Synthesis of low linolenic acid rapeseed (Brassica napus L.) through protoplast fusion

Brassica napus somatic hybrids with low linolenic acid (18:3) content in their seed oil have been produced using fusion partners screened for low 18:3. One somatic hybrid contained only 3.5% 18:3, a level significantly below the mid-parental mean. The low level of 18:3 proved stable in the R₁ generation. Oil content of the lowest 18:3 selection increased from the mid-parental mean (29.3%) in the R₀ generation to 36% in a R₁ field bulk. The R₁ field population also showed some resistance to shattering. This revised version was published online in July 2006 with corrections to the Cover Date.     

Estimating the fatty acid composition of the oil in intact-seed rapeseed (Brassica napus L.) by near-infrared reflectance spectroscopy

The objective of this work was to evaluate the potential of near-infrared reflectance spectroscopy (NIRS) as a rapid method to estimate the fatty acid composition of the oil in intact-seed samples of rapeseed. A total of 549 samples (3 g intact seed) from selected mutant and breeding lines were scanned by NIRS, and 220 of them were selected and scanned again by using two different adapters, which reduced the sample size to 300 and 60 mg, respectively. Selected samples were analysed by gas liquid chromatography and calibration equations for individual fatty acids were developed. Calibrations for oleic, linoleic, linolenic, and erucic acid were highly accurate, with values of r² in cross validation from 0.95 to 0.98 (samples of 3 g), from 0.93 to 0.97 (300 mg), and from 0.84 to 0.96 (60 mg). Calibrations for palmitic and stearic acid were less accurate, with values of r² in cross validation always lower than 0.8, probably because of the narrow range available for these fatty acids. The accuracy of the calibration equations for eicosenoic acid was very low (r² = 0.69 in 3 g samples), although improved equations were developed (r² from 0.78 to 0.91) when the relationship between erucic and eicosenoic acid was taken into account. We conclude that NIRS is a powerful technique to estimate the fatty acid composition of the oil in rapeseed, provided that samples covering a wide range of fatty acid levels are available, with the advantage that such estimation is possible with few additional costs when NIRS is used for the determination of other seed quality traits. This revised version was published online in July 2006 with corrections to the Cover Date.     

Impact of low linolenic acid content on seed yield of winter oilseed rape (Brassica napus L.)

An essential quality improvement of rapeseed oil can be obtained by reduction of its linolenic acid (C18:3) content from about 10% to less than 3% of the total fatty acids. Genotypes low in C18:3 have been developed by mutagenesis. The initial summer rapeseed mutant had been low yielding and highly susceptible to various diseases. It has been debated whether the low C18:3 character can be successfully combined with high seed yield for physiological reasons. Therefore, the low linolenic character of mutant M48 was transferred into high-yielding genotypes by repeated backcrossing to well-adapted low erucic acid, low glucosinolate (00-) winter rapeseed cultivars. Lines with low C18:3 content were selected from BC3 and BC4 generations and examined in 1990–95. Positive selection response for seed yield was shown to continue over the years. Presently, the best lines are yielding as well as the control cultivars being equivalent also in oil and glucosinolate contents. In order to test the effect of a low C18:3 content on seed yield, plants with low and with high C18:3 content, respectively, were selected from 16 segregating BC5-F₂ populations and bulked to form 32 F₃ populations. These ‘isogenic’ bulk populations were tested for field performance at four locations in 1995. The results show that C18:3 content of the seed oil is not associated with seed yield, oil content, beginning of flowering, plant height and disease resistance. Means of relative seed yield for the high and the low linolenic F₃ bulk populations were not significantly different with 88.0% and 86.9% of the control cultivars, respectively. There was a significant interaction between genotypes with high or low C18:3 content and location. This shows that under specific environmental conditions a low C18:3 content may be either favourable or unfavourable. The results indicate that the low C18:3 character of the original mutants per se does not cause a decrease in seed yield, oil content or general field performance.     

