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Inheritance of basic density and microfibril angle and their variations among full-sib families and their parental clones in Picea glehnii

  • Jun Tanabe , Akira Tamura , Futoshi Ishiguri EMAIL logo , Yuya Takashima , Kazuya Iizuka and Shinso Yokota
Published/Copyright: October 25, 2014
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Holzforschung
From the journal Holzforschung Volume 69 Issue 5

Abstract

Picea glehnii is one of the most important plantation species in Hokkaido, Japan. Basic density (BD) and microfibril angle (MFA) of the S2 layer in latewood tracheid in 16 full-sib families and their six parental clones planted in Hokkaido were examined to clarify among-family and clonal variations of wood properties and their inheritance from parents to offspring. Mean values of BD and MFA in full-sib families and parental clones were 0.36 and 0.35 g cm-3 and 16.1° and 10.7°, respectively. Estimated repeatabilities of BD and MFA in juvenile wood (jW) were higher than those in mature wood. In addition, larger genetic coefficient of variation was detected for jW, indicating that improvement of jW properties is important to Hokkaido’s tree breeding program. Parent-offspring correlation coefficients were positive and significant in all properties. These results suggest that the influence of parental clones on wood properties is inheritable to offspring. Moreover, there were no significant differences between reciprocal crosses of wood properties, suggesting that plus-tree clones with good wood properties can be used as either female or male parents for producing offspring. There is a possibility of improving wood properties in P. glehnii by crossing clones with desirable properties.

Keywords: basic density; microfibril angle; parent-offspring correlation; tree breeding for wood quality
Corresponding author: Futoshi Ishiguri, Faculty of Agriculture, Utsunomiya University, Utsunomiya 321-8505, Japan, e-mail:

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Received: 2014-2-20
Accepted: 2014-9-26
Published Online: 2014-10-25
Published in Print: 2015-7-1

©2015 by De Gruyter

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  15. Chemical and ultrastructural changes of ash wood thermally modified (TMW) using the thermo-vacuum process: II. Immunocytochemical study of the distribution of noncellulosic polysaccharides
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https://doi.org/10.1515/hf-2014-0052
Keywords for this article
basic density; microfibril angle; parent-offspring correlation; tree breeding for wood quality

Articles in the same Issue

  1. Frontmatter
  2. Original Articles
  3. Study on the residual lignin in Eucalyptus globulus sulphite pulp
  4. Hydrogenolysis of lignin in ZnCl2 and KCl as an inorganic molten salt medium
  5. Synthesis of lignin polyols via oxyalkylation with propylene carbonate
  6. Preparation of water-dispersive poly(3,4-ethylenedioxythiophene) (PEDOT) conductive nanoparticles in lignosulfonic acid solution
  7. Properties of polyurethane (PUR) films prepared from liquefied wood (LW) and ethylene glycol (EG)
  8. Dynamic response of earlywood and latewood within annual growth ring structure of Scots pine subjected to changing relative humidity
  9. One-stage thermo-hydro treatment (THT) of hardwoods: an analysis of form stability after five soaking-drying cycles
  10. The variation of tangential rheological properties caused by shrinkage anisotropy and moisture content gradient in white birch disks
  11. Inheritance of basic density and microfibril angle and their variations among full-sib families and their parental clones in Picea glehnii
  12. Mechanical properties and chemical composition of beech wood exposed for 30 and 120 days to white-rot fungi
  13. Chemical improvement of surfaces. Part 3: Covalent modification of Scots pine sapwood with substituted benzoates providing resistance to Aureobasidium pullulans staining fungi
  14. Chemical and ultrastructural changes of ash wood thermally modified using the thermo-vacuum process: I. Histo/cytochemical studies on changes in the structure and lignin chemistry
  15. Chemical and ultrastructural changes of ash wood thermally modified (TMW) using the thermo-vacuum process: II. Immunocytochemical study of the distribution of noncellulosic polysaccharides
  16. Revisiting hardboard properties from the fiber sorting point of view
  17. Effects of acetylation and formalization on the dynamic water vapor sorption behavior of wood
  18. Immune-regulatory activity of methanolic extract of Acacia confusa heartwood and melanoxetin isolated from the extract
  19. Stereomicroscopic optical method for the assessment of load transfer patterns across the wood-adhesive bond interphase
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