Combinations of mutant FAD2 and FAD3 genes to produce high oleic acid and low linolenic acid soybean oil

High oleic acid soybeans were produced by combining mutant FAD2-1A and FAD2-1B genes. Despite having a high oleic acid content, the linolenic acid content of these soybeans was in the range of 4-6 %, which may be high enough to cause oxidative instability of the oil. Therefore, a study was conducted to incorporate one or two mutant FAD3 genes into the high oleic acid background to further reduce the linolenic acid content. As a result, soybean lines with high oleic acid and low linolenic acid (HOLL) content were produced using different sources of mutant FAD2-1A genes. While oleic acid content of these HOLL lines was stable across two testing environments, the reduction of linolenic acid content varied depending on the number of mutant FAD3 genes combined with mutant FAD2-1 genes, on the severity of mutation in the FAD2-1A gene, and on the testing environment. Combination of two mutant FAD2-1 genes and one mutant FAD3 gene resulted in less than 2 % linolenic acid content in Portageville, Missouri (MO) while four mutant genes were needed to achieve the same linolenic acid in Columbia, MO. This study generated non-transgenic soybeans with the highest oleic acid content and lowest linolenic acid content reported to date, offering a unique alternative to produce a fatty acid profile similar to olive oil.     

Mapping of the loci controlling oleic and linolenic acid contents and development of fad2 and fad3 allele-specific markers in canola (Brassica napus L.)

The quality of canola oil is determined by its constituent fatty acids such as oleic acid (C18:1), linoleic acid (C18:2) and linolenic acid (C18:3). Most canola cultivars normally produce oil with about 55–65% oleic acid and 8–12% linolenic acid. High concentrations of linolenic acid lead to oil instability and off-type flavor, while high levels of oleic acid increase oxidative stability and nutritional value of oil. Therefore, development of canola cultivars with increased oleic acid and reduced linolenic acid is highly desirable for canola oil quality. In this study, we have mapped one locus that has a major effect and one locus that has a minor effect for high oleic acid and two loci that have major effects for low linolenic acid in a doubled haploid population. The major locus for high C18:1 was proven to be the fatty acid desaturase-2 (fad2) gene and it is located on the linkage group N5; the minor locus is located on N1. One major QTL for C18:3 is the fatty acid desaturase-3 gene of the genome C (fad3c) and it is located on N14. The second major QTL resides on N4 and is the fad3a gene of the A genome. We have sequenced genomic clones of the fad2 and fad3c genes amplified from an EMS-induced mutant and a wild-type canola cultivar. A comparison of the mutant and wild-type allele sequences of the fad2 and fad3c genes revealed single nucleotide mutations in each of the genes. Detailed sequence analyses suggested mechanisms by which both the mutations can cause altered fatty acid content. Based on the sequence differences between the mutant and wild-type alleles, two single nucleotide polymorphism (SNP) markers, corresponding to the fad2 and fad3c gene mutations, were developed. These markers will be highly useful for direct selection of desirable fad2 and fad3c alleles during marker-assisted trait introgression and breeding of canola with high oleic and low linolenic acid.     

Simultaneous silencing of FAD2 and FAE1 genes affects both oleic acid and erucic acid contents in Brassica napus seeds

The fatty acid composition in the seed oil was significantly modified following the introduction of transgenes. To further enhance the desirable characteristics of rapeseed oil, it would be beneficial to develop a new approach for the simultaneous silencing of two or more target genes. Our goals in the current study were to (1) increase oleic acid to more than 75%, (2) reduce polyunsaturated fatty acids (PUFA) to about 10% and erucic acid to zero, and (3) accomplish these changes in a single-transformation event. In a single transformation, two fragments amplified from the fatty acid ^Δ12-desaturase 2 (BnaFAD2) and fatty acid elongase 1 (BnaFAE1) genes of Brassica napus were linked together to form a fusion fragment. The fusion fragment was then used to assemble unique intron-spliced hairpin interfering constructs. In the transgenic plant FFRP4-4, the expression of BnaFAD2 and BnaFAE1 genes was completely inhibited. The composition of oleic acid in FFRP4-4 rose to 85%, PUFA dropped to 10% and erucic acid was undetectable. All hybrid F₁ seeds obtained from the reciprocal crossing of FFRP4-4 and GX-parents (with different genetic backgrounds) contained more than 80% oleic acid, about 10% PUFA and very low, or undetectable, erucic acid. The results confirmed that the fusion fragment silencing construct can simultaneously and effectively silence the target genes on a consistent basis. The strategy provides a useful tool for detecting gene function and advancing genetic engineering techniques for the improvement of agricultural crops.     

