Abstract
Beech forests naturally regenerating from clear-cutting can exhibit different microclimates depending on size of saplings and stem density. When beech trees are young and stem density is low, the level of radiation inside the ecosystem reaching the soil surface is high; consequently, air and soil temperatures rise and the soil water content may decrease. These microclimatic parameters presumably will affect the anatomy, photosynthesis, and carbon metabolism of beech leaves. We studied the morphology and physiology of sun and shade leaves of beech trees differing in age and growing within clear-cut areas with distinct microclimate. Results were compared with those of adult trees in an unmanaged forest. We selected a stand clear-cut in 2001 (14,000 trees ha−1), another clear-cut in 1996 (44,000 trees ha−1) and an unmanaged forest (1,000 trees ha−1). Photosynthetic photon flux density (PPFD) incident on sun leaves, air temperature, soil moisture, and soil temperature within the forests affected water status and carbohydrate storage in all trees. As trees became older, PPFD also influenced pigment composition and Rubisco activity in sun leaves. On the other hand, shade leaves from the oldest trees were the most sensitive to PPFD, air temperature, and soil moisture and temperature inside the forest. Contrariwise, microclimatic parameters slightly affected the physiology of shade leaves of the beech in the stand with the highest light attenuation. Air and soil temperatures were the parameters that most affected the photosynthetic pigments and carbohydrate storage in shade leaves of the youngest trees.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Amores G, Bermejo R, Elustondo D, Lasheras E, Santamaría JM (2006) Nutritional status of northern Spain beech forests. Water Air Soil Pollut 177:227–238
Barthod S, Epron D (2005) Variations of construction cost associated to leaf area renewal in saplings of two co-occurring temperate tree species Acer platanoides L. and Fraxinus excelsior L. along a light gradient. Ann Sci 62:545–551
Bethlenfalvay GJ, Brown MS, Franson RL (1990) The Glycine-Glomus-Bradyrhizobium symbiosis. X. Relationships between leaf gas exchange and plant and soil water status in nodulated, mycorrhizal soybean under drought stress. Plant Physiol 94:723–728
Bradford MM (1976) A rapid and sensitive method for the quantification of microgram quantities of protein utilizing the principle of protein–dye binding. Anal Biochem 72:248–254
Čaňová I, Ďurkovič J, Hladká D (2008) Stomatal and chlorophyll fluorescence characteristics in European beech cultivars during leaf development. Biol Plantarum 52:577–581
Closa I, Goicoechea N (2010) Seasonal dynamics of the physicochemical and biological properties of soils in naturally regenerating, unmanaged and clear-cut beech stands in northern Spain. Eur J Soil Biol 46:190–199
Comstock JP, Ehleringer JR (1988) Contrasting photosynthetic behaviour in leaves and twigs of Hymenoclea salsola, a green-twigged warm desert shrub. Am J Bot 75:1360–1370
Cutter EG (1969) Plant anatomy: experiment and interpretation. Part I. Cells and tissues. Addison, Wesley, London
Dale JE (1988) The control of leaf expansion. Annu Rev Plant Phys 39:267–295
Darwish DS, Fahmy GM (1997) Transpiration decline curves and stomatal characteristics of faba bean genotypes. Biol Plantarum 39:243–249
Ellenberg H (1988) Vegetation ecology of central Europe. Cambridge University Press, Cambridge
Evans J (1988) Natural regeneration of broadleaves. Forestry Commission Bulletin No 78. HMSO, London
García-Plazaola JI, Becerril JM (2000) Photoprotection mechanisms in European beech (Fagus sylvatica L.) seedlings from diverse climatic origins. Trees 14:339–343
García-Plazaola JI, Becerril JM (2001) Seasonal changes in photosynthetic pigments and antioxidants in beech (Fagus sylvatica) in a Mediterranean climate: implications for tree decline diagnosis. Aust J Plant Physiol 28:225–232
