Abstract
Red spruce (Picea rubens Sarg.) and balsam fir (Abies balsamea[L.] Mill) are the dominant conifer species at treeline in the mountains of the northeastern United States. The objective of this study was to investigate changes in foliar chemistry of these species along both elevational (below, at, and above treeline) and canopy light (sun vs. shade leaves) gradients. Nutrient concentrations (mass basis) did not show any significant (all P>0.05) differences among elevations, although mean concentrations of all macronutrients (N, P, K, Ca, Mg) tended to be higher at low elevation sites compared to high elevation. This result contradicts the traditional view that plants in cold growth environments are adapted to maintain high foliar nutrient concentrations, but it also gives only weak support for the hypothesis that nutrient limitation plays a role in determining treeline location. Foliar concentrations (mass basis) of lignin (both sun and shade needles) and cellulose (sun needles only) decreased sharply and significantly with increasing elevation, but foliar concentrations of hemicellulose did not change with elevation. These results are consistent with the hypothesis that as a result of carbon limitation at high elevation, synthesis of the most expensive fiber constituent (i.e. lignin) is reduced more than that of the least expensive fiber constituent (i.e. hemicellulose). The reduced lignin concentration at high elevation may have implications for nutrient cycling in this ecosystem where cold temperatures limit decomposition rates.
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References
Aber J D and Melillo J M 1991 Terrestrial ecosystems. Saunders, Philadelphia. 429 pp.
Audley D E, Skelly J M, McCormick L H and Jackson W A 1998 Crown condition and nutrient status of red spruce (Picea rubens Sarg.) in West Virginia. Water Air Soil Poll. 102, 177–199.
Balaguer L, Martínez-Ferri E, Valladares F, Pérez-Corona M E, Baquedano F J, Castillo F J and Manrique E 2001 Population divergence in the plasticity of the response of Quercus coccifera to the light environment. Funct. Ecol. 15, 124–135.
Barrick K A and Schoettle A W 1996 A comparison of the foliar nutrient status of elf in wood and symmetrically formed tall trees, Colorado Front Range, U.S.A. Can. J. Bot. 74, 1461–1475.
Bryant K N, Fowlkes A J, Mustafa S F, O'Neil B J, Osterman A C, Smith T M, Shepard M R, Woosley R S and Butcher D J 1997 Determination of aluminum, calcium and magnesium in Fraser fir, balsam fir, and red spruce foliage and soil from the Southern and Middle Appalachians. Microchem. J. 56, 382–392.
Chabot B F and Hicks D J 1982 The ecology of leaf life spans. Annu. Rev. Ecol. Syst. 13, 229–259.
Cogbill C V and White P S 1991 The latitude-elevation relationship for spruce-fir forest and tree line along the Appalachian mountain chain. Vegetatio 94, 153–175.
Comerford N B 1981 Distributional gradients and variability of macroelement concentrations in the crowns of plantation grown Pinus resinosa (Ait.). Plant Soil 63, 345–353.
Field C 1983 Allocating leaf nitrogen for the maximization of carbon gain: Leaf age as a control on the allocation program. Oecologia 56, 341–347.
Friedland A J, Hawley G J and Gregory R A 1988 Red spruce (Picea rubens Sarg.) foliar chemistry in Northern Vermont and New York, USA. Plant Soil 105, 189–193.
Goering H K and Van Soest P J 1970 Forage fiber analyses (Agricultural Handbook No. 379). ARS–USDA, Washington, DC. 20 pp.
Hollinger D Y 1996 Optimality and nitrogen allocation in a tree canopy. Tree Physiol. 16, 627–634.
Huntington T G, Peart D R, Hornig J, Ryan D F and Russo-Savage S 1990 Relationships between soil chemistry, foliar chemistry, and condition of red spruce at Mount Moosilauke, New Hampshire. Can. J. For. Res. 20, 1219–1227.
Johnson A H, Schwartzman T N, Battles J J, Miller R, Miller E K, Friedland A J and Vann D R 1994 Acid rain and soils of the Adirondacks. II. Evaluation of calcium and aluminum as causes of red spruce decline at Whiteface Mountain, New York. Can. J. For. Res. 24, 654–662.
Johnson D W, Richter D D, Lovett G M and Lindberg S E 1985 The effects of atmospheric deposition on potassium, calcium, and magnesium cycling in two deciduous forests. Can. J. For. Res. 15, 773–782.
Joslin J D, Kelly J M and Van Miegroet H 1992 Soil chemistry and nutrition of North American spruce-fir stands: Evidence for recent change. J. Environ. Qual. 21, 12–30.
Körner C 1999 Alpine plant life. Springer-Verlag, Berlin. 338 p.
Kozlowski T T and Pallardy S G 1997 Physiology of woody plants, 2nd ed. Academic Press, New York. 411 pp.
Larsen J A 1927 Relation of leaf structure of conifers to light and moisture. Ecology 8, 371–377.