利用DH和IF_2群体检测油菜籽粒油酸、亚油酸、亚麻酸含量QTL

以德国冬性甘蓝型油菜Express和中国半冬性甘蓝型油菜SWU07为亲本构建包含261个株系的DH群体和包含234个株系的IF2群体,检测不同年份条件下油菜籽粒油酸、亚油酸、亚麻酸含量相关的QTL。在DH群体4年环境下共检测出71个QTL,在IF2群体2年环境下共检测出4个QTL。去掉在不同年份和群体中置信区间相互重叠的QTL之后,共得到3个品质性状的51个QTL,其中有15个在2年以上环境中被检测到。这些QTL分别分布在13个连锁群上,其中与油酸含量相关的18个,分布于A01、A02、A04、A05、A07、A09、C01连锁群,揭示3.44%～13.97%的表型变异;与亚油酸相关的12个,分布于A02、A06、A09、C01、C02连锁群,揭示3.84%～19.51%的表型变异;与亚麻酸相关的21个,分布于A01、A02、A03、A04、A05、A08、A09、C01、C02、C03、C06连锁群,揭示2.86%～11.91%的表型变异。这些结果将为油菜脂肪酸品质改良提供更多遗传信息。     

New mutants of winter rapeseed (Brassica napus L.) with changed fatty acid composition

Seeds of the winter oilseed rape (Brassica napus L.) line PN 3756/93 were treated with ethyl methanesulphonate to induce mutations in the fatty acid biosynthetic pathway. The seed mutagenic treatment was repeated in the M₂ generation. After treatments, individual seed and plant selections were made for changes in fatty acid composition during several generations of inbreeding. Self‐pollinated plants with changed fatty acid compositions were inbred to obtain genetically homozygous and stable mutant lines. Two mutants, M‐10453 and M‐10464, with increased levels of oleic acid (approximately 76%) and reduced linoleic and linolenic acid contents (8.5% and 7.5%, respectively) were selected. Gene or genes controlling desaturation of oleic acid were probably mutated in these plants. The third mutant, M‐681 had a very low linolenic acid content (approximately 2.6%) and increased linoleic acid content (approximately 26%). This would suggest the occurrence of mutations in genes controlling linoleic acid desaturation. The results of selection work during several generations showed that the environment had substantial influence on the composition of seed oil. This made the search for mutants with modify fatty acid compositions difficult. The induced mutants are not directly usable as new varieties, but can be used as parents in crosses for the development of high quality rapeseed varieties.     

Inheritance of reduced linolenic acid content in the Ethiopian mustard mutant N2-4961

The zero erucic acid Ethiopian mustard lines developed so far are characterized by an exceptionally high linolenic acid content in the seed oil. The mutant line N2‐4961, expressing low linolenic acid content in a high erucic acid background, was developed through chemical mutagenesis. The objective of this research was to study the inheritance of low linolenic acid content in this mutant. Line N2‐4961 was reciprocally crossed with its parent line C‐101 and the linolenic acid content of the reciprocal F₁, F₂ and BC₁ generations was studied. No maternal, cytoplasmic or dominance effects were detected in the analysis of F₁ seeds and F₁ plants from reciprocal crosses. Linolenic acid content segregated in 1: 2: 1 ratios in all the F₂ populations studied, suggesting monogenic inheritance. This was confirmed with the analysis of the reciprocal backcross generation. The simple inheritance of low linolenic acid content in N2‐4961 will facilitate the transference of this trait to zero erucic acid lines of Ethiopian mustard.     

Estimation of seed weight, oil content and fatty acid composition in intact single seeds of rapeseed ( Brassica napus} L.) by near-infrared reflectance spectroscopy

The potential of near-infrared reflectance spectroscopy (NIRS) for the simultaneous analysis of seed weight, total oil content and its fatty acid composition in intact single seeds of rapeseed was studied. A calibration set of 530 single seeds was analysed by both NIRS and gas-liquid chromatography (GLC) and calibration equations for the major fatty acids were developed. External validation with a set of 75 seeds demonstrated a close relationship between NIRS and GLC data for oleic (r = 0.92) and erucic acid (r = 0.94), but not for linoleic (r = 0.75) and linolenic acid (r = 0.73). Calibration equations for seed weight and oil content were developed from a calibration set of 125 seeds. A gravimetric determination was used as reference method for oil content. External validation revealed a coefficient of correlation between NIRS and reference methods of 0.92 for both traits. The performance of the calibration equations for oleic and erucic acid was further studied by analysing two segregating F2 seed populations not represented in the calibration set. The results demonstrated that a reliable selection for both fatty acids in segregating populations can be made by using NIRS. We concluded that a reliable estimation of seed weight, oil content, oleic acid and erucic acid content in intact, single seeds of rapeseed is possible by using NIRS technique. This revised version was published online in July 2006 with corrections to the Cover Date.     