Geisler M, Nadeau J, Sack FD (2000) Oriented asymmetric divisions that generate the stomatal spacing pattern in Arabidopsis are disrupted by the too many mouths mutation. Plant Cell 12:2075–2086
Goicoechea N, Closa I, de Miguel A (2009) Ectomycorrhizal communities within beech (Fagus sylvatica L.) forests that naturally regenerate from clear-cutting in northern Spain. New Forests 38:157–175
Halldin S, Saugier B, Pontailler JY (1984) Evapotranspiration of a deciduous forest: simulation using routine meteorological data. J Hydrol 75:323–341
Hansen U, Fiedler B, Rank B (2002) Variation of pigment composition and antioxidative systems along the canopy light gradient in a mixed beech/oak forest: a comparative study on deciduous tree species differing in shade tolerance. Trees 16:354–364
Harmer R, Gill R (2000) Natural Regeneration in broadleaved woodlands: deer browsing and the establishment of advance regeneration. Information Note. Forestry Commission, 6 pp. Accessed online September, 2006: http://www.forestry.gov.uk
Harmer R, Morgan G (2007) Development of Quercus robur advance regeneration following canopy reduction in an oak woodland. Forestry 80:137–149
Harmer R, Kerr G, Boswell R (1997) Characteristics of lowland broadleaved woodland being restocked by natural regeneration. Forestry 70:199–209
Harmer R, Boswell R, Robertson M (2005) Survival and growth of tree seedlings in relation to changes in the ground flora during natural regeneration of an oak shelterwood. Forestry 78:21–32
Herbinger K, Ch Then, Löw M, Haberer K, Alexous M, Koch N, Remele K, Heerdt C, Grill D, Rennenberg H, Häberle K-H, Matyssek R, Tausz M, Wieser G (2005) Tree age dependence and within-canopy variation of leaf gas exchange and antioxidative defence in Fagus sylvatica under experimental free-air ozone exposure. Environ Pollut 137:476–482
Hovenden MJ, Vander Schoor JK (2003) Nature vs nurture in the leaf morphology of Southern beech, Nothofagus cunninghamii (Nothofagaceae). New Phytol 161:585–594
Jarvis CE, Walker JRL (1993) Simultaneous, rapid, spectrophotometric determination of total starch, amylose and amylopectin. J Sci Food Agric 63:53–57
Kerr G (2000) Natural regeneration of Corsican pine (Pinus nigra subsp. laricio) in Great Britain. Forestry 73:479–488
King DA (2003) Allocation of above-ground growth is related to light in temperate deciduous saplings. Funct Ecol 17:482–488
Kutsch WL, Herbst M, Vanselow R, Hummelshoj P, Jensen NO, Kappen L (2001) Stomatal acclimation influences water and carbon fluxes of a beech canopy in northern Germany. Basic Appl Ecol 2:265–281
Last FT, Pelham J, Mason PA, Ingleby K (1979) Influence of leaves on sporophore production by fungi forming sheathing mycorrhizas with Betula spp. Nature 280:168–169
Le Dantec V, Dufrene E, Saugier B (2000) Interannual and spatial variation in maximum leaf area index of temperate deciduous stands. Forest Ecol Manage 134:71–81
Leuchner C, Voβ S, Foetzki A, Clases Y (2006) Variation in leaf area index and stand mass of European beech across gradients of soil acidity and precipitation. Plant Ecol 182:247–258
Lichtenthaler HK (1981) Adaptation of leaves and chloroplasts to high quanta fluence rates. In: Akoyunoglou G (ed) Photosynthesis VI. Balaban International Science Service, Philadelphia, pp 273–285
Lichtenthaler HK (1987) Chlorophylls and carotenoids: pigments of photosynthetic biomembranes. In: Colowick SP, Kaplan NO (eds) Methods in enzymology, vol 148. Academic Press, San Diego, pp 350–382
Lichtenthaler HK, Babani F (2004) Light adaptation and senescence of the photosynthetic apparatus. Changes in pigment composition, chlorophyll fluorescence parameters and photosynthetic activity. In: Papageorgiou GC, Govindjee (eds) Chlorophyll fluorescence: a signature of photosynthesis. Springer, Dordrecht, pp 713–736
Lichtenthaler HK, Buschmann C, Döll M, Fietz HJ, Bach T, Kozel U, Meier D, Rahmsdorf U (1981) Photosynthetic activity, chloroplast ultrastructure, and leaf characteristics of high-light and low-light plants and of sun and shade leaves. Photosynth Res 2:115–141