Mapping of quantitative trait loci and development of allele-specific markers for seed weight in Brassica napus

Seed weight is an important component of grain yield in oilseed rape (Brassica napus L.), but the genetic basis for the important quantitative trait is still not clear. In order to identify the genes for seed weight in oilseed rape, QTL mapping for thousand seed weight (TSW) was conducted with a doubled haploid (DH) population and an F₂ population. A complete linkage map of the DH population was constructed using 297 simple sequence repeat (SSR) markers. Among nine TSW QTLs detected, two major QTLs, TSWA7a and TSWA7b, were stably identified across years and collectively explained 27.6–37.9% of the trait variation in the DH population. No significant epistatic interactions for TSW detected in the DH population indicate that the seed weight variation may be primarily attributed to additive effects. The stability and significance of TSWA7a and TSWA7b were further validated in the F₂ population with different genetic backgrounds. By cloning BnMINI3a and BnTTG2a, two B. napus homologous genes to Arabidopsis thaliana, allele-specific markers were developed for TSWA5b and TSWA5c, two TSW QTLs on A5, respectively. The importance of the major and minor QTLs identified was further demonstrated by analysis of the allelic effects on TSW in the DH population.     

Mapping and cloning of FAD2 gene to develop allele-specific PCR for oleic acid in spring turnip rape (Brassica rapa ssp. oleifera)

The previously identified QTL for oleic acid content observed in an F2 population from the Brassica rapa ssp. oleifera cross Jo4002 × Jo4072 (a high-oleic-acid individual) was mapped more precisely by adding markers to the linkage group which harbours the locus. In addition, the fad2 gene, which is known to encode the 18:1 desaturase in Arabidopsis, was mapped in Brassica, too. The results are consistent with the QTL corresponding to the Arabidopsis fad2 gene. Comparison of the wild-type and high-oleic-acid allele of the locus revealed only one difference in their nucleic acid sequences leading to an amino acid change. This substitution of leucine by proline most likely affects the fold of the protein and thereby activity of the enzyme. Using this base difference, an allele-specific PCR was designed. The allele-specific markers will be very effective in selection for plants with high-oleic-acid content derived from Jo4072 because they are located exactly at the locus and can differentiate between homo- and heterozygotes.     

Microsatellite markers for genome analysis in Brassica. I. development in Brassica napus and abundance in Brassicaceae species

One hundred and twenty one microsatellites were identified by screening a λ phage library of Brassica napus. The distribution of these microsatellites within Brassicaceae species was estimated using 81 locus-specific primer pairs. Most of them (83%) amplified fragments either from Brassica oleracea or Brassica campestris, or from both species, whereas less than 30% detected loci in Brassica nigra. The same was true (30–35%) for more-distantly related crucifer species such as Diplotaxis ssp., Brassica tournefortii, Sinapis alba, Raphanus sativus and Eruca sativa. Only 16 microsatellite-specific primer pairs (19.8%) amplified fragments from Arabidopsis thaliana. Moreover, 61 of the primer pairs detecting 198 polymorphisms were used to estimate the extent of genetic diversity among 32 Brassica napus varieties and breeding lines. On average, four alleles per locus were observed. The spring and winter types of oilseed rape could be clearly distinguished by using the microsatellite markers in a cluster analysis. The results demonstrated the high efficiency of these markers for monitoring genetic diversity. Received: 14 April 2000 / Accepted: 3 July 2000     

Identification of molecular markers associated with linoleic acid desaturation in Brassica napus

 Linolenic acid is a component of canola oil that is readily oxidized, which results in a reduced frying stability and shelf life of the oil. The reduction of linolenic acid in canola seed has therefore been an important breeding objective for many years. The inheritance of linolenic acid concentrations in seed oil is polygenic and is also strongly influenced by the environment. For these reasons, molecular markers are sought to assist in early and reliable selection of desired low linolenic acid genotypes in breeding programmes. Molecular markers associated with low linolenic acid loci were identified in a doubled-haploid population derived from a cross between the Brassica napus lines, ‘Apollo’ (low linolenic)×YN90-1016 (high linolenic) using RAPDs and bulked segregant analysis. A total of 16 markers were distributed over three linkage groups, which individually accounted for 32%, 14% and 5% of the phenotypic variation in linolenic acid content. The rapeseed fad3 gene was mapped near the locus controlling 14% of the variation. The mode of inheritance appeared to be additive, and a QTL analysis showed that collectively the three loci explained 51% of the phenotypic variation within this population. PCR fragments for low linolenic acid ‘Apollo’ alleles (3% linolenic acid) were identified at all three loci. Simultaneous selection for low linolenic acid ‘Apollo’ alleles at each locus resulted in a group of DH lines with 4.0% linolenic acid. The use of these makers in the breeding programme will enhance the breeding of low linolenic acid B. napus cultivars for production in Canada. Received: 23 September 1997 / Accepted: 21 October 1997     

