regain their photosynthetic activity within a few days after rainfall. Other desiccation-tolerant species colonize shallow depressions, crevices and even temporarily water-filled rock pools on inselbergs. Desiccation-tolerant vascular plants occur in 13 families and are best represented within the monocotyledons and ferns. Only a few desiccation-tolerant dicots exist, in the Gesneriaceae, Myrothamnaceae and Scrophulariaceae. In total, about 330 species of vascular desiccation-tolerant plants are known, of which nearly 90% occur on inselbergs. With regard to morphological adaptations, the mat-forming monocotyledons are particularly remarkable due to the possession of roots with a velamen radicum, which is reported here in the genus Borya for the first time.
This is a preview of subscription content, log in via an institution to check access.
References
Alves, R. J. V. 1994. Morphological age determination and longevity in some Vellozia populations in Brazil. Folia Geobot. Phytotax. 29: 55–59.
Ayensu, E. S. 1974. Leaf anatomy and systematics of New World Velloziaceae. Smithonian Contr. Bot. 15: 1–125.
Ayo-Owoseye, J. & Sanford, W. W. 1972. An ecological study of Vellozia schnitzleinia, a drought-enduring plant of northern Nigeria. J. Ecol. 60: 807–817.
Bartels, D., Furini, A., Bockel, C., Frank, W. & Salamini F. 1996. Gene expression during dehydration stress in the resurrection plant Craterostigma plantagineum. Pp. 117–122. In: Grillo, S. & Leone, A. (eds), Physical stress in plants. Springer-Verlag, Berlin.
Barthlott, W. & Capesius, I. 1975. Mikromorphologische und funktionelle Untersuchungen am Velamen radicum der Orchideen. Ber. Dt. Bot. Ges. 88: 379–390.
Barthlott, W., Gröger, A. & Porembski, S. 1993. Some remarks on the vegetation of tropical inselbergs: diversity and ecological differentiation. Biogéographica 69: 105–124.
Bewley, J. D. 1979. Physiological aspects of desiccation tolerance. Annu. Rev. Plant Physiol. 30: 195–238.
Bewley, J. D. 1995. Physiological aspects of desiccation tolerance -a retrospect. Int. J. Plant Sci. 156: 393–403.
Bonardi, B. 1966. Contribution à l'étude botanique des inselbergs de Cô te d'Ivoire forestiè re. Dipl. Ét. sup., Abidjan.
Carlquist S. 1976. Wood anatomy of Myrothamnus flabellifolia (Myrothamnaceae) and the problem of multiperforate perforation plates. J. Arnold Arbor. 57: 119–126.
Dinter, K. 1918. Botanische Reisen in Deutsch-Südwest-Afrika. Feddes Rep. Beih. 3: 1–169.
Engler, A. & Krause, K. 1911. Ñber den anatomischen Bau der baumartigen Cyperaceae Schoenodendron bücheri Engl. aus Kamerun. Abh. Kgl. Preuß . Akad. d. Wissensch. 1911.
Fahn, A. & Cutler, D. F. 1992. Xerophytes. In: Braun, H. J., Carlquist, S., Ozenda, P. & Roth, I. (eds), Handbuch der Pflanzenanatomie. Spezieller Teil, Vol. 13, part 3. Borntraeger, Berlin.
Gaff, D. F. & Churchill, D. M. 1976. Borya nitida Labill. -an Australian species in the Liliaceae with desiccation-tolerant leaves. Aust. J. Bot. 24: 209–224.
Gaff, D. F. 1977. Desiccation tolerant vascular plants of Southern Africa. Oecologia 31: 95–109.
Gaff, D. F. 1981. The biology of resurrection plants. Pp. 114–146. In: Pate, J. S. & McComb, A. J. (eds), The biology of Australian plants. University of Western Australia Press, Perth.
Gaff, D. F. & Bole, P. V. 1986. Resurrection grasses in India. Oecologia 71: 159–160.
Gaff, D. F. 1987. Desiccation tolerant plants in South America. Oecologia 74: 133–136.
Gaff, D. F. 1989. Responses of desiccation tolerant 'resurrection' plants to water stress. Pp. 264–311. In: Kreeb, K. H., Richter, H. & Hinckley, T. M. (eds), Structural and functional responses to environmental stresses: water shortages. SPB Academic Publishing, The Hague.
Hambler, D. J. 1961. A poikilohydrous, poikilochlorophyllous angiosperm from Africa. Nature 191: 1415–1416.
Hartung, W., Schiller, P. & Dietz, K.-J. 1998. Physiology of Poikilohydric Plants. Pp. 299–327. In: Behnke, H.-D., Esser, K., Kadereit, J. W. & Lüttge, U. (eds), Progress in Botany, Vol. 59.
Heil, H. 1924. Chamaegigas intrepidus Dtr., eine neue Auferstehungspflanze. Beih. Bot. Zentralbl. 41: 41–50.
