Mapping the low palmitate fap1 mutation and validation of its effects in soybean oil and agronomic traits in three soybean populations

Cardinal, Andrea J.; Whetten, Rebecca; Wang, Sanbao; Auclair, Jéròme; Hyten, David L.; Cregan, Perry B.; Bachlava, Eleni; Gillman, Jason D.; Ramirez, Martha E.; Dewey, Ralph E.; Upchurch, Greg; Miranda, Lilian; Burton, J. W.

doi:10.1007/s00122-013-2204-8

Cited by 23 publications

(24 citation statements)

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“…Because this predominant saturated fatty acid in cultivated soybeans is associated with cardiovascular problems [38], efforts have been made to reduce its level [5, 39, 40]. Considerable success has been achieved with the discovery of alleles at two independent loci , fap1 on chromosome nine and fap3 on chromosome five, either of which can reduce palmitic acid levels to as low as 6% or even lower [41, 42]. Unfortunately, these alleles also tend to decrease overall yield [42] and thus compromise their usefulness in soybean breeding regimes.…”

Section: Discussionmentioning

confidence: 99%

“…Considerable success has been achieved with the discovery of alleles at two independent loci , fap1 on chromosome nine and fap3 on chromosome five, either of which can reduce palmitic acid levels to as low as 6% or even lower [41, 42]. Unfortunately, these alleles also tend to decrease overall yield [42] and thus compromise their usefulness in soybean breeding regimes. This suggests that a useful alternate might be to screen wild soybeans for accessions with reduced palmitic acid levels to identify novel genes for eventual transfer to domesticated varieties.…”

Section: Discussionmentioning

confidence: 99%

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A genome-wide association study of seed composition traits in wild soybean (Glycine soja)

et al. 2017

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BackgroundCultivated soybean (Glycine max) is a major agricultural crop that provides a crucial source of edible protein and oil. Decreased amounts of saturated palmitic acid and increased amounts of unsaturated oleic acid in soybean oil are considered optimal for human cardiovascular health and therefore there has considerable interest by breeders in discovering genes affecting the relative concentrations of these fatty acids. Using a genome-wide association (GWA) approach with nearly 30,000 single nucleotide polymorphisms (SNPs), we investigated the genetic basis of protein, oil and all five fatty acid levels in seeds from a sample of 570 wild soybeans (Glycine soja), the progenitor of domesticated soybean, to identify quantitative trait loci (QTLs) affecting these seed composition traits.ResultsWe discovered 29 SNPs located on ten different chromosomes that are significantly associated with the seven seed composition traits in our wild soybean sample. Eight SNPs co-localized with QTLs previously uncovered in linkage or association mapping studies conducted with cultivated soybean samples, while the remaining SNPs appeared to be in novel locations. Twenty-four of the SNPs significantly associated with fatty acid variation, with the majority located on chromosomes 14 (6 SNPs) and seven (8 SNPs). Two SNPs were common for two or more fatty acids, suggesting loci with pleiotropic effects. We also identified some candidate genes that are involved in fatty acid metabolism and regulation. For each of the seven traits, most of the SNPs produced differences between the average phenotypic values of the two homozygotes of about one-half standard deviation and contributed over 3% of their total variability.ConclusionsThis is the first GWA study conducted on seed composition traits solely in wild soybean populations, and a number of QTLs were found that have not been previously discovered. Some of these may be useful to breeders who select for increased protein/oil content or altered fatty acid ratios in the seeds. The results also provide additional insight into the genetic architecture of these traits in a large sample of wild soybean, and suggest some new candidate genes whose molecular effects on these traits need to be further studied.Electronic supplementary materialThe online version of this article (doi:10.1186/s12864-016-3397-4) contains supplementary material, which is available to authorized users.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

A genome-wide association study of seed composition traits in wild soybean (Glycine soja)

et al. 2017

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“…While null alleles of the KAS III gene in Arabidopsis may be lethal, the soybean genome contains KAS III orthologues on chromosome 09 and 18 that may allow more nuanced phenotypic changes to be revealed by mutation in one or the other gene. The fap1 mutation from C1726 was mapped to Glyma.09g277400, a KAS III variant with a splice‐site mutation (Cardinal et al, ). Selection for this allele in soybean results in lower palmitic acid but no other obvious plant phenotypes, perhaps because of a functionally redundant homologue on chromosome 18.…”