The use of specific DNA markers for the identification of alleles of the FAD3 genes in rape (Brassica napus L.)

Russian Journal of Genetics - A search was conducted for the alleles responsible for the quality of food-grade rapeseed oil in a collection of 21 samples of spring and winter oilseed rape of...     

Two high linolenic mutants of Arabidopsis thaliana contain megabase-scale genome duplications encompassing the FAD3 locus

Understanding the quantitative control of fatty acid desaturation during the biosynthesis of seed storage oil has become a priority area for research, as a consequence of its importance for both human health and the substitution of mineral oil for industrial applications. We have analysed the genome structure of two mutants in Arabidopsis thaliana that show substantially elevated content of the omega‐3 polyunsaturated fatty acid linolenic acid in their seed oil. In one, rfc4, sequences totalling approximately 2 Mb from chromosome 2 have been duplicated and inserted into chromosome 3. In the other mutant, ife, chromosome 2 sequences totalling approximately 1.4 Mb have been duplicated and inserted into a linked position. In both cases, the duplications encompass the FAD3 locus, which encodes the linoleate desaturase responsible for the biosynthesis of linolenic acid for accumulation in seed storage oil. The results show that mutagens such as fast neutrons (used for the induction of rfc4) and T‐DNA (used for the induction of ife, which is not linked to the T‐DNA present in the line) can result in the duplication of very large genome segments. They also show that increasing the dosage of the FAD3‐containing genomic region results in an increase in the linolenic acid content of seed oil. Consequently, screening methods for duplication of FAD3 orthologues in oil crops may be an appropriate approach for the identification of germplasm for breeding varieties with increased proportions of linolenic acid in the oil that they produce.     

Mapping a high oleic acid mutation in winter oilseed rape (Brassica napus L.)

Two winter oilseed rape mutant lines, 7488 and 19661, with a high oleic (HO) acid content in the seed oil were characterized phenotypically. In both mutant lines the HO trait was monogenically inherited. Segregation analysis in an F₂ population derived from a cross between 7488 and 19661 showed the two mutations to be allelic. From a comparison of seed, leaf and root fatty acid composition it was concluded that fad2, the endoplasmic oleic acid desaturase, is affected by the mutation. In a bulked segregant analysis three AFLP markers linked to this mutation were detected and localized on the genetic map of Brassica napus. The markers mapped near the locus of one copy of the fad2 gene in the rapeseed genome. Received: 16 February 2000 / Accepted: 28 March 2000     

Identification of AFLP markers linked to fertility restorer genes for tournefortii cytoplasmic male-sterility system in Brassica napus

The tournefortii cytoplasmic male-sterility system is being used as a method of pollination control to develop hybrids in Brassica napus. Genetic analyses have indicated that two dominant genes, one major ( Rft1) and another minor ( Rft2), were required to achieve complete fertility restoration. Though the major gene ( Rft1) can cause complete fertility restoration on its own, its expression was significantly enhanced in the presence of the minor gene ( Rft2). In the absence of Rft1, Rft2 caused only partial fertility restoration. We used a pair of near-isogenic lines (NILs), differing for the presence/absence of Rf genes, to identify AFLP markers linked to fertility restorer genes. A total of 64 EcoRI/ MseI primer combinations were surveyed which produced 3,225 bands, of which 19 (0.006%) were polymorphic between parental NILs. Primer combinations which led to the identification of polymorphic bands present in fertile parental NILs were used for assaying a mapping population of 70 F(2) plants for determining the segregation pattern of markers. Initial screening resulted in the identification of five AFLP markers. The recombination analyses of these AFLP markers revealed that at least two (EACC/MCTT(105), EAAG/MCTC(80)) were present in the same linkage group along with the Rf loci. Marker EACC/MCTT(105) was separated from the major gene ( Rft1) by a distance of 18.1 cM, while it was 33.2 cM away from the minor fertility restorer gene ( Rft2). Another marker EAAG/MCTC(80) was also located adjacent to Rft1 at a distance of 18.1 cM, but on other side. Identification of flanking markers (EACC/MCTT(105), EAAG/MCTC(80)) for the major fertility restorer gene ( Rft1) provides a crucial component for marker-assisted selection and map-based cloning of the restorer genes, and can hence be used to construct elite restorer genotypes.     

