Eleven biosynthetic genes explain the majority of natural variation for carotenoid levels in maize grain

Diepenbrock, Christine H.; Ilut, Daniel C.; Magallanes‐Lundback, Maria; Kandianis, Catherine B.; Lipka, Alexander E.; Bradbury, Peter J.; Holland, James B.; Hamilton, John P.; Wooldridge, Edmund; Vaillancourt, Brieanne; Góngora-Castillo, Elsa; Wallace, Jason; Cepela, Jason; Mateos-Hernandez, Maria; Owens, Brenda F.; Tiede, Tyler; Buckler, Edward S.; Rocheford, Torbert; Buell, C. Robin; Gore, Michael A.; DellaPenna, Dean

doi:10.1101/2020.07.15.203448

Cited by 13 publications

(49 citation statements)

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“…lut1 was identified in this study for zeinoxanthin and lutein, with PVEs of 4.5% and 2.7%, respectively (Figure 1, Table 3). Within the β -branch of the carotenoid pathway, β -carotene hydroxylase (CRTRB) preferentially converts β -carotene to β -cryptoxanthin and then zeaxanthin (Diepenbrock et al 2021). crtRB5 (also known as hyd5) was identified with PVEs of 1.6% for β -cryptoxanthin and 1.8% for zeaxanthin.…”

Section: Resultsmentioning

confidence: 99%

“…Within the precursor pathway, DXS has been found to be a rate-limiting activity through genetic engineering and overexpression studies in Arabidopsis and E. coli (Harker and Bramley 1999;Estevez et al 2001). While dxs2 has appeared to be the major controller in maize-with PVEs of 3.5 to 11.3% for dxs2 and 1.2 to 4.1% for dxs3 in the 25 NAM families (Diepenbrock et al 2021)-these ranges were more similar in the present study: 1.0 to 5.2% for dxs2 and 2.2 to 3.3% for dxs3. This could be related to dxs2 having been found to be nearly fixed among yellow inbreds as examined in Fang et al (2020).…”

Section: Discussionmentioning

confidence: 99%

“…Using the phenotypic data from the 10 families, best linear unbiased estimators (BLUEs) were generated from the Chandler et al (2013) kernel color phenotypes and Diepenbrock et al (2021) carotenoid phenotypes using a process similar to that taken in Diepenbrock et al (2021). Briefly, family, RIL within family, year, and field within year were fitted as random effects as a baseline model.…”

Section: Best Linear Unbiased Estimatorsmentioning

confidence: 99%

“…Linkage disequilibrium (LD) was examined within the same HapMap v1 and v2 input data set used for GWAS. Specifically, LD was examined for markers exhibiting one or more significant associations in GWAS (hereafter, GWAS variants) as in Diepenbrock et al (2021), by calculating pairwise correlations between GWAS variants and markers within 250 kb of each variant. A null distribution was generated by calculating the same pairwise correlations for 50,000 randomly selected variants with markers within 250 kb of the respective randomly selected variant.…”

Section: Linkage Disequilibriummentioning

confidence: 99%

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Simultaneous Dissection of Grain Carotenoid Levels and Kernel Color in Biparental Maize Populations with Yellow-to-Orange Grain

LaPorte

Vachev

Fenn

et al. 2021

Preprint

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Maize enriched in provitamin A carotenoids could be key in combatting vitamin A deficiency in human populations relying on maize as a food staple. Consumer studies indicate that orange maize may be regarded as novel and preferred. This study identifies genes of relevance for grain carotenoid concentrations and kernel color, through simultaneous dissection of these traits in 10 families of the U.S. maize nested association mapping population that have yellow to orange grain. Quantitative trait loci (QTL) were identified via joint-linkage analysis, with phenotypic variation explained for individual kernel color QTL ranging from 2.4 to 17.5%. These QTL were cross-analyzed with significant marker-trait associations in a genome-wide association study that utilized ~27 million variants. Nine genes were identified: four encoding activities upstream of the core carotenoid pathway, one at the pathway branchpoint, three within the α- or β-pathway branches, and one encoding a carotenoid cleavage dioxygenase. Of these, three exhibited significant pleiotropy between kernel color and one or more carotenoid traits. Kernel color exhibited moderate positive correlations with β-branch and total carotenoids and negligible correlations with α-branch carotenoids. These findings can be leveraged to simultaneously achieve desirable kernel color phenotypes and increase concentrations of provitamin A and other priority carotenoids.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Best Linear Unbiased Estimatorsmentioning

confidence: 99%

Section: Linkage Disequilibriummentioning

confidence: 99%

See 2 more Smart Citations

Simultaneous Dissection of Grain Carotenoid Levels and Kernel Color in Biparental Maize Populations with Yellow-to-Orange Grain

