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Czasopismo

2012 | 68 |

Tytuł artykułu

Differences in chemical composition of needle and leaf litter from exotic and native tree species stands

Treść / Zawartość

Warianty tytułu

Języki publikacji

EN

Abstrakty

EN
The potential differentiations in litter chemistry among native and non-native trees are poorly understood. We compared the chemical composition of leaf litterfall of 11 exotic tree species, e.g. coniferous: Abies cephalonica, A. grandis, A. procera, Chamaecyparis pisifera, Pinus peuce, Pseudotsuga menziesii, Thuja plicata, and deciduous: Acer rubrum, A. saccharum, Betula alleghaniensis and Quercus rubra, with that of a native European conifer, Pinus sylvestris (as reference to coniferous species) anda mixture of native European Quercus robur, Carpinus betulus, Tilia cordata, T. platyphyllos and Corylus avellana leaves (as a reference mixture of deciduous species). We found significant differences among the species studied in nitrogen and carbon content in needles/leaves, C/N ratio, as well as total soluble phenolic compounds (TPh) and total nonstructural carbohydrates (TNC) content, including soluble carbohydrates and starch. However, we found no clear differentiation of exotic from native tree species in the analyzed elements and metabolites. Among the exotic coniferous tree species, P. menziesii stood out among the species studied – fallen needles of this species were characterized by relatively high TPh and TNC content. The relationships between TPh and TNC content in leaf and needle litter among tree species were similar among two consecutive years. For deciduous tree species, the tendency of higher TPh content and C/N ratio in leaves falling earlier (September; leaves of sun-type) than later (November; leaves of shade-type) was more distinct than in coniferous tree species. Generally, we cannot see any special differences in the levels or mutual quantitative relationships of the chemical compounds studied in fallen needles/leaves of exotic tree species in comparison with native tree species.

Wydawca

-

Czasopismo

Rocznik

Tom

68

Opis fizyczny

p.101-112,fig.,ref.

Twórcy

autor
  • Department of Forest Protection, Poznan University of Life Sciences, Wojska Polskiego 71c, 60-625 Poznan, Poland
autor