Lichtenthaler HK, Ac A, Marek MV, Kalina J, Urban O (2007) Differences in pigment composition, photosynthetic rates and chlorophyll fluorescence images of sun and shade leaves of four tree species. Plant Physiol Biochem 45:577–588
Loidi J, Báscones JC (2006) Memoria del Mapa de Series de Vegetación de Navarra. E 1:200, 000. Departamento de Medio Ambiente. Ordenación del Territorio y Vivienda, Gobierno de Navarra, Spain
Matschonat G, Falkengren-Grerup U (2000) Recovery of soil Ph. cation-exchange capacity and the saturation sites from stemflow-induced soil acidification in three Swedish beech (Fagus sylvatica L.) forests. Scand J For Res 15:39–48
Petritan AM, von Lüpke B, Petritan IC (2009) Influence of light availability on growth. Leaf morphology and plant architecture of beech (Fagus sylvatica L.), maple (Acer pseudoplatanus L.) and ash (Fraxinus excelsior L.) saplings. Eur J For Res 128:61–74
Piper FI, Reyes-Díaz M, Corcuera LJ, Lusk CH (2009) Carbohydrate storage, survival, and growth of two evergreen Nothofagus species in two contrasting light environments. Ecol Res 24:1233–1241
Quisenberry JE, Roark B, McMichael BL (1982) Use of transpiration decline curves to identify drought-tolerant cotton germplasm. Crop Sci 22:918–922
Sarijeva G, Knapp M, Lichtenthaler HK (2007) Differences in photosynthetic activity, chlorophyll and carotenoid levels, and in chlorophyll fluorescence parameters in green sun and shade leaves of Ginkgo and Fagus. J Plant Physiol 164:950–955
Séstak Z, Càtsky J, Jarvis P (1971) Plant photosynthetic production. Manual of Methods. Dr Junk Publishers, The Hague, The Netherlands
Sharkey TD, Savitch LV, Butz ND (1991) Photometric method for routine determination of Kcat and carbamylation of rubisco. Photosynth Res 28:41–48
Smith SE, Gianinazzi-Pearson V (1988) Physiological interactions between symbionts in vesicular-arbuscular mycorrhizal plants. Annu Rev Plant Physiol 39:221–244
USDA (1999) Soil Taxonomy, 2nd edn. Agriculture Handbook number 436, United States Department of Agriculture, Washington
Van der Hout P (2000) Testing the applicability of reduced impact logging in greenheart forest in Guyana. Int For Rev 2:24–32
Von Stamm S (1994) Linked stomata and photosynthesis model for Corylus avellana (hazel). Ecol Model 75(76):345–357
Weatherley PE (1950) Studies in the water relations of the cotton plant. I. The field measurements of water deficits in leaves. New Phytol 49:81–87
Wittmann C, Aschan G, Pfanz H (2001) Leaf and twig photosynthesis of young beech (Fagus sylvatica) and aspen (Populus tremula) trees grown under different light regime. Basic Appl Ecol 2:145–154
Wu L, Shinzato T, Kudo T, Ishigaki C, Aramoto M (2008) Characteristics of a 20-year-old evergreen broad-leaved forest restocked by natural regeneration after clearcut-burning. Ann For Sci 65:505
Yemm EW, Willis AJ (1954) The estimation of carbohydrates in plant extracts by anthrone. Biochem J 57:508–514
Acknowledgments
Our research was supported by Fundación Universitaria de Navarra (FUNA, PIUNA) and Caja Navarra. Iván Closa was a recipient of a grant from Asociación de Amigos de la Universidad de Navarra (ADA). The authors are grateful to Lorenzo Etxarri for assistance with logistics, site locations and history information on forest management as well as Amadeo Urdiain for technical assistance.
Author information
Authors and Affiliations
Corresponding author
Additional information
Communicated by M. Buckeridge.
Rights and permissions
About this article
Cite this article
Closa, I., Irigoyen, J.J. & Goicoechea, N. Microclimatic conditions determined by stem density influence leaf anatomy and leaf physiology of beech (Fagus sylvatica L.) growing within stands that naturally regenerate from clear-cutting. Trees 24, 1029–1043 (2010). https://doi.org/10.1007/s00468-010-0472-3
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00468-010-0472-3