Carbon isotope compositions (δ(13) C) of leaf, wood and holocellulose differ among genotypes of poplar and between previous land uses in a short-rotation biomass plantation

Carbon isotope compositions (δ(13) C) of leaf, wood and holocellulose differ among genotypes of poplar and between previous land uses in a short-rotation biomass plantation

The efficiency of water use to produce biomass is a key trait in designing sustainable bioenergy-devoted systems. We characterized variations in the carbon isotope composition (δ(13) C) of leaves, current year wood and holocellulose (as proxies for water use efficiency, WUE) among six poplar genotyp...

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Published in:Plant, cell and environment Vol. 38; no. 1; pp. 144 - 156
Main Authors: Verlinden, M S, Fichot, R, Broeckx, L S, Vanholme, B, Boerjan, W, Ceulemans, R
Format: Journal Article
Language:English
Published: United States Wiley 01-01-2015
Subjects:
Biomass
Carbon - metabolism
Carbon Isotopes - analysis
Cellulose - metabolism
Genetic Variation
Genotype
Life Sciences
Nitrogen - metabolism
Phenotype
Photosynthesis
Plant Leaves - genetics
Plant Leaves - growth & development
Populus - genetics
Populus - growth & development
Populus - physiology
Seasons
Soil - chemistry
Trees
Water - metabolism
Wood - genetics
Wood - growth & development
water use efficiency
water relations
genotypic variations
bioenergy
carbon isotope discrimination
cropland
growth
pasture
Populus spp
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Summary:The efficiency of water use to produce biomass is a key trait in designing sustainable bioenergy-devoted systems. We characterized variations in the carbon isotope composition (δ(13) C) of leaves, current year wood and holocellulose (as proxies for water use efficiency, WUE) among six poplar genotypes in a short-rotation plantation. Values of δ(13) Cwood and δ(13) Cholocellulose were tightly and positively correlated, but the offset varied significantly among genotypes (0.79-1.01‰). Leaf phenology was strongly correlated with δ(13) C, and genotypes with a longer growing season showed a higher WUE. In contrast, traits related to growth and carbon uptake were poorly linked to δ(13) C. Trees growing on former pasture with higher N-availability displayed higher δ(13) C as compared with trees growing on former cropland. The positive relationships between δ(13) Cleaf and leaf N suggested that spatial variations in WUE over the plantation were mainly driven by an N-related effect on photosynthetic capacities. The very coherent genotype ranking obtained with δ(13) C in the different tree compartments has some practical outreach. Because WUE remains largely uncoupled from growth in poplar plantations, there is potential to identify genotypes with satisfactory growth and higher WUE.
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ISSN:0140-7791
1365-3040
DOI:10.1111/pce.12383