Abstract
Clonal variability among trees has been studied and found to have profound effects on nearly all measured phenotypes. However, when estimating wood properties it is important to consider variability within the tree. The position in which a tree is sampled could have a large influence on biomass characterization. We looked at variability in lignin content as height increases and as the number of rings from the pith increase in Populus species. Seven trees were destructively sampled; subsamples were obtained along a 2.4 m length of each stem and across increment rings. All samples were analyzed by pyrolysis molecular beam mass spectroscopy to map the variability across sampling heights and/or ring positions in lignin content. The results of this study indicate that when sampling a tree, there is more variability from ring to ring than at different heights going up the stem.
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References
Apiolaza LA, Garrick DJ (2001) Breeding objectives for three silvicultural regimes of radiata pine. Can J For Res 31:654–662
Borralho NMG, Cotterill PP, Kanowski PJ (1993) Breeding objectives for pulp production of Eucalyptus globulus under different industrial cost structures. Can J For Res 23:648–656
Browning BL (1967) Methods of wood chemistry. Interscience Publishers, New York
Dinus RJ, Payne P, Sewell MM, Chiang VL, Tuskan GA (2000) Genetic modification of short rotation poplar wood properties for energy and fiber production. Crit Rev Plant Sci 20:51–69
Downes GM (1997) Sampling plantation eucalypts for wood and fibre properties. CSIRO Australia Collingwood Vic
Evans RJ, Milne TA, Soltys MN (1986) Direct mass-spectrometric studies of the pyrolysis of carbonaceous fuels. III. Primary pyrolysis of lignin. J Anal Appl Pyrolysis 9:207–236
Evans RJ, Milne TA (1987) Molecular characterization of the pyrolysis of biomass 1. Fundamentals. Energy Fuels 1:123–137
Fries A (1987) Genetics of plus tree progenies of lodgepole pine (Pinus contorta ssp. latifolia), and possible implications for a breeding program in Sweden. Swedish University of Agricultural Sciences Dept. of Forest Genetics and Plant Physiology, Umea Sweden
Gartner BL, North EM, Johnson GR, Singleton R (2002) Effects of live crown on vertical patterns of wood density and growth in Douglas-fir. Can J For Res 32:439–447
Gwaze DP, Harding KJ, Purnell RC, Bridgwater FE (2002) Optimum selection age for wood density in loblolly pine. Can J For Res 32:1393–1399
Igartua DV, Monteoliva SE, Monterubbianesi MG, Villegas MS (2003) Basic density and fibre length at breast height of Eucalyptus globulus ssp. globulus for parameter prediction of the whole tree. IAWA J 24:173–184
Jett JB, Zobel BJ (1975) Wood and pulping properties of young hardwoods. Tappi J 58(1):92–96
Jones PD, Schimleck LR, Peter GF, Daniels RF, Clark AIII (2005) Nondestructive estimation of Pinus taeda L. wood properties for samples from a wide range of sites in Georgia. Can J For Res 35:85–92
Kopp RF, Smart LB, Maynard CA, Isebrands JG, Tuskan GA, Abrahamson LP (2001) The status of genetic improvement of Salix in North America. For Chron 77:287–292
Lambeth C (1980) Juvenile-mature correlations in Pinaceae and implications for early selection. For Sci 26:571–580
Lambeth C, Endo M, Wright J (1994) Genetic analysis of 16 clonal trials of Eucalyptus grandis and comparisons with seedling checks. For Sci 40:397–411
Li B, McKeand SE, Weir RJ (1999) Tree improvement and sustainable forestry – impact of two cycles of loblolly pine breeding in the U.S.A. For Genet 6:229–234
McNaught AD, Wilkinson A (1997) Compendium of chemical terminology. Blackwell Science, Oxford
Muneri A, Raymond CA (2001) Nondestructive sampling of Eucalyptus globulus and E. nitens for wood properties; II. Fibre length and coarseness. Wood Sci Technol 35:41–56
Ona T, Sonoda T, Ito K, Shibata M, Tamai Y, Kojima Y, Ohshima J, Yokota S, Yoshizawa N (2001) Investigation of relationships between cell and pulp properties in Eucalyptus by examination of within-tree property variations. Wood Sci Technol 35:229–243
Osorio L, White T, Huber D (2003) Age-age and trait-trait correlations for Eucalyptus grandis Hill ex Maiden and their implications for optimal selection age and design of clonal trials. Theor Appl Genet 106:735–743
Pilate G, Guiney E, Holt K, Petit-Conil M, Lapierre C, Leple JC, Pollet B, Mila I, Webster EA, Marstorp HG, Hopkins DW, Jouanin L, Boerjan W, Schuch W, Cornu D, Halpin C (2002) Field and pulping performances of transgenic trees with altered lignification. Nat Biotecnol 20:607–612
Rao PV (1998) Statistical research methods in the life sciences. Duxbury Press, Pacific Grove
Raymond CA, Muneri A (2001) Nondestructive sampling of Eucalyptus globulus and E. nitens for wood properties. I. Basic density. Wood Sci Technol 35:27–39
Raymond CA, Banham P, Macdonald A (1998) Within tree variation and genetic control of basic density, fibre length and coarseness in Eucalyptus regnans in Tasmania. Appita J 51:299–305
Raymond CA, Schimleck LR, Muneri A, Michell AJ (2001) Nondestructive sampling of Eucalyptus globulus and E. nitens for wood properties. III. Predicted pulp yield using near infrared reflectance analysis. Wood Sci Technol 35:203–215
Riemenschneider DE, Berguson WE, Dickmann DI, Hall RB, Isebrands JG, Mohn CA, Stanoz GR, Tuskan GA (2001) Poplar breeding and testing strategies in the north-central U.S.: demonstration of potential yield and consideration of future research needs. For Chron 77:245–253
Sarkanen KV, Ludwig CH (1971) Lignins: occurrence, formation, structure, and reactions. Wiley-Interscience, New York
Schimleck LR, Kube PD, Raymond CA (2004) Genetic improvement of kraft pulp yield in Eucalyptus nitens using cellulose content determined by near infrared spectroscopy. Can J For Res 34(11):2363–2370
So CL, Via BK, Groom LH, Schimleck LR, Shupe TF, Kelley SS, Rials TG (2004) Near infrared spectroscopy in the forest products industry. For Prod J 54:6–16
Sykes R, Isik F, Li B, Kadla J, Chang HM (2003) Genetic variation of juvenile wood properties in a loblolly pine progeny test. TAPPI J 2:3–8
Tuskan GA (1998) Short-rotation forestry: what we know and what we need to know. Biomass Bioenergy 14(4):307–315
Tuskan GA, West D, Bradshaw HD, Neale D, Sewell M, Wheeler N, Megraw B, Jech K, Wieslogel A, Evans R, Elam C, Davis M, Davis R (1999) Two high-throughput techniques for determining wood properties as part of a molecular genetics analysis of hybrid poplar and loblolly pine. Appl Biochem Biotechnol 77:55–65
Xiang B, Li B, McKeand S (2003) Genetic gain and selection efficiency of loblolly pine in three geographic regions. For Sci 49:196–208
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Sykes, R., Kodrzycki, B., Tuskan, G. et al. Within tree variability of lignin composition in Populus . Wood Sci Technol 42, 649–661 (2008). https://doi.org/10.1007/s00226-008-0199-0
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DOI: https://doi.org/10.1007/s00226-008-0199-0