Identification of two novel genes for blackleg resistance in Brassica napus

Blackleg, caused by Leptosphaeria maculans, is a major disease of Brassica napus. Two populations of B. napus DH lines, DHP95 and DHP96, with resistance introgressed from B. rapa subsp. sylvestris, were genetically mapped for resistance to blackleg disease with restriction fragment length polymorphism markers. Examination of the DHP95 population indicated that a locus on linkage group N2, named LepR1, was associated with blackleg resistance. In the DHP96 population, a second locus on linkage group N10, designated LepR2, was associated with resistance. We developed BC₁ and F₂ populations, to study the inheritance of resistance controlled by the genes. Genetic analysis indicated that LepR1 was a dominant nuclear allele, while LepR2 was an incompletely dominant nuclear resistance allele. LepR1 and LepR2 cotyledon resistance was further evaluated by testing 30 isolates from Canada, Australia, Europe, and Mexico. The isolates were from B. napus, B. juncea, and B. oleracea and represented different pathogenicity groups of L. maculans. Results indicated that LepR1 generally conferred a higher level of cotyledon resistance than LepR2. Both genes exhibited race-specific interactions with pathogen isolates; virulence on LepR1 was observed with one isolate, pl87-41, and two isolates, Lifolle 5, and Lifolle 6, were virulent on LepR2. LepR1 prevented hyphal penetration, while LepR2 reduced hyphal growth and inhibited sporulation. Callose deposition was associated with resistance for both loci.     

Development and genetic mapping of microsatellite markers from genome survey sequences in Brassica napus

Microsatellite or simple sequence repeat (SSR) markers are routinely used for tagging genes and assessing genetic diversity. In spite of their importance, there are limited numbers of SSR markers available for Brassica crops. A total of 627 new SSR markers (designated BnGMS) were developed based on publicly available genome survey sequences and used to survey polymorphisms among six B. napus cultivars that serve as parents for established populations. Among these SSR markers, 591 (94.3%) successfully amplified at least one fragment and 434 (73.4%) detected polymorphism among the six B. napus cultivars. No correlation was observed between SSR motifs, repeat number or repeat length with polymorphism levels. A linkage map was constructed using 163 newly developed BnGMS marker loci and anchored with 164 public SSRs in a doubled haploid population. These new markers are evenly distributed over all linkage groups (LGs). Given that the majority of these SSRs are derived from bacterial artificial chromosome (BAC) end sequences, they will be useful in the assignment of their cognate BACs to LGs and facilitate the integration of physical maps with genetic maps for genome sequencing in B. napus. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Mapping of genes affecting linolenic acid content in Brassica rapa ssp. oleifera

F₂ progeny segregating for linolenic acid content were used to identify genes and develop markers for linolenic acid in spring turnip rape (Brassica rapa ssp. oleifera). A candidate gene approach applying the rapeseed fad3 gene and bulked segregant analysis with RAPD markers was used. A total of 27 markers were distributed in three linkage groups which each exhibited a QTL for linolenic acid. Jointly the three QTLs accounted for 73.5% of the variation in linolenic acid level in this population. The fad3 gene was mapped near one QTL controlling 23.5% of the variation. Allele-specific markers were developed for fad3 and can be used for marker-assisted selection in future spring turnip rape breeding programmes.     

Genetic control of linolenic acid concentration in seed oil of rapeseed (Brassica napus L.)

Summary Results from a diallel mating of two rapeseed lines with distinctly different linolenic acid concentration show that this trait is mainly under control of nuclear genes of the embryo. However, significant differences in reciprocal F₁, BC₁ and BC₂ indicate maternal control, which is realized by interaction between maternal genotype and nuclear genes of the embryo. Additionally, temperature exerts considerable influence on the degree of maternal control. Since no reciprocal differences are detectable in F₂, cytoplasmic factors seem not to be involved in the inheritance of linolenic acid concentration. Hypotheses on the physiological nature of maternal control of this trait are discussed.     

Omega-3 fatty acid desaturase (FAD3, FAD7, FAD8) gene expression and linolenic acid content in cowpea leaves submitted to drought and after rehydration

Membrane polyunsaturated fatty acids (PUFA) and particularly linolenic acid (18:3, LA) are known to be implicated in plant tolerance to low temperature. Their role in resistance to drought is much less investigated. In this work, three full-length cDNAs corresponding to omega-3 fatty acid desaturases: fad3 (endoplasmic reticulum), fad7 and fad8 (chloroplastic) were isolated from Vigna unguiculata leaves. Two cowpea cultivars, one drought-tolerant, EPACE-1, and one drought-susceptible, 1183, were compared in terms of fad isoform gene expression and leaf LA contents in plants submitted to water stress followed by rehydration. In EPACE-1, LA content in the main leaf polar lipids increased in response to mild water deficit. Severe water deficits induced a decrease in MGDG LA content while those of PC and DGDG continued to increase. Variations in FAD gene expression, matched those in LA contents. In 1183, LA contents decreased in all lipid classes in response to water stress, as did FAD3 and FAD8 gene expression levels. Rehydration after a moderate water stress induced stimulation mostly in FAD3 gene expression in both cvs. LA contents were equivalent to control levels in EPACE-1. In 1183, they were back to control levels in PC shortly after rehydration but remained low in galactolipids. These results suggested that omega-3 FAD activities were involved in the increase in leaf membrane unsaturation, in the drought tolerant plants whereas the sensitive plants lost PUFAs in response to the treatment. The significance of this discrepancy between the two cvs. in terms of adaptation to drought is discussed.     

Identification,characterization and field testing of Brassica napus mutants producing high‐oleic oils

Producing healthy, high‐oleic oils and eliminating trans‐fatty acids from foods are two goals that can be addressed by reducing activity of the oleate desaturase, FAD2, in oilseeds. However, it is essential to understand the consequences of reducing FAD2 activity on the metabolism, cell biology and physiology of oilseed crop plants. Here, we translate knowledge from studies of fad2 mutants in Arabidopsis (Arabidopsis thaliana) to investigate the limits of non‐GMO approaches to maximize oleic acid in the seed oil of canola (Brassica napus), a species that expresses three active FAD2 isozymes. A series of hypomorphic and null mutations in the FAD2.A5 isoform were characterized in yeast (Saccharomyes cerevisiae). Then, four of these were combined with null mutations in the other two isozymes, FAD2.C5 and FAD2.C1. The resulting mutant lines contained 71–87% oleic acid in their seed oil, compared with 62% in wild‐type controls. All the mutant lines grew well in a greenhouse, but in field experiments we observed a clear demarcation in plant performance. Mutant lines containing less than 80% oleate in the seed oil were indistinguishable from wild‐type controls in growth parameters and seed oil content. By contrast, lines with more than 80% oleate in the seed oil had significantly lower seedling establishment and vigor, delayed flowering and reduced plant height at maturity. These lines also had 7–11% reductions in seed oil content. Our results extend understanding of the B. napusFAD2 isozymes and define the practical limit to increasing oil oleate content in this crop species.     

Mapping of major and modifying genes for high oleic acid content in safflower

Oils with high oleic acid content are in great demand because they have optimal properties for food and non-food uses. Two different levels of high oleic acid content (>75 and >84%) have been reported in safflower (Carthamus tinctorius L.). The trait is mainly controlled by partially recessive alleles at a major gene Ol, but the highest levels have been attributed to modifying genes. The objectives of this research were to map the Ol locus and modifying genes involved in oleic acid content of safflower seeds and to determine the nature of Ol through a candidate gene approach. Two F2 mapping populations from the nuclear male-sterile line CL-1 and the high oleic acid lines CR-6 (>75% oleic acid) and CR-9 (>84%) were developed and phenotyped for oleic acid content at the F2 and F3 seed level. A genetic linkage map comprising 15 linkage groups and 116 random amplified polymorphic DNA, simple sequence repeat (SSR), and sequence-characterized amplified regions marker loci was constructed for the CL-1?×?CR-9 population. The Ol gene was mapped to linkage group (LG) T3 tightly linked to the SSR marker ct365, which was confirmed in the CL-1?×?CR-6 population. Additionally, a quantitative trait locus with a minor effect on increasing oleic acid content was identified on LG T2. The candidate gene approach indicated that an oleoyl-phosphatidylcholine desaturase FAD2-1 locus underlies the Ol gene. Both the genetic information and the markers developed in this research will contribute to marker-assisted selection for high oleic acid content in safflower.