Lichtenthaler H K. 1985. Differences in morphology and chemical composition of leaves grown at different light intensities and qualities. In Control of leaf growth. Eds. N R Baker, W J Davies and C K Ong. pp. 201–221. Cambridge University Press, New York.
Likens G E and Bormann F H 1970 Chemical analyses of plant tissues from the Hubbard Brook ecosystem in New Hampshire. School of Forestry Bulletin No. 79, Yale University, New Haven. 25 p.
MacLean K S and Robertson R G 1981 Variation in the major element content of red spruce foliage with season, crown position, tree and tissue age. Commun. Soil Sci. Plant Anal. 12, 39–49.
Melillo J M, Aber J D and Muratore J F 1982 Nitrogen and lignin control of hardwood leaf litter decomposition dynamics. Ecology 63, 621–626.
Miller E K, Friedland A J, Aarons E A, Mohnen V A, Battles J J, Panek J A, Kadlecek J and Johnson A H 1993 Atmospheric deposition to forests along an elevational gradient at Whiteface Mountain, NY, U.S.A. Atmos. Environ. 27A, 2121–2136.
Myre R and Camiré C 1996 The effect of crown position and date of sampling on biomass, nutrient concentrations and contents of needles and shoots in European larch. Trees 10, 339–350.
Noble I R 1993 A model of the responses of ecotones to climate change. Ecol. Appl. 3, 396–403.
Oleksyn J, Reich P B, Zytkowiak R, Karolewski P and Tjoelker MG 2002 Needle nutrients in geographically diverse Pinus sylvestris L. populations. Ann. Sci. Forest. 59, 1–18.
Richardson A D 2003 Ecophysiological and morphological responses of balsam fir and red spruce to elevation and the canopy light gradient in the mountains of the northeastern United States. Ph.D. Dissertation, School of Forestry & Environmental Studies, Yale University, New Haven, CT. 224 pp. Available at: http://www.aber.sr.unh.edu/richardson/
Richardson A D and Berlyn G P 2002 Spectral reflectance and photosynthetic properties of Betula papyrifera (Betulaceae) leaves along an elevational gradient on Mt. Mansfield, Vermont, USA. Am. J. Bot. 89, 88–94.
Richardson A D, Berlyn G P, Ashton P M S, Thadani R and Cameron I R 2000 Foliar plasticity of hybrid spruce in relation to crown position and stand age. Can. J. Bot. 78, 305–317.
Richardson A D, Ashton P M S, Berlyn G P, McGroddy M E and Cameron I R 2001a Within-crown foliar plasticity of western hemlock, Tsuga heterophylla, in relation to stand age. Ann. Bot. 88, 1007–1015.
Richardson A D, Berlyn G P and Gregoire T G 2001b Spectral reflectance of Picea rubens (Pinaceae) and Abies balsamea (Pin-aceae) needles along an elevational gradient, Mt. Moosilauke, New Hampshire, USA. Am. J. Bot. 88, 667–676.
Rutigliano F A, de Santo A V, Berg B, Alfani A and Fioretto A 1996 Lignin decomposition in decaying leaves of Fagus sylvatica L. and needles of Abies alba Mill. Soil Biol. Biochem. 28, 101–106.
Salisbury F B and Ross C W 1992 Plant Physiology. Wadsworth, Belmont, CA. 682 pp.
Siccama T G 1974 Vegetation, soil, and climate on the Green Mountains of Vermont. Ecol. Monogr. 44, 325–349.
Stenberg P, Palmroth S, Bond B J, Sprugel D G and Smolander H 2001 Shoot structure and photosynthetic efficiency along the light gradient in a Scots pine canopy. Tree Physiol. 21, 805–814.
Stenberg P, Smolander H, Sprugel D and Smolander S 1998 Shoot structure, light interception, and distribution of nitrogen in an Abies amabilis canopy. Tree Physiol. 18, 759–767.
Swan H S D 1971 Relationships between nutrient supply, growth and nutrient concentrations in the foliage of white and red spruce. Woodlands Report WR/34, Pulp and Paper Research Institute of Canada, Pointe Claire, Quebec. 26 pp.
Taylor B R, Prescott C E, Parsons WJ F and Parkinson D 1991 Sub-strate control of litter decomposition in four Rocky-Mountain coniferous forests. Can. J. Bot. 69, 2242–2250.
Tranquillini W 1979 Physiological ecology of the alpine timberline. Springer-Verlag, New York. 136 pp.
Van den Driessche R 1974 Prediction of mineral nutrient status of trees by foliar analysis. Bot. Rev. 40, 347–394.
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Richardson, A.D. Foliar chemistry of balsam fir and red spruce in relation to elevation and the canopy light gradient in the mountains of the northeastern United States. Plant and Soil 260, 291–299 (2004). https://doi.org/10.1023/B:PLSO.0000030179.02819.85
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DOI: https://doi.org/10.1023/B:PLSO.0000030179.02819.85