Abstract
The extractive content of lignin and the brown-rot decay-resistance against Coniophora puteana and Poria placenta were studied in larch heartwood from different species and origin (Larix decidua var. decidua, L. decidua var. sudetica, L. kaempferi , L. × eurolepis). The study material consisted of 106 trees from a 39-year old provenance trial in France. The hot-water-soluble extractives were very variable (from5.66% to 20.50% of dry weight), but there was no significant variation between the investigated species and origins. In contrast, acetone extractives, the total amount of phenolics and lignin showed significant differences. The concentration of phenolics and lignin was significantly higher in L. kaempferi and in L. × eurolepis than in L. decidua. The total phenolics content was strongly correlated with decay-resistance in all investigated larch origins. A higher concentration of phenolics goes hand in hand with higher decay resistance and phenolics might therefore be a promising parameter to rapidly evaluate the level of decay-resistance in larch.
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References
Babkin VA, Ostroukhova LA, Malkov YA, Babkin DV, Onuchina NA, Ivanova SZ (2001) Isolation of biologically active compounds from larch wood. 11th ISWPC, International Symposium on Wood and Pulping Chemistry, Nice, France, vol II, pp 119–122
Backa S, Gierer J, Reitberger T, Nilson T (1993) Hydroxyl radical activity associated with the growth of white-rot fungi method. Holzforschung 47:181–187
Beckers EPJ, Militz H, Stevens M (1994) Resistance of acetylated wood to basidiomycetes, soft rot and blue stain. IRG/WP 94–40021. The International Research Group on Wood Preservation, Stockholm
BeMiller JN (1989) Carbohydrates. In: Rowe JW (eds) Natural products of woody plants, vol II. Springer, Berlin Heidelberg New York
Beritognolo I, Magel E, Abdel-Latif A, Charpentier JP, Jay-Allemand C, Breton C (2002) Expression of genes encoding chalcone synthase, flavanone 3-hydroxylase and dihydroflavonol 4-reductase correlates with flavanol accumulation during heartwood formation in Juglans nigra. Tree Physiol 22:291–300
Celimene C, Micales J, Ferge L, Young R (1999) Efficacy of pinosylvins against white rot and brown rot fungi. Holzforschung 53:491–497
Chui YH, MacKinnon-Peters G (1995) Wood properties of exotic larch grown in eastern Canada and north-eastern United States. For Chron 71:639–646
Côté WA, Day AC, Simson BW (1966) Studies on larch arabinogalactan. I. The distribution of arabionogalactan in Larch wood. Holzforschung 20:178–192
DeBell JD, Morrell JJ, Gartner B (1997) Tropolone content of increment cores as an indicator of decay resistance in western red cedar. Wood Fiber Sci 29:364–369
Dix B, Roffael E (1997) Extraktstoffgehalt von Lärchensplint- und kernholz. Holz Roh Werkst 52:336
Eaton RA, Hale MDC (1993) Natural durability In: Hall C (eds) Wood: decay, pests and protection, vol 1. Chapman and Hall, London, pp 311–318
Einspahr DW, Wyckoff GW, Fiscus M (1984) Larch—a fast growing fiber source of the lake states and Northeast. J For 82:104–106
Gierlinger N, Rosner S, Gindl W, Grabner M, Wimmer R, Schwanninger M, Pâques LE (2002a) Wood anatomical and chemical characteristics of different larch wood resources in Europe. In: Proceedings of LARIX 2002, Improvement of larch (Larix sp.) for better growth, stem form and wood quality. INRA, Unité d‘Amélioration, de Génétique et de Physiologie des Arbres forestiers, Gap—Auverge & Limousin, pp 388–395
Gierlinger N, Schwanninger M, Hinterstoisser B, Wimmer R (2002b) Rapid determination of heartwood extractives in Larix sp. by means of Fourier transform near infrared spectroscopy. J Near Infrared Spectrosc 10:203–214
Gierlinger N, Schwanninger M, Wimmer R, Hinterstoisser B, Jacques D, Pâques LE (2003) Estimation of extractives, lignin and natural durability of larch heartwood (Larix spp.) by FT-NIR spectroscopy. In: Proceedings of 12th International Symposium on Wood and Pulping Chemistry. Department of Forest Ecology and Management, Madison, Wisconsin, USA, vol III, pp 51–54
Giwa SAO, Swan EP (1975) Heartwood extractives of a western larch tree (Larix occidentalis Nutt.). Wood Fiber 7:216–221
Green F, Highley TL (1997) Mechanism of brown-rot decay: paradigm or paradox. International Biodeterior Biodegrad 39:113–124
Hakkila P, Nikki M, Palenius I (1972) Suitability of larch as pulpwood for Finland. Papp Trä 54:41–58
Harju AM, Venäläinen M, Anttonen S, Viitanen H, Kainulainen P, Saranpää P, Vapaavuori E (2003) Chemical factors affecting the brown-rot decay resistance of Scots pine heartwood. Trees: 17:263–268