Hetherington, S. E., Hallam, N. D. & Smillie, R. M. 1982. Ultra-structural and compositional changes in chloroplast thylakoids of leaves of Borya nitida during humidity-sensitive degreening. Austr. J. Plant Phys. 9: 601–609.
Ingram, J. & Bartels, D. 1996. The molecular basis of dehydration tolerance in plants. Annu. Rev. Plant Physiol. Plant Mol. Biol. 47: 377–403.
Kluge, M. & Brulfert, J. In press. Ecophysiology of vascular plants on inselbergs. In: Porembski, S. & Barthlott, W. (eds), Inselbergs: biotic diversity of isolated rock outcrops in tropical and temperate regions. Springer-Verlag, Berlin.
Kubitzki, K. 1998. Velloziaceae. Pp. 459–467. In: Kubitzki, K. (ed.), The families and genera of vascular plants. Vol. 3, Springer-Verlag, Berlin.
Meirelles, S. T., Mattos, E. A. & da Silva, A. C. 1997. Potential desiccation tolerant vascular plants from southeastern Brazil. Polish J. Environ. Studies 6: 17–21.
Menezes, N. L. de 1971. Traqueides de transfusã o no gê nero Vellozia Vand. Ciê nc. Cult. 23: 389–409.
Mora-Osejo, L. E. 1989. La bioforma de Bulbostylis leucostachya Kunth (Cyperaceae) y de otras monocotiledoneas arboriformes tropicales. Rev. Acad. Colomb. Cien. 17: 215–230.
Porembski, S. 1996. Notes on the vegetation of inselbergs in Malawi. Flora 191: 1–8.
Porembski, S. & Barthlott, W. 1995. On the occurrence of a velamen radicum in tree-like Cyperaceae and Velloziaceae. Nord. J. Bot. 15: 625–629.
Porembski, S. & Barthlott, W. 1988. Velamen radicum micromorphology and classification of Orchidaceae. Nord. J. Bot. 8: 117–137.
Porembski, S., Brown, G. & Barthlott, W. 1996. A species-poor tropical sedge community: Afrotrilepis pilosa mats on inselbergs in West Africa. Nord. J. Bot. 16: 239–245.
Porembski, S., Martinelli, G., Ohlemüller, R. & Barthlott, W. 1998. Diversity and ecology of saxicolous vegetation mats on inselbergs in the Brazilian Atlantic rainforest. Diversity Distributions 4: 107–119.
Rudall, P. 1995. New records of secondary thickening in monocotyledons. IAWA J. 261–268.
Schiller, P., Hartung, W. & Ratcliffe, R. G. 1998. Intracellular pH stability in the aquatic resurrection plant Chamaegigas intrepidus in the extreme environmental conditions that characterize its natural habitat. New Phytol. 140: 1–7.
Schiller, P., Wolf, R. & Hartung, W. 1999. A scanning electron microscopical study of hydrated and desiccated submerged leaves of the aquatic resurrection plant Chamaegigas intrepidus. Flora 194: 97–102.
Sherwin, H. W. & Farrant, J. M. 1996. Differences in rehydration of three desiccation-tolerant angiosperm species. Ann. Bot. 78: 703–710.
Sherwin, H. W., Pammenter, N. W., February, E., van der Willigen, C. & Farrant, J. M. 1998. Xylem hydraulic characteristics, water relations and wood anatomy of the resurrection plant Myrothamnus flabellifolius Welw. Ann. Bot. 81: 567–575.
Tuba, Z., Lichtenthaler, H. K., Csintalan, Z. & Pó cs, T. 1993a. Regreening of desiccated leaves of the poikilochlorophyllous plant Xerophyta scabrida upon rehydration. J. Plant Physiol. 142: 103–108.
Tuba, Z., Lichtenthaler, H. K., Maroti, I. & Csintalan, Z. 1993b. Resynthesis of thylakoids and functional chloroplasts in the desiccated leaves of the poikilochlorophyllous plant Xerophyta scabrida upon rehydration. J. Plant Physiol. 142: 742–748.
Tuba, Z., Proctor, M. C. F. & Csintalan, Z. 1998. Ecophysiological responses of homoiochlorophyllous desiccation tolerant plants: a comparison and an ecological perspective. Plant Growth Regulation 24: 211–217.
Walter, H. 1931. Die Hydratur der Pflanze und ihre physiologischökologische Bedeutung. Gustav Fischer, Jena.
Weber, H. 1963. Ñber die Wuchsform von Bulbostylis paradoxa (Spreng.) Lindm. (Cyperaceae). Abh. Math.-Nat. Kl. Akad. Wiss. Lit. Mainz 5: 267–284.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Porembski, S., Barthlott, W. Granitic and gneissic outcrops (inselbergs) as centers of diversity for desiccation-tolerant vascular plants. Plant Ecology 151, 19–28 (2000). https://doi.org/10.1023/A:1026565817218
Issue Date:
DOI: https://doi.org/10.1023/A:1026565817218