Bibliografia

  • Aerts R. 1997. Climate, leaf litter chemistry andleaf litter decomposition in terrestrial ecosystems: a triangular relationship. Oikos 79: 439–449.
  • Binkley D., Giardina C. 1998. Why do tree species affect soils? The Warp of Woof of tree-soil interaction. Biogeochemistry 42: 89–106.
  • Bogatyrev L., Berg B., Staaf H. 1983. Leaching of plant nutrients andtotal phenolic substances from some foliage litters – a laboratory study. Swedish Coniferous Forest Project Barrskogslandskapets Ekologi. Technical Report 33. Department of Ecology andEnvironmental Research, Swedish University of Agricultural Sciences, Upsala, pp. 1–57.
  • Bonanomi G., Incerti G., Antignani V., Capodilupo M., Mazzoleni S. 2010. Decomposition andnutrient dynamics in mixed litter of Mediterranean species. Plant and Soil 331: 481–496.
  • Camm E.L., Towers G.H.N. 1973. Phenylalanine ammonialyase. Phytochemistry 12: 961–973.
  • CouplandG.T., Paling E.I., McGuinness K.A. 2005. Vegetative andreprod uctive phenologies of four mangrove species from northern Australia. Australian Journal of Botany 53: 109–117.
  • Covelo F., Gallardo A. 2004. Green and senescent leaf phenolics showedspatial autocorrelation in a Quercus robur population in northwestern Spain. Plant and Soil 259: 267–276.
  • Coviella C.E., Stipanovic R.D., Trumble J.T. 2002. Plant allocation to defensive compounds: interactions between elevatedCO 2 andnitrogen in transgenic cotton plants. Journal of Experimental Botany 53: 323–331.
  • Dauer J.M., Chorover J., Chadwick O.A., Oleksyn J., Tjoelker M.G., Hobbie S.E., Reich P.B., Eissenstat D.E. 2007. Controls over leaf andlitter calcium concentrations among temperate trees. Biogeochemistry 86: 175–187.
  • Dickie I.A., Oleksyn J., Reich P.B., Karolewski P., Zytkowiak R., Jagodzinski A.M., Turzanska E. 2006. Soil modification by different tree species influences the extent of seedling ectomycorrhizal infection. Mycorrhiza 16: 73–79.
  • Forge T.A., SimardS.W. 2001. Structure of nematode communities in forest soils of southern British Columbia: relationships to nitrogen mineralization andeffects of clearcut harvesting andfertilization. Biology andFertility of Soils 34: 170–178.
  • Haissig B.E., Dickson R.E. 1979. Starch measurement in plant tissue using enzymatic hydrolysis. Physiologia Plantarum 47: 151–157.
  • Hansen J., Møller I. 1975. Percolation of starch and soluble carbohydrates from plant tissue for quantitative determination with anthrone. Analytical Biochemistry 68: 87–94.
  • Henriksson J., Haukioja E., Ossipov V., Osipova S., Sillsnpää S., Kaspari L., Pihlaja K. 2003. Effects of host shading on consumption and growth of the geometrid Epirrita autumnata: interactive roles of water, primary and secondary compounds. Oikos 103: 3–16.
  • Hobbie S.E., Ogdahl M., Chorover J., Chadwick O.A., Oleksyn J., Zytkowiak R., Reich P.B. 2007. Tree species effects on soil organic matter dynamics: the role of soil cation composition. Ecosystems 10: 999–1018.
  • Hobbie S.E., Oleksyn J., Eissenstat D.E., Reich P.B. 2010. Fine root decomposition rates do not mirror those of leaf litter among temperate tree species. Oecologia 162: 505–513.
  • Hobbie S.E., Reich P.B., Oleksyn J., Ogdahl M., Zytkowiak R., Hale C., Karolewski P. 2006. Litter decomposition in a common garden experiment with fourteen tree species. Ecology 87: 2288–2297.
  • Jagodziński A.M., Banaszczak P. 2010. Stem volume and above ground wood y biomass in Noble fir (Abies procera Rehder) stands in Rogów Arboretum (Poland). Acta Scientiarum Polonorum, Silvarum Colendarum Ratio et Industria Lignaria 9: 9–24.
  • Jagodziński A.M., Skorupski M., Kasprowicz M., Wojterska M., Dobies T., Kałucka I., Sławska M., Wierzbicka A., Łabędzki A., Oleszyńska-Niżniowska J., Nowiński M., Małek S., Karolewski P., Oleksyn J., Banaszczak P. 2011. Biodiversity of Greek fir (Abies cephalonica Loudon) experimental stands in Rogów Arboretum (Poland). Acta Scientiarum Polonorum, Silvarum Colendarum Ratio et Industria Lignaria 10: 5–15.
  • Johnson G., Schaal L.A. 1957. Accumulation of phenolic substances andascorbic acids in potato tuber tissue upon injury andtheir possible role in disease and resistance. American Potato Journal 34: 200–202.
  • Kaplan I., Halitschke R., Kessler A., Sardanelli S., Denno R.F. 2008. Constitutive and induced defenses to herbivory in above- andbelowground plant tissues. Ecology 89: 392–406.
