Sustainable bioenergy for climate mitigationdeveloping drought-tolerant trees and grasses

Authors Organisations
  • G. Taylor(Author)
    University of Southampton
    University of California, Davis
  • Iain Donnison(Author)
  • Donal Murphy-Bokern(Author)
  • Michele Morgante(Author)
    Universita degli studi di Udine
  • M-B. Bogeat-Triboulot(Author)
    University of Lorraine
  • R. Bhalerao(Author)
    Swedish University of Agricultural Sciences
  • M. Hertzberg(Author)
    SweTree Technologies
  • A. Polle(Author)
    Georg-August Universität Göttingen
  • A. Harfouche(Author)
    University of Tuscia
  • F. Alasia(Author)
    Alasia Franco Vivai
  • V. Petoussi(Author)
    University of Crete
  • D. Trebbi(Author)
  • K. Schwarz(Author)
    Julius Kühn Institute
  • J. J. B. Keurentjes(Author)
    Wageningen University and Research Centre
  • M. Centritto(Author)
    Tree and Timber Institute, Florence
  • B. Genty(Author)
    Aix-Marseille University
  • J. Flexas(Author)
    University of the Balearic Islands
  • E. Grill(Author)
    Technical University of Munich
  • S. Salvi(Author)
    University of Bologna
  • W. J. Davies(Author)
    Lancaster University
Type Article
Original languageEnglish
Article numbermcz146
Pages (from-to)513-520
Number of pages8
JournalAnnals of Botany
Issue number4
Publication statusPublished - 29 Oct 2019
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Background and Aims
Bioenergy crops are central to climate mitigation strategies that utilize biogenic carbon, such as BECCS (bioenergy with carbon capture and storage), alongside the use of biomass for heat, power, liquid fuels and, in the future, biorefining to chemicals. Several promising lignocellulosic crops are emerging that have no food role – fast-growing trees and grasses – but are well suited as bioenergy feedstocks, including Populus, Salix, Arundo, Miscanthus, Panicum and Sorghum.

These promising crops remain largely undomesticated and, until recently, have had limited germplasm resources. In order to avoid competition with food crops for land and nature conservation, it is likely that future bioenergy crops will be grown on marginal land that is not needed for food production and is of poor quality and subject to drought stress. Thus, here we define an ideotype for drought tolerance that will enable biomass production to be maintained in the face of moderate drought stress. This includes traits that can readily be measured in wide populations of several hundred unique genotypes for genome-wide association studies, alongside traits that are informative but can only easily be assessed in limited numbers or training populations that may be more suitable for genomic selection. Phenotyping, not genotyping, is now the major bottleneck for progress, since in all lignocellulosic crops studied extensive use has been made of next-generation sequencing such that several thousand markers are now available and populations are emerging that will enable rapid progress for drought-tolerance breeding. The emergence of novel technologies for targeted genotyping by sequencing are particularly welcome. Genome editing has already been demonstrated for Populus and offers significant potential for rapid deployment of drought-tolerant crops through manipulation of ABA receptors, as demonstrated in Arabidopsis, with other gene targets yet to be tested.

Bioenergy is predicted to be the fastest-developing renewable energy over the coming decade and significant investment over the past decade has been made in developing genomic resources and in collecting wild germplasm from within the natural ranges of several tree and grass crops. Harnessing these resources for climate-resilient crops for the future remains a challenge but one that is likely to be successful.


  • Miscanthus, Populus, Arundo, molecular breeding, next-generation sequencing, marginal land, lignocellulosic crop