LaPorte

Vachev

Fenn

et al. 2021

Preprint

Self Cite

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“…(2020a) Carotenoids in kernels LC multiple candidate genes GWAS Baseggio et al. (2020) Carotenoids in kernels HPLC multiple candidate genes linkage mapping and GWAS Diepenbrock et al. (2020) Anthocyanin in kernels HPLC and spectrophotometry multiple candidate genes GWAS Chatham and Juvik, (2021) Metabolite biomarkers for salt tolerance LC-MS cts3 , cyp709b2 , ugt , and multiple candidate genes GWAS Liang et al.…”

Section: Defining Biochemical Pathwaysmentioning

confidence: 99%

The utility of metabolomics as a tool to inform maize biology

Medeiros

Brotman

Fernie

2021

Plant Communications

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With the rise of high-throughput omics tools and the importance of maize and its products as food and bioethanol, maize metabolism has been extensively explored. Modern maize is still rich in genetic and phenotypic variation, yielding a wide range of structurally and functionally diverse metabolites. The maize metabolome is also incredibly dynamic in terms of topology and subcellular compartmentalization. In this review, we examine a broad range of studies that cover recent developments in maize metabolism. Particular attention is given to current methodologies and to the use of metabolomics as a tool to define biosynthetic pathways and address biological questions. We also touch upon the use of metabolomics to understand maize natural variation and evolution, with a special focus on research that has used metabolite-based genome-wide association studies (mGWASs).

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Transcriptome‐wide association and prediction for carotenoids and tocochromanols in fresh sweet corn kernels

et al. 2022

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Sweet corn (Zea mays L.) is consistently one of the most highly consumed vegetables in the United States, providing a valuable opportunity to increase nutrient intake through biofortification. Significant variation for carotenoid (provitamin A, lutein, zeaxanthin) and tocochromanol (vitamin E, antioxidants) levels is present in temperate sweet corn germplasm, yet previous genome‐wide association studies (GWAS) of these traits have been limited by low statistical power and mapping resolution. Here, we employed a high‐quality transcriptomic dataset collected from fresh sweet corn kernels to conduct transcriptome‐wide association studies (TWAS) and transcriptome prediction studies for 39 carotenoid and tocochromanol traits. In agreement with previous GWAS findings, TWAS detected significant associations for four causal genes, β‐carotene hydroxylase (crtRB1), lycopene epsilon cyclase (lcyE), γ‐tocopherol methyltransferase (vte4), and homogentisate geranylgeranyltransferase (hggt1) on a transcriptome‐wide level. Pathway‐level analysis revealed additional associations for deoxy‐xylulose synthase2 (dxs2), diphosphocytidyl methyl erythritol synthase2 (dmes2), cytidine methyl kinase1 (cmk1), and geranylgeranyl hydrogenase1 (ggh1), of which, dmes2, cmk1, and ggh1 have not previously been identified through maize association studies. Evaluation of prediction models incorporating genome‐wide markers and transcriptome‐wide abundances revealed a trait‐dependent benefit to the inclusion of both genomic and transcriptomic data over solely genomic data, but both transcriptome‐ and genome‐wide datasets outperformed a priori candidate gene‐targeted prediction models for most traits. Altogether, this study represents an important step toward understanding the role of regulatory variation in the accumulation of vitamins in fresh sweet corn kernels.

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Eleven biosynthetic genes explain the majority of natural variation for carotenoid levels in maize grain

Cited by 13 publications

References 123 publications

Simultaneous Dissection of Grain Carotenoid Levels and Kernel Color in Biparental Maize Populations with Yellow-to-Orange Grain

Simultaneous Dissection of Grain Carotenoid Levels and Kernel Color in Biparental Maize Populations with Yellow-to-Orange Grain

The utility of metabolomics as a tool to inform maize biology

Transcriptome‐wide association and prediction for carotenoids and tocochromanols in fresh sweet corn kernels

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