  • Karolewski P., Jagodziński A.M., Grzebyta J. 2011. Wpływ wieku drzew oraz wieku i lokalizacji igieł w koronie na zawartość związków fenolowych w igłach młodych sosen [Influence of tree age, needle age and location in the crown on the phenolic compounds content in needles of young Scots pines]. Sylwan 155: 797–807.
  • Kasprowicz M., Jagodziński A.M., Skorupski M., Wojterska M., Dobies T., Kałucka I., Sławska M., Wierzbicka A., Łabędzki A., Nowiński M., Karolewski P., Oleksyn J., Banaszczak P., Małek S. 2011. The list of plants, fungi andinvertebrates of noble fir (Abies procera Rehder) experimental stands in Rogów Arboretum (Poland). Acta Scientiarum Polonorum, Silvarum Colendarum Ratio et Industria Lignaria 10: 17–27.
  • Knight K.S., Oleksyn J., Jagodzinski A.M., Reich P.B., Kasprowicz M. 2008. Overstory tree species regulate colonization by native andexotic plants: a source of positive relationships between understorey diversity and invasibility. Diversity and Distributions 14: 666–675.
  • Lavelle P., Spain A. 2001. Soil Ecology. Kluwer Academic Publishers Dordrecht, Boston, London, pp. 201-356.
  • Marshall V.G., Lousier J.D. 2000. Impacts of forest harvesting on biological processes in northern forest soils. Forest Ecology andManagement 133: 43–60.
  • Mueller K.E., Eissenstat D.M., Hobbie S.E., Oleksyn J., Jagodzinski A.M., Reich P.B., Chadwick O.A., Chorover J. 2012. Tree species effects on coupled cycles of carbon, nitrogen, andacid ity in mineral soils at a common garden experiment. Biogeochemistry (DOI 10.1007/s10533-011-9695-7).
  • Nieminen T., Helmisaari H.–S. 1996. Nutrient retranslocation in the foliage of Pinus sylvestris L growing along a heavy metal pollution gradient. Tree Physiology 16: 825–831.
  • Oleksyn J., Reich P.B., Zytkowiak R., Karolewski P., Tjoelker M.G. 2003. Nutrient conservation increases with latitude of origin in European Pinus sylvestris populations. Oecologia 136: 220–235.
  • Priha O., Grayston S.J., Hiukka R., Pennanen T., Smolander A. 2001. Microbial Community structure and characteristics of the organic matter in soils under Pinus sylvestris, Picea abies and Betula pendula at two mature forest sites. Biology and Fertility of Soils 33: 17–24.
  • Reich P.B., Oleksyn J., Modrzynski J., Mrozinski P., Hobbie S.E., Eissenstat D.M., Chorover J., Chadwick O.A., Hale C.M., Tjoelker M.G. 2005. Linking litter calcium, earthworms andsoil properties: a common garden test with 14 tree species. Ecology Letter 8: 811–818.
  • Sanz-Pérez V., Castro-Díez P., MillardP. 2009. Effects of drought and shade on nitrogen cycling in the leaves andcanopy of Mediterranean Quercus seedlings. Plant and Soil 316: 45–56.
  • Sarcanen K.V. 1971. Precursors andtheir polymeriztion. In: Lignins (Eds. Sarkanen K.V. and Ludwig C.H.). Wiley–Interscience, New York–London–Sydney–Toronto, pp. 95–163.
  • Singleton V.L., Rossi J.A. 1965. Colorimetry of total phenolics with phosphomolybdicphosphotungstic acidreagent. American Journal for Enology and Viticulture 16: 144–158.
  • Skorupski M., Jagodziński A.M., Kałucka I., Kasprowicz M., Wojterska M., Dobies T., Sławska S., Wierzbicka A., Łabędzki A., Oleszyńska-Niżniowska J., Nowiński M., Małek S., Karolewski P., Oleksyn J., Banaszczak P. 2011. Plants, fungi and invertebrates of grandfir [Abies grandis (Douglas ex D. Don) Lindl.] experimental stands in Rogów Arboretum (Poland). Acta Scientiarum Polono Polonorum, Silvarum Colendarum Ratio et Industria Lignaria 10: 39–49.
  • Snedecor W., Cochran W.G. 1976. Statistical methods 6th edition Ames, Iowa, USA The Iowa State University Press, pp. 327–329.
  • Tegelberg R., Julkunen-Tito R., Aphalo P. 2001. The effects of long-term elevatedUV-B on the growth and phenolics of field-grown silver birch (Betula pendula). Global Change Biology 7: 839–848.
  • Trocha L.K., Kałucka I., Stasińska M., Nowak W., Dabert M., Leski T., Rudawska M., Oleksyn J. 2012. Ectomycorrhizal fungal communities of native andnon–native Pinus and Quercus species in a common garden of 35-year-old trees. Mycorrhiza 22: 121–134.
  • Withington J.M., Reich P.B., Oleksyn J., Eissenstat D.M. 2006. Comparisons of structure andlife span in roots andleaves among temperate trees. Ecological Monographs 76: 381–397.
  • Żmuda M., Karolewski P., Giertych M.J., Żytkowiak R., Bąkowski M., Grzebyta J., Oleksyn J. 2008. The effect of light conditions on leaf injury in underbrush shrubs caused by leaf-eating insects. Acta Scientiarum Polonorum, Silvarum Colendarum Ratio et Industria Lignaria 7: 47–57.

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Bibliografia

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