Projects per year
Abstract
Background
Miscanthus has potential as a biomass crop but the development of varieties that are consistently superior to the natural hybrid M. × giganteus has been challenging, presumably because of strong G × E interactions and poor knowledge of the complex genetic architectures of traits underlying biomass productivity and climatic adaptation. While linkage and association mapping studies are starting to generate long lists of candidate regions and even individual genes, it seems unlikely that this information can be translated into effective marker-assisted selection for the needs of breeding programmes. Genomic selection has emerged as a viable alternative, and prediction accuracies are moderate across a range of phenological and morphometric traits in Miscanthus, though relatively low for biomass yield per se.
Methods
We have previously proposed a combination of index selection and genomic prediction as a way of overcoming the limitations imposed by the inherent complexity of biomass yield. Here we extend this approach and illustrate its potential to achieve multiple breeding targets simultaneously, in the absence of a priori knowledge about their relative economic importance, while also monitoring correlated selection responses for non-target traits. We evaluate two hypothetical scenarios of increasing biomass yield by 20 % within a single round of selection. In the first scenario, this is achieved in combination with delaying flowering by 44 d (roughly 20 %), whereas, in the second, increased yield is targeted jointly with reduced lignin (–5 %) and increased cellulose (+5 %) content, relative to current average levels in the breeding population.
Key Results
In both scenarios, the objectives were achieved efficiently (selection intensities corresponding to keeping the best 20 and 4 % of genotypes, respectively). However, the outcomes were strikingly different in terms of correlated responses, and the relative economic values (i.e. value per unit of change in each trait compared with that for biomass yield) of secondary traits included in selection indices varied considerably.
Conclusions
Although these calculations rely on multiple assumptions, they highlight the need to evaluate breeding objectives and explicitly consider correlated responses in silico, prior to committing extensive resources. The proposed approach is broadly applicable for this purpose and can readily incorporate high-throughput phenotyping data as part of integrated breeding platforms.
Miscanthus has potential as a biomass crop but the development of varieties that are consistently superior to the natural hybrid M. × giganteus has been challenging, presumably because of strong G × E interactions and poor knowledge of the complex genetic architectures of traits underlying biomass productivity and climatic adaptation. While linkage and association mapping studies are starting to generate long lists of candidate regions and even individual genes, it seems unlikely that this information can be translated into effective marker-assisted selection for the needs of breeding programmes. Genomic selection has emerged as a viable alternative, and prediction accuracies are moderate across a range of phenological and morphometric traits in Miscanthus, though relatively low for biomass yield per se.
Methods
We have previously proposed a combination of index selection and genomic prediction as a way of overcoming the limitations imposed by the inherent complexity of biomass yield. Here we extend this approach and illustrate its potential to achieve multiple breeding targets simultaneously, in the absence of a priori knowledge about their relative economic importance, while also monitoring correlated selection responses for non-target traits. We evaluate two hypothetical scenarios of increasing biomass yield by 20 % within a single round of selection. In the first scenario, this is achieved in combination with delaying flowering by 44 d (roughly 20 %), whereas, in the second, increased yield is targeted jointly with reduced lignin (–5 %) and increased cellulose (+5 %) content, relative to current average levels in the breeding population.
Key Results
In both scenarios, the objectives were achieved efficiently (selection intensities corresponding to keeping the best 20 and 4 % of genotypes, respectively). However, the outcomes were strikingly different in terms of correlated responses, and the relative economic values (i.e. value per unit of change in each trait compared with that for biomass yield) of secondary traits included in selection indices varied considerably.
Conclusions
Although these calculations rely on multiple assumptions, they highlight the need to evaluate breeding objectives and explicitly consider correlated responses in silico, prior to committing extensive resources. The proposed approach is broadly applicable for this purpose and can readily incorporate high-throughput phenotyping data as part of integrated breeding platforms.
Original language | English |
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Article number | mcy187 |
Pages (from-to) | 521-529 |
Number of pages | 9 |
Journal | Annals of Botany |
Volume | 124 |
Issue number | 4 |
Early online date | 23 Oct 2018 |
DOIs | |
Publication status | Published - 13 Sept 2019 |
Keywords
- selection indices
- genomic selection
- breeding objectives
- economic values
- correlated responses
- Miscanthus sinensis
- Selection indices
- Economic values
- Breeding objectives
- Correlated responses
- Genomic selection
- Breeding
- Genomics
- Selection, Genetic
- Genotype
- Poaceae
- Phenotype
Fingerprint
Dive into the research topics of 'Genomic index selection provides a pragmatic framework for setting and refining multi-objective breeding targets in Miscanthus'. Together they form a unique fingerprint.Projects
- 4 Finished
-
BBSRC Core Strategic Programme in Resilient Crops: Miscanthus
Donnison, I. (PI)
Biotechnology and Biological Sciences Research Council
01 Apr 2017 → 31 Mar 2020
Project: Externally funded research
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A population genomics approach to accelerating the domestication of the energy grass miscanthus
Slavov, G. (PI)
Biotechnology and Biological Sciences Research Council
01 Jan 2014 → 31 Dec 2016
Project: Externally funded research
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Genetic resources for the dissection of bioenergy traits
Donnison, I. (PI) & Clifton-Brown, J. (PI)
01 Apr 2012 → 31 Mar 2017
Project: Externally funded research
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Optimising and sustaining biomass yield
Donnison, I. (PI), Farrar, K. (PI) & Slavov, G. (PI)
01 Apr 2012 → 31 Mar 2017
Project: Externally funded research