Section: Discussionmentioning

confidence: 99%

“…Reductions in palmitic acid in soybean seed oil have also been achieved (Cardinal et al, ; De Vries, Fehr, Welke, & Dewey, ; Wilcox & Cavins, ). Several independent mutations in a soybean acyl‐ACP thioesterase B enzyme encoded by the FATB‐1A gene on chromosome 5 (Glyma.05g012300) have been identified and characterized (Cardinal et al, ; De Vries et al, ; Gillman et al, ; Thapa, Carrero‐Colón, & Hudson, ).…”

Section: Introductionmentioning

confidence: 99%

“…Several independent mutations in a soybean acyl‐ACP thioesterase B enzyme encoded by the FATB‐1A gene on chromosome 5 (Glyma.05g012300) have been identified and characterized (Cardinal et al, ; De Vries et al, ; Gillman et al, ; Thapa, Carrero‐Colón, & Hudson, ). The reduction in soybean seed saturated fatty acids from a splice‐site mutation in a β‐ketoacyl‐[acyl‐carrier‐protein] synthase III gene (KAS III; Glyma.09g277400) was an unexpected result (Cardinal et al, ). The role of the KAS III enzyme was thought to be fundamental to the initiation of fatty acid biosynthesis.…”

Section: Introductionmentioning

confidence: 99%

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The Interaction of the Soybean Seed High Oleic Acid Oil Trait With Other Fatty Acid Modifications

Bilyeu

Škrabišová

Allen

et al. 2018

J Americ Oil Chem Soc

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Oil value is determined by the functional qualities imparted from the fatty acid profile. Soybean oil historically had excellent use in foods and industry; the need to increase the stability of the oil without negative health consequences has led to a decline in soybean oil use. One solution to make the oil stable is to have high oleic acid (>70%) and lower linolenic acid content in the oil. Other fatty acid profile changes are intended to target market needs: low‐saturated fatty acid and high stearic acid content in the oil. The objective of this study is to determine the interaction of the high oleic acid oil trait with other alleles controlling fatty acid profiles. Soybean lines containing high oleic acid allele combinations plus other fatty acid modifying alleles were produced, and the seed was produced in multiple field environments over 2 years. Stable high oleic acid with low linolenic acid (<3.0%) was achieved with a 4‐allele combination. The target of >20% stearic acid in the seed oil was not achieved. Reducing total saturated fatty acids below 7% in a high oleic acid background was possible with mutant alleles of both an acyl‐ACP thioesterase B and a β‐ketoacyl‐[acyl‐carrier‐protein] synthase III gene. The results identified allele combinations that met the target fatty acid profile thresholds and were most stable across environments.

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Mutations in KASIIB result in increased levels of palmitic acid in soybean seeds

Devereaux,

Carrero‐Colón,

Hudson

2024

J Americ Oil Chem Soc

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The plasticity of the lipid profile of soybean oil has made the soybean a crop with value in feed, food and industrial uses. Soybean oil typically consists of approximately 10% of the fully saturated palmitic acid, which has value for industrial purposes, however it is generally undesirable in food applications. Two soybean KASII (ketoacyl‐ACP synthase II) genes have been previously implicated in the control of seed palmitic acid levels. Using forward genetics, we isolated four novel alleles in the GmKASIIB gene that result in increased levels of palmitic acid, ranging from 13% to 16% of the total fatty acid content, over multiple seasons in the field. Three of the KASIIB mutations result in independent amino acid substitutions at conserved positions in the KASII protein, and one single nucleotide polymorphism is likely to cause aberrant splicing of the KASIIB transcript. These new mutations can be used in breeding applications to increase palmitic acid content and to probe the control of fatty acid biosynthesis in soybean seeds.

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Mapping the low palmitate fap1 mutation and validation of its effects in soybean oil and agronomic traits in three soybean populations

Cited by 23 publications

References 50 publications

A genome-wide association study of seed composition traits in wild soybean (Glycine soja)

A genome-wide association study of seed composition traits in wild soybean (Glycine soja)

The Interaction of the Soybean Seed High Oleic Acid Oil Trait With Other Fatty Acid Modifications

Mutations in KASIIB result in increased levels of palmitic acid in soybean seeds

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