Multivariate Genome-wide Association Analyses Reveal the Genetic Basis of Seed Fatty Acid Composition in Oat (<i>Avena sativa</i>L.)

Carlson, Maryn O.; Montilla-Bascón, Gracia; Hoekenga, Owen A.; Tinker, Nicholas A.; Poland, Jesse; Baseggio, Matheus; Sorrells, Mark E.; Jannink, Jean‐Luc; Gore, Michael A.; Yeats, Trevor H.

doi:10.1101/589952

Cited by 5 publications

(10 citation statements)

References 58 publications

(16 reference statements)

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“…This prior has thicker tails compared to the Normal density used in BRR, but will shrink small-effect markers toward zero much stronger than BRR. These frameworks provide a means to estimate marker effects for a range of traits with different genetic architectures, which is consistent with what has been reported for fatty acid traits in oat (Carlson et al, 2019) (Supplementary Figures 1-18).…”

Section: Prediction Of Marker Effects For Fatty Acid Traitssupporting

confidence: 85%

“…The following protocol was used for all experiments that measured fatty acid phenotypes. The methods are described in detail in Campbell et al (2020) and Carlson et al (2019). Briefly, dehulled seeds were homogenized, and 100 mg of pulverized tissue was used to separate polar and non-polar compounds using a biphasic extraction method.…”

Section: Metabolite Profiling For Fatty Acid Methyl Esters (Fame)mentioning

confidence: 99%

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Improving Genomic Prediction for Seed Quality Traits in Oat (Avena sativa L.) Using Trait-Specific Relationship Matrices

Campbell

Yeats

et al. 2021

Front. Genet.

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The observable phenotype is the manifestation of information that is passed along different organization levels (transcriptional, translational, and metabolic) of a biological system. The widespread use of various omic technologies (RNA-sequencing, metabolomics, etc.) has provided plant genetics and breeders with a wealth of information on pertinent intermediate molecular processes that may help explain variation in conventional traits such as yield, seed quality, and fitness, among others. A major challenge is effectively using these data to help predict the genetic merit of new, unobserved individuals for conventional agronomic traits. Trait-specific genomic relationship matrices (TGRMs) model the relationships between individuals using genome-wide markers (SNPs) and place greater emphasis on markers that most relevant to the trait compared to conventional genomic relationship matrices. Given that these approaches define relationships based on putative causal loci, it is expected that these approaches should improve predictions for related traits. In this study we evaluated the use of TGRMs to accommodate information on intermediate molecular phenotypes (referred to as endophenotypes) and to predict an agronomic trait, total lipid content, in oat seed. Nine fatty acids were quantified in a panel of 336 oat lines. Marker effects were estimated for each endophenotype, and were used to construct TGRMs. A multikernel TRGM model (MK-TRGM-BLUP) was used to predict total seed lipid content in an independent panel of 210 oat lines. The MK-TRGM-BLUP approach significantly improved predictions for total lipid content when compared to a conventional genomic BLUP (gBLUP) approach. Given that the MK-TGRM-BLUP approach leverages information on the nine fatty acids to predict genetic values for total lipid content in unobserved individuals, we compared the MK-TGRM-BLUP approach to a multi-trait gBLUP (MT-gBLUP) approach that jointly fits phenotypes for fatty acids and total lipid content. The MK-TGRM-BLUP approach significantly outperformed MT-gBLUP. Collectively, these results highlight the utility of using TGRM to accommodate information on endophenotypes and improve genomic prediction for a conventional agronomic trait.

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Section: Prediction Of Marker Effects For Fatty Acid Traitssupporting

confidence: 85%

Section: Metabolite Profiling For Fatty Acid Methyl Esters (Fame)mentioning

confidence: 99%

Improving Genomic Prediction for Seed Quality Traits in Oat (Avena sativa L.) Using Trait-Specific Relationship Matrices

Campbell

Yeats

et al. 2021

Front. Genet.

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“…Correlation network analyses have been widely used in biology and social sciences to capture causality and precursor/product relationship patterns in functional traits. Despite the elegance of this approach, only a few studies applied network theory to plant root traits (Poorter et al, 2014;Messier et al, 2017;Carlson et al, 2019;Kleyer et al, 2019). In addition to root dry weight, SRL, and average diameter, SRR_M, which is rarely used in functional trait analysis, was identified as one of the hub traits and had substantial effects on the plant phenotype as a whole.…”

Section: Discussionmentioning

confidence: 99%

“…Network analysis with a Gaussian graphical model is more likely to capture causality and precursor/product relationships in trait networks relative to standard correlation analyses (Krumsiek et al, 2011;Carlson et al, 2019). The network analysis and the visualization of trait relationships were carried out with the R package 'qgraph' (Epskamp et al, 2012).…”

Section: Network Analysismentioning

confidence: 99%

Functional phenomics and genetics of the root economics space in winter wheat using high-throughput phenotyping of respiration and architecture

Guo

Ayalew

Seethepalli

et al. 2020

Preprint

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SummaryThe root economics space is a useful framework for plant ecology, but rarely considered for crop ecophysiology. In order to understand root trait integration in winter wheat, we combined functional phenomics with trait economic theory utilizing genetic variation, high-throughput phenotyping, and multivariate analyses.We phenotyped a diversity panel of 276 genotypes for root respiration and architectural traits using a novel high-throughput method for CO2 flux and the open-source software RhizoVision Explorer for analyzing scanned images.We uncovered substantial variation for specific root respiration (SRR) and specific root length (SRL), which were primary indicators of root metabolic and construction costs. Multiple linear regression estimated that lateral root tips had the greatest SRR, and the residuals of this model were used as a new trait. SRR was negatively correlated with plant mass. Network analysis using a Gaussian graphical model identified root weight, SRL, diameter, and SRR as hub traits. Univariate and multivariate genetic analyses identified genetic regions associated with aspects of the root economics space, with underlying gene candidates.Combining functional phenomics and root economics is a promising approach to understand crop ecophysiology. We identified root traits and genomic regions that could be harnessed to breed more efficient crops for sustainable agroecosystems.

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“…After harvest, mature seeds were dehulled and analysed with gas chromatography–mass spectrometry (GC‐MS) and liquid chromatography–mass spectrometry (LC‐MS) at the Proteomics and Metabolomics Facility at Colorado State University following Carlson et al ().…”

Section: Methodsmentioning

confidence: 99%

Heritable temporal gene expression patterns correlate with metabolomic seed content in developing hexaploid oat seed

Gutiérrez-González

Liu

et al. 2020

Plant Biotechnology Journal

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Summary Oat ranks sixth in world cereal production and has a higher content of health‐promoting compounds compared with other cereals. However, there is neither a robust oat reference genome nor transcriptome. Using deeply sequenced full‐length mRNA libraries of oat cultivar Ogle‐C, a de novo high‐quality and comprehensive oat seed transcriptome was assembled. With this reference transcriptome and QuantSeq 3′ mRNA sequencing, gene expression was quantified during seed development from 22 diverse lines across six time points. Transcript expression showed higher correlations between adjacent time points. Based on differentially expressed genes, we identified 22 major temporal co‐expression (TCoE) patterns of gene expression and revealed enriched gene ontology biological processes. Within each TCoE set, highly correlated transcripts, putatively commonly affected by genetic background, were clustered and termed genetic co‐expression (GCoE) sets. Seventeen of the 22 TCoE sets had GCoE sets with median heritabilities higher than 0.50, and these heritability estimates were much higher than that estimated from permutation analysis, with no divergence observed in cluster sizes between permutation and non‐permutation analyses. Linear regression between 634 metabolites from mature seeds and the PC1 score of each of the GCoE sets showed significantly lower p‐values than permutation analysis. Temporal expression patterns of oat avenanthramides and lipid biosynthetic genes were concordant with previous studies of avenanthramide biosynthetic enzyme activity and lipid accumulation. This study expands our understanding of physiological processes that occur during oat seed maturation and provides plant breeders the means to change oat seed composition through targeted manipulation of key pathways.

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Multivariate Genome-wide Association Analyses Reveal the Genetic Basis of Seed Fatty Acid Composition in Oat (Avena sativaL.)

Cited by 5 publications

References 58 publications

Improving Genomic Prediction for Seed Quality Traits in Oat (Avena sativa L.) Using Trait-Specific Relationship Matrices

Improving Genomic Prediction for Seed Quality Traits in Oat (Avena sativa L.) Using Trait-Specific Relationship Matrices

Functional phenomics and genetics of the root economics space in winter wheat using high-throughput phenotyping of respiration and architecture

Heritable temporal gene expression patterns correlate with metabolomic seed content in developing hexaploid oat seed

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