Timing and Biosynthetic Potential for Carotenoid Accumulation in Genetically Diverse Germplasm of Maize

Vallabhaneni, Ratnakar; Wurtzel, Eleanore T.

doi:10.1104/pp.109.137042

Cited by 149 publications

(146 citation statements)

References 43 publications

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“…In particular transcript profiling led to discovery of the Hydroxylase3 locus that coincidently mapped to a carotene QTL, thereby prompting investigation of allelic variation in a broader collection. Vallabhaneni & Wurtzel (2009) …”

Section: Carotenoid Biosynthesis and Genetic Controlmentioning

confidence: 99%

“…Genetic variation at crtRB1 also affects hydroxylation efficiency among encoded allozymes, as observed by resultant carotenoid profiles in recombinant expression assays. Similarly, studies on natural maize genetic diversity carried out by Vallabhaneni et al (2009), have provided the identification of hydroxylation genes associated with reduced endosperm provitamin A content. In particular transcript profiling led to discovery of the Hydroxylase3 locus that coincidently mapped to a carotene QTL, thereby prompting investigation of allelic variation in a broader collection.…”

Section: Carotenoid Biosynthesis and Genetic Controlmentioning

confidence: 99%

See 1 more Smart Citation

Genetic Enhancement of Grain Quality-Related Traits in Maize

Hartings¹,

Fracassetti²,

Motto³

2012

Transgenic Plants - Advances and Limitations

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Section: Carotenoid Biosynthesis and Genetic Controlmentioning

confidence: 99%

Section: Carotenoid Biosynthesis and Genetic Controlmentioning

confidence: 99%

Genetic Enhancement of Grain Quality-Related Traits in Maize

Hartings¹,

Fracassetti²,

Motto³

2012

Transgenic Plants - Advances and Limitations

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“…Maize is considered a source of carotenoids, substances that are important for human health, given the capability as antioxidant and the activity as vitamin A precursor of some of these compounds (Rodriguez-Amaya, 2001;Vallabhaneni & Wurtzel, 2009). The variability in the concentration of carotenoids in grains have been observed in maize cultivars and inbred lines, making the increase of concentration these compounds in the edible part of the plant possible by genetic improvement, especially of those of biological significance, provitamin A carotenoids (pVAC), precursors of vitamin A (Janick-Buckner et al, 1999;Kurilich & Juvik, 1999;Cardoso et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Influence of the moisture at harvest and drying process of the grains on the level of carotenoids in maize (Zea mays)

et al. 2015

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Maize is considered a source of carotenoids; however, these compounds are highly unstable, degraded by high temperatures, exposure to light and presence of oxygen. The objective of this work was to evaluate the influence of the moisture and type of drying applied to grains on the level of carotenoids in yellow maize. The experiment was conducted in a completely randomized design (2 × 4 factorial), two levels of initial moisture at the harvest (22 and 19%) and three types of drying (in the sun; in the shade and in a dryer) and control (no drying). The samples of grains after drying with 12% of final moisture were analyzed by concentration of total carotenoids, carotenes (α-carotene + β-carotene), monohydroxilated carotenoids (β-cryptoxanthin), and xanthophylls (lutein + zeaxanthin). Initial moisture, type of drying and the interaction between moisture versus drying influence (p≤0.05) the levels of carotenoids in grains. This is the first report about the drying conditions and harvest's initial moisture as influence on the profile and content of carotenoids in maize grains. Based on the results, this work suggested that the harvest be carried out preferably when the grains present 22% humidity, with drying in a dryer or in shade for further use or storage.

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“…These traits include, for example, the sum of related metabolites or the ratio of two related metabolites, such as precursors or products (Sauer et al, 1999;Weckwerth et al, 2004;Wentzell et al, 2007). With both linkage analysis and GWAS, derived traits that represent ratios based on metabolic pathways or known interactions have generated more significant associations compared with associations from absolute levels of metabolites (Wentzell et al, 2007;Vallabhaneni and Wurtzel, 2009;Wurtzel et al, 2012;Angelovici et al, 2013; GonzalezJorge et al, 2013;Lipka et al, 2013;Owens et al, 2014). One explanation for this phenomenon could be the higher heritability of metabolic ratios compared with content traits (Wentzell et al, 2007).…”

mentioning

confidence: 99%

“…In addition, Gu et al (2010) found that knocking out mitochondrial isovaleryl-CoA dehydrogenase, an enzyme in the Leu degradation pathway, results in a significant increase in 12 FAAs in a seed-specific manner (Gu et al, 2010). Taken together, these findings suggest that the inherent coordination of seed FAAs could be used as a tool to further unravel the genetic basis of quantitative traits, such as amino acids.Forward genetic approaches, such as linkage analysis, have proven to be powerful for identifying quantitative trait loci (QTLs) that control phenotypic variation for phenological and metabolic traits, such as flowering time and levels of carotenoids, tocochromanols, and amino acids in seed (Kowalski et al, 1994; Alonso-Blanco et al, 1998;Yan et al, 2000;Wong et al, 2004;Wentzell et al, 2007;Chander et al, 2008; Balasubramanian et al, 2009;Vallabhaneni and Wurtzel, 2009;Gutiérrez-Rojas et al, 2010;Maloney et al, 2010;Kochevenko and Fernie, 2011). Nevertheless, traditional linkage analysis to identify QTLs in biparental recombinant inbred line (RIL) populations has two major weaknesses: it captures narrow levels of allelic diversity as a result of only two parental lines, and it provides low mapping resolution due to the overall limited number of recombination events that occur while constructing the RIL population (Yu and Buckler, 2006;Korte and Farlow, 2013).…”

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confidence: 99%

Network-Guided GWAS Improves Identification of Genes Affecting Free Amino Acids

et al. 2016

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Amino acids are essential for proper growth and development in plants. Amino acids serve as building blocks for proteins but also are important for responses to stress and the biosynthesis of numerous essential compounds. In seed, the pool of free amino acids (FAAs) also contributes to alternative energy, desiccation, and seed vigor; thus, manipulating FAA levels can significantly impact a seed's nutritional qualities. While genome-wide association studies (GWAS) on branched-chain amino acids have identified some regulatory genes controlling seed FAAs, the genetic regulation of FAA levels, composition, and homeostasis in seeds remains mostly unresolved. Hence, we performed GWAS on 18 FAAs from a 313-ecotype Arabidopsis (Arabidopsis thaliana) association panel. Specifically, GWAS was performed on 98 traits derived from known amino acid metabolic pathways (approach 1) and then on 92 traits generated from an unbiased correlation-based metabolic network analysis (approach 2), and the results were compared. The latter approach facilitated the discovery of additional novel metabolic interactions and singlenucleotide polymorphism-trait associations not identified by the former approach. The most prominent network-guided GWAS signal was for a histidine (His)-related trait in a region containing two genes: a cationic amino acid transporter (CAT4) and a polynucleotide phosphorylase resistant to inhibition with fosmidomycin. A reverse genetics approach confirmed CAT4 to be responsible for the natural variation of His-related traits across the association panel. Given that His is a semiessential amino acid and a potent metal chelator, CAT4 orthologs could be considered as candidate genes for seed quality biofortification in crop plants.Free amino acids (FAAs) play a pivotal role in the central metabolism of plants. FAAs serve as building blocks for protein synthesis and also are precursors for osmolytes, alternative energy, hormones, and key secondary metabolites (Rai, 2002; Araújo et al., 2010;Tzin and Galili, 2010; Angelovici et al., 2011). Studies of both developing and germinating seeds also have implicated FAAs in proper seed development and germination (Angelovici et al., 2010;Galili and Amir, 2013). Still, the genetic control of FAA metabolism in seed remains poorly understood. One reason is that FAA metabolism is tightly intertwined with essential cellular processes in plants, and manipulating FAA levels can have strong deleterious, pleiotropic effects on the entire system (Guyer et al., 1995;Galili, 2011;Ingle, 2011;Pratelli and Pilot, 2014). For example, increasing Lys and Thr inhibits the activity of Asp kinase via a feedback inhibition loop (Clark and Lu, 2015). At high concentrations, this inhibition can lead to starvation of a downstream metabolic product, Met, which inhibits plant growth (Bright et al., 1982;Rognes et al., 1983;Heremans and Jacobs, 1995). In addition, several amino acid catabolic products, such as those emanating from branched-chain amino acids (BCAAs) or Lys degradation pathways, can be chan...

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Timing and Biosynthetic Potential for Carotenoid Accumulation in Genetically Diverse Germplasm of Maize

Cited by 149 publications

References 43 publications

Genetic Enhancement of Grain Quality-Related Traits in Maize

Genetic Enhancement of Grain Quality-Related Traits in Maize

Influence of the moisture at harvest and drying process of the grains on the level of carotenoids in maize (Zea mays)

Network-Guided GWAS Improves Identification of Genes Affecting Free Amino Acids

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