Hart JH (1989) Role of wood exudates and extractives in protecting wood from decay In: Rowe JW (eds) Natural products of woody plants, vol II. Springer, Berlin Heidelberg New York, pp 861–878
Hawley LF, Fleck LC, Richards CA (1924) The relation between natural durability and chemical composition in wood. Ind Eng Chem 16:699–706
Hegnauer R (1962) Chemotaxonomie der Pflanzen. Birkhäuser, Basel
Hillinger C, Höll W, Ziegler H (1996) Lipids and lipolytic enzymes in the trunkwood of Robinia pseudoacacia L. during heartwood formation. I. Radial distribution of lipid classes. Trees 10:376–381
Keith CT, Chauret G (1988) Basic wood properties of European larch from fast-growth plantations in eastern Canada. Can J For Res 18:1325–1331
Knuchel H (1954) Das Holz. H.R. Sauerländer, Aarau
Lang KJ (1987) Die Zusammensetzung der Monoterpen-Fraktion in Zweigen von Larix decidua und L. kaempferi in Abhängigkeit von Jahreszeit und Provenienz. Phyton 29:23–32
Magel EA (2000) Biochemistry and physiology of heartwood formation In: Savidge RA, Barnett JR, Napier R (eds) Cell and molecular biology of wood formation. BIOS Scientific, Oxford, pp 363–376
Nilsson T (1997) Natural durability of larch heartwood against decay. IRG/WP 97–10201. The International Research Group on Wood Preservation, Stockholm
Odonmazig P, Ebringerova A, Machova E, Alföldi J (1994) Structural and molecular properties of arabinogalactan isolated from Mongolian larchwood (Larix dahurica L.). Carbohydr Res 252:317–324
Pâques L.E. (2001). Genetic control of heartwood content in larch. Silvae Genet 50:69–75
Ponder GR, Richards GN (1997) Arabinogalactan from Western larch. III. Alkaline degradation revisited, with novel conclusions on molecular structure. Carbohydr Polym 34:251–261
Reyes-Chilpa R, Gómez-Garibay F, Moreno-Torres G, Jiménez-Estrada M, Quiroz-Vásquez RI (1998) Flavonoids and Isoflavonoids with antifungal properties from Platymiscium yucatanum heartwood. Holzforschung 52:459–462
Rudman P (1963) The causes of natural durability in timber. XI. Some tests on the fungi toxicity of wood extractives and related compounds. Holzforschung 17:54–57
Saranpää P, Piispanen R (1994) Variation in the amount of triglycerols and steryl esters in the outer sapwood of Pinus sylvestris L. Trees 8:228–231
Sasaya T (1987) Distribution and accumulation of extractives in tree trunk. II. Phenolics in the stem of Larix leptolepis Gord. Coll Exp For Hokkaido Univ 44:1417–1434
Schober R (1985) Neue Ergebnisse des II. Internationalen Lärchenprovenienzversuches von 1958/59 nach Aufnahmen von Teilversuchen in 11 europäischen Ländern und den USA. J.D. Sauerländer, Frankfurt
Schultz TP, Nicholas DD (2000) Naturally durable heartwood: evidence for a proposed dual defensive function of the extractives. Phytochemistry 54:47–52
Schultz TP, Hubbard TF, J. L, Fisher TH, Nicholas DD (1990) Role of stilbenes in the natural durability of wood: fungicidal structure-activity relationships. Phytochemistry 29:1501–1507
Schultz TP, Harms WB, Fisher TH, McMurtrey KD, Minn J, Nicholas DD (1995) Durability of angiosperm heartwood: the importance of extractives. Holzforschung 49:29–34
Srinivasan U, Ung T, Taylor A, Cooper PA (1999) Natural durability and waterborne treatability of tamarack. For Prod J 49:82–87
Vance CP, Kirk TK, Sherwood RT (1980) Lignification as a mechanism of disease resistance. Annu Rev Phytopathol 18:259–288
Viitanen H, Paajanen L, Saranpää P, Viitaniemi P (1997) Durability of larch (Larix spp.) wood against brown-rot fungi. IRG/WP 97–10228. The International Research Group on Wood Preservation, Stockholm
Weissmann G, Reck S (1987) Identifizierung von Hybridlärchen mit Hilfe chemischer Merkmale. Silvae Genet 36:60–64
Windeisen E, Wegener G, Lesnino G, Schumacher P (2002) Investigation of the correlation between extractives content and natural durability in 20 cultivated larch trees. Holz Roh Werkst 60:373–374
Zabel RA, Morell JJ (1992) Wood microbiology, decay and its prevention. Academic Press, London
Acknowledgements
The research was funded by the EU-project “Towards a European Larch Wood Chain (FAIR 98–3354)” and the research project “The causes of natural durability in larch” (P15903, Austrian Science Fund).
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Gierlinger, N., Jacques, D., Schwanninger, M. et al. Heartwood extractives and lignin content of different larch species (Larix sp.) and relationships to brown-rot decay-resistance. Trees 18, 230–236 (2004). https://doi.org/10.1007/s00468-003-0300-0
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DOI: https://doi.org/10.1007/s00468-003-0300-0