Network-based integration of systems genetics data reveals pathways associated with lignocellulosic biomass accumulation and processing

As a consequence of their remarkable adaptability, fast growth, and superior wood properties, eucalypt tree plantations have emerged as key renewable feedstocks (over 20 million ha globally) for the production of pulp, paper, bioenergy, and other lignocellulosic products. However,most biomass proper...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2017-01, Vol.114 (5), p.1195-1200
Main Authors: Mizrachi, Eshchar, Verbeke, Lieven, Christie, Nanette, Fierro, Ana C., Mansfield, Shawn D., Davis, Mark F., Gjersing, Erica, Tuskan, Gerald A., Van Montagu, Marc, Van de Peer, Yves, Marchal, Kathleen, Myburg, Alexander A.
Format: Article
Language:English
Subjects:
09 BIOMASS FUELS
Adaptability
bioenergy
Biological Sciences
Biomass
Carbon - metabolism
cell wall
Cell Wall - metabolism
Chromosome Mapping
Crosses, Genetic
Eucalyptus
Eucalyptus - genetics
Eucalyptus - growth & development
Eucalyptus - metabolism
Gene Expression Regulation, Plant
Gene Regulatory Networks
Genes
Genes, Plant
Genetics
Hybridization, Genetic
Lignin - metabolism
lignocellulosic biomass
Metabolic Networks and Pathways - genetics
Metabolites
Models, Genetic
network-based data integration
Plant biomass
Plant Proteins - genetics
Plant Proteins - metabolism
Plantations
Quantitative Trait Loci
Renewable energy
systems genetics
Wood
Wood - metabolism
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Summary:As a consequence of their remarkable adaptability, fast growth, and superior wood properties, eucalypt tree plantations have emerged as key renewable feedstocks (over 20 million ha globally) for the production of pulp, paper, bioenergy, and other lignocellulosic products. However,most biomass properties such as growth, wood density, and wood chemistry are complex traits that are hard to improve in long-lived perennials. Systems genetics, a process of harnessing multiple levels of component trait information (e.g., transcript, protein, and metabolite variation) in populations that vary in complex traits, has proven effective for dissecting the genetics and biology of such traits. We have applied a network-based data integration (NBDI) method for a systems-level analysis of genes, processes and pathways underlying biomass and bioenergy-related traits using a segregating Eucalyptus hybrid population. We show that the integrative approach can link biologically meaningful sets of genes to complex traits and at the same time reveal the molecular basis of trait variation. Gene sets identified for related woody biomass traits were found to share regulatory loci, cluster in network neighborhoods, and exhibit enrichment for molecular functions such as xylan metabolism and cell wall development. These findings offer a framework for identifying the molecular underpinnings of complex biomass and bioprocessing-related traits. A more thorough understanding of the molecular basis of plant biomass traits should provide additional opportunities for the establishment of a sustainable bio-based economy.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1620119114