Selection for reduced linolenic acid content in Ethiopian mustard (Brassica carinata Braun)

Reducing linolenic acid content is one of the most important objectives for the development of Ethiopian mustard lines with high oil quality. This work was aimed at searching for variability of the fatty acid composition of oil within a germplasm collection of Ethiopian mustard. A total of 217 lines were analysed by gas-liquid chromatography (GLC) in 1991, and one was selected as having reduced values of both linolenic acid content (10.2% versus 14.0% of total fatty acids as the collection average) and linoleic acid desaturation ratio (LDR, 0.34 versus 0.45). After 3 years of pedigree selection for low linolenic acid content, this line showed, in 1995, average values of this fatty acid of 5.4% and 2.4% in two different environments, compared with 11.6% and 8.3%, respectively, in the control. The values of the LDR were 0.18 and 0.09, respectively, compared with 0.36 and 0.27 in the control line.     

Development of novel clubroot resistant rapeseed lines (Brassica napus L.) effective against Japanese field isolates by marker assisted selection

Clubroot is an important disease infectible to cruciferous plants and a major threat to rapeseed production in Japan. However, no clubroot resistant rapeseed cultivars have been released. We surveyed pathotype variation of six isolates collected from rapeseed fields and found they were classified as pathotype groups 2 and 4 using Japanese F₁ Chinese cabbage cultivars. We produced the resynthesized clubroot resistant Brassica napus harboring two resistant loci, Crr1 and Crr2, by interspecific crossing and developed resistant rapeseed lines for southern and northern regions by marker-assisted selection and backcrossing. We improved the DNA marker for erucic acid content to remove linkage drag between Crr1 and high erucic acid content and successfully selected lines with clubroot resistance and zero erucic acid for northern regions. A novel line, ‘Tohoku No. 106’, suitable for southern regions showed stable resistance against all six isolates and high performance in infested fields. We conclude that Crr1 and Crr2 are important genes for CR rapeseed breeding and marker-assisted selection is effective in improving clubroot resistance.     

Identification of molecular markers associated with oleic and linolenic acid in spring oilseed rape (Brassica napus)

The quality of the oil derived from oilseed rape is determined by its fatty acid composition. Breeding oilseed rape for enhanced oil quality includes the development of cultivars with high oleic and low linolenic acid. Random amplified polymorphic DNA (RAPD) and intersimple sequence repeat (ISSR) techniques were investigated for the development of molecular markers for genes controlling oleic and/or linolenic acid. Markers that were identified were converted to sequence characterized amplified region (SCAR) markers for use in breeding. Molecular markers associated with these two fatty acids were identified in a doubled haploid population derived from a cross between the oilseed rape lines TO99‐5318‐20, very high oleic (>79%) and very low linolenic acid (<2%) × DH12075, high oleic (68%) and higher linolenic acid (>7%). Eight RAPD markers were associated with oleic and linolenic acid contents. The RAPD marker UBC 2₈₃₀ accounted for 43% and 13% of the genetic variation for oleic and linolenic acid levels, respectively. The RAPD marker UBC 153₅₅₀ accounted for 19% of the genetic variation for linolenic acid. The UBC 2₈₃₀ fragment was converted to a SCAR marker. The markers identified in this study should be useful tools for the early generation selection of high oleic and low linolenic acid genotypes in oilseed rape breeding programmes.     

甘蓝型油菜轮回选择研究

以同时携带显性核不育基因Ms和显性不育抑制基因Rf的甘蓝型油菜为父本,含有相应隐性等位基因的同类型油菜为母本,经一代杂交成功地把显性核不育基因导入具不同细胞质来源的基因型中.90%以上的杂种一代\回交和复交组合均表现为1可育:1不育的分离.在第一批转育所用的15个亲本中,有3个对由Ms基因控制的雄性不育性有抑制作用,它们     

Selection for fast germination in rapeseed (Brassica napus L. and B. Campestris L.)

Summary Eleven populations of Brassica napus L. and twelve populations of B. campestris L. were subjected to three cycles of selection for fast germination at 2°C and at 25°C. The seeds from the selected populations, and unselected control populations grown in the same environment as the selected populations, were examined for germination behaviour at 2°C and 25°C, and for growth behaviour at 10°C. The populations in both species responded differently in terms of germination behaviour to selection for fast germination. In most of the populations that did respond positively to selection, selection practised at 2°C was superior to selection at 25°C in improving percent germination at 2°C, and was as good as the selection at 25°C in improving germination rate at the higher temperature. Selection for fast germination had no effect on growth characteristics of B. napus and B. campestris populations grown at 10°C. Thus, selection for fast germination at one low temperature may lead to improvement in germination characteristics over a range of temperatures, but will not necessarily lead to improved growth performance of the selected populations.     

Selection in vitro for erucic-acid content in segregating populations of microspore-derived embryoids of Brassica napus

Microspore culture of Brassica napus under optