Photosynthesis, Chlorophyll Fluorescence and Within-Canopy Distribution of Epiphytic Ferns in a Mexican Cloud Forest

P. Hietz; O. Briones

doi:10.1055/s-2001-15198

Plant Biology, Inhaltsverzeichnis

Plant Biol (Stuttg) 2001; 3(3): 279-287
DOI: 10.1055/s-2001-15198

Original Paper

Georg Thieme Verlag Stuttgart ·New York

Photosynthesis, Chlorophyll Fluorescence and Within-Canopy Distribution of Epiphytic Ferns in a Mexican Cloud Forest

P. Hietz ¹ , O. Briones ²

¹ Institut für Botanik, Universität für Bodenkultur, Wien, Austria
² Instituto de Ecología, Apartado Postal 63, 91000 Xalapa, Ver., México

Abstract

Parameters associated with the photosynthetic performance of eight common epiphytic ferns in a Mexican cloud forest were investigated in relation to the distribution of these species within the canopy. If the substantial microclimatic gradients within tropical forest canopies provide microhabitats exploited by different epiphytic species, we would expect to find correlations between distribution and physiological traits. Maximum rates of CO₂ uptake (A_max) and photon flux densities at light compensation points (LCP) were in the range of shade plants (A_max = 0.6 - 5.2 μmol m^-2 s^-1; LCP = 4 - 6.5 μmol m^-2 s^-1), but saturation light intensities were more typical for sun plants (270 - 550 μmol m^-2 s^-1). A_max and nitrogen content per unit dry weight were correlated with the distribution of the species within the canopy, but LCP, apparent quantum yield and dark respiration were not. When leaves were left to desiccate, the fluorescence yield of dark-adapted leaves (Y₀) remained high until the relative water content (RWC) had dropped below 30 to 20 %. Fluorescence after short illumination with 200 μmol m^-2 s^-1 declined when RWC dropped below 70 to 40 %. After exposure to full sunlight for 1 h, Y₀ of species growing in the outer canopy (Pleopeltis mexicana and Polypodium plebeium) and a plant characteristic of the mid-canopy (Elaphoglossum petiolatum) recovered better than in species from shadier locations (Trichomanes bucinatum, Asplenium cuspidatum, Phlebodium areolatum). With the exception of Ph. areolatum and a species growing at both exposed and shaded sites (Polypodium puberulum), Y₀ recovered at least partially after a loss of 80 - 96 % of saturation water, with the humidity-loving filmy fern (T. bucinatum) showing no signs of permanent damage at all. The results suggest that tolerance or avoidance of desiccation and high light may be at least as important in controlling the distribution of the species studied as photosynthetic performance without stress.

Key words

Chlorophyll fluorescence - epiphyte - ferns - photosynthesis - water content

Volltext

Referenzen

References

01 Andrade, J. L., and Nobel, P. S.. (1997); Microhabitats and water relations of epiphytic cacti and ferns in a lowland neotropical forest. Biotropica. 29 261-270
02 Barker, M. G.,, Press, M. C.,, and Brown, N. D.. (1997); Photosynthetic characteristics of dipterocarp seedlings in three tropical rain forest light environments: a basis for niche partitioning?. Oecologia. 112 453-463
03 Bewley, J. D., and Krochko, J. E.. (1982) Desiccation-tolerance. In Physiological plant ecology II. Encyclopedia in plant physiology, NS, Vol. 12 B. Lange, O. L., Nobel, P. S., Osmond, C. B., and Ziegler, H., eds. Berlin; Springer pp. 325-378
04 Boardman, N. K.. (1977); Comparative photosynthesis of sun and shade plants. Annual Review of Plant Physiology. 28 355-377
05 Bro, E.,, Meyer, S.,, and Genty, B.. (1996); Heterogeneity of leaf CO₂ assimilation during photosynthetic induction. Plant, Cell and Environment. 19 1349-1358
06 Chazdon, R. L.,, Pearcy, R. W.,, Lee, D. W.,, and Fetcher, N.. (1996) Photosynthetic responese of tropical forest plants to contrasting light environments. Tropical forest plant ecophysiology. Mulkey, S. S., ed. New York; Chapman & Hall pp. 5-55
07 Coutinho, L. M.. (1962) Contribuição ao conhecimento da ecologia da mata pluvial tropical. Universidade de São Paulo; Boletim 257: Faculdade de Filosofia
08 de Mattos, E. A.,, Grams, T. E. E.,, Ball, E.,, Franco, A. C.,, Haagkerwer, A.,, Herzog, B.,, Scarano, F. R.,, and Lüttge, U.. (1997); Diurnal patterns of chlorophyll alpha fluorescence and stomatal conductance in species of two types of coastal tree vegetation in southeastern Brazil. Trees: Structure and Function. 11 363-369
09 Deltoro, V. I.,, Calatayud, A.,, Gimeno, C.,, Abadia, A.,, and Barreno, E.. (1998); Changes in chlorophyll a fluorescence, photosynthetic CO₂ assimilation and xanthophyll cycle interconversions during dehydration in desiccation-tolerant and intolerant liverworts. Planta. 207 224-228
10 Demmig-Adams, B., and Adams, W. W.. (1992); Photoprotection and other responses of plants to high light stress. Annual Review of Plant Physiology. 43 599-626
11 Demmig, B., and Björkman, O.. (1987); Comparison of the effect of excessive light on chlorophyll fluorescence (77 K) and photon yield of O₂ evolution in leaves of higher plants. Planta. 171 171-184
12 Freiberg, M.. (1996); Spatial distribution of vascular epiphytes on three emergent canopy trees in French Guiana. Biotropica. 28 345-355
13 Griffiths, H., and Smith, J. A. C.. (1983); Photosynthetic pathways in the Bromeliaceae of Trinidad: relations between life-forms, habitat preference and the occurrence of CAM. Oecologia. 60 176-184
14 Hietz, P., and Briones, O.. (1998); Correlation between water relations and within-canopy distribution of epiphytic ferns in a Mexican cloud forest. Oecologia. 114 305-316
15 Hietz, P., and Hietz-Seifert, U.. (1995); Structure and ecology of epiphyte communities of a cloud forest in central Veracruz, Mexico. Journal of Vegetation Science. 6 719-728
16 Huber, O.. (1978); Light compensation point of vascular plants of a tropical cloud forest and an ecological interpretation. Photosynthetica. 12 382-390
17 Kelly, D. L.. (1985); Epiphytes and climbers of a Jamaican rain forest: vertical distribution, life forms and life history. Journal of Biogeography. 12 223-241
18 Krall, J. P., and Edwards, G. E.. (1992); Relationship between photosystem II activity and CO₂ fixation in leaves. Physiologia Plantarum. 86 180-187
19 Krause, G. H., and Winter, K.. (1996); Photoinhibition of photosynthesis in plants growing in natural tropical forest gaps. A chlorophyll fluorescence study. Botanica Acta. 109 456-462
20 Kursar, T. A., and Coley, P. D.. (1999); Contrasting modes of light acclimation in two species of the rainforest understory. Oecologia. 121 489-498
21 Larcher, W.. (1984) Ökologie der Pflanzen. Stuttgart; Ulmer
22 Lawlor, D. W.. (1987) Photosynthesis: metabolism, control, and physiology. London; Longman
23 Long, S. P.,, Humphries, S.,, and Falkowski, P. G.. (1994); Photoinhibition and photosynthesis in nature. Annual Review of Plant Physiology. 45 662-663
24 Lüttge, U.,, Ball, E.,, Kluge, M.,, and Ong, B. L.. (1986); Photosynthetic light requirements of various tropical vascular epiphytes. Physiologie Végetal. 24 315-331
25 Maxwell, C.,, Griffiths, H.,, Borland, A. M.,, Broadmeadow, M. S. J.,, and McDavid, C. R.. (1992); Photoinhibitory responses of the epiphytic bromeliad Guzmania monostachia during the dry season in Trinidad maintain photochemical integrity under adverse conditions. Plant, Cell and Environment. 15 37-47
26 Maxwell, C.,, Griffiths, H.,, Borland, A. M.,, Young, A. J.,, Broadmeadow, M. S. J.,, and Fordham, M. C.. (1995); Short-term photosynthetic responses of the C3-CAM epiphyte Guzmania monostachia var. monostachia to tropical seasonal transitions under field conditions. Australian Journal of Plant Physiology. 22 771-781
27 Mooney, H. A.,, Field, C.,, and Vázquez-Yanes, C.. (1984) Photosynthetic characteristics of wet tropical forest plants. Physiological ecology of plants in the wet tropics. Medina, E., Mooney, H. A., and Vázquez-Yanes, C., eds. The Hague; W. Junk pp. 113-128
28 Muslin, E. H., and Homann, P. H.. (1992); Light as a hazard for the desiccation-resistant ”resurrection” fern Polypodium polypodioides L. Plant, Cell and Environment. 15 81-89
29 Parker, G. G.. (1995) Structure and microclimate of forest canopies. Forest Canopies. Lowman, M., Nadkarni, N. M., eds. San Diego; Academic Press pp. 73-106
30 Pittendrigh, C. S.. (1948); The bromeliad-Anopheles-malaria complex in Trinidad. I - The bromeliad flora. Evolution. 2 58-89
31 Powles, S. B.. (1984); Photoinhibition of photosynthesis induced by visible light. Annual Review of Plant Physiology. 35 15-44
32 Raveh, E.,, Gersani, M.,, and Nobel, P. S.. (1995); CO₂ uptake and fluorescence responses for a shade-tolerant cactus Hylocereus undatus under current and doubled CO₂ concentrations. Physiologia Plantarum. 93 505-511
33 Scholes, J. D.,, Press, M. C.,, and Zipperlen, S. W.. (1997); Differences in light energy utilisation and dissipation between dipterocarp rain forest tree seedlings. Oecologia. 109 41-48
34 Smith, J. A. C.,, Griffiths, H.,, and Lüttge, U.. (1986); Comparative ecophysiology of CAM and C3 bromeliads. I. The ecology of the Bromeliaceae in Trinidad. Plant, Cell and Environment. 9 359-376
35 Stuart, T. S.. (1968); Revival of respiration and photosynthesis in dried leaves of Polypodium polypodioides. Planta (Berl.). 83 185-206
36 Stuntz, S., and Zotz, G.. (2001) Photosynthesis in vascular epiphytes. Flora in print
37 ter Steege, H., and Cornelissen, J. H. C.. (1989); Distribution and ecology of vascular epiphytes in lowland rain forest of Guayana. Biotropica. 21 331-339
38 Veenendaal, E. M.,, Swaine, M. D.,, Agyeman, V. K.,, Blay, D.,, Abebrese, I. K.,, and Mullins, C. E.. (1995); Differences in plant and soil water relations in and around a forest gap in West Africa during the dry season may influence seedling establishment and survival. Journal of Ecology. 83 83-90
39 Walter, H., and Breckle, S.-W.. (1984) Ökologie der Erde. Band 2. Spezielle Ökologie der Tropischen und Subtropischen Zonen. Stuttgart; Gustav Fischer
40 Zipperlen, S. W., and Press, M. C.. (1996); Photosynthesis in relation to growth and seedling ecology of two dipterocarp rain forest species. Journal of Ecology. 84 863-876
41 Zotz, G., and Andrade, J. L.. (1998); Water relations of two co-occurring epiphytic bromeliads. Journal of Plant Physiology. 152 545-554
42 Zotz, G., and Tyree, M. T.. (1996); Water stress in the epiphytic orchid, Dimerandra emarginata (G. Meyer) Hoehne. Oecologia. 107 151-159
43 Zotz, G., and Ziegler, H.. (1997); The occurrence of crassulacean acid metabolism among vascular epiphytes from central Panama. New Phytologist. 137 223-229

P. Hietz

Institut für Botanik
Universität für Bodenkultur

Gregor Mendel Str. 33
1180 Wien
Austria

eMail: hietz@edv1.boku.ac.at

Section Editor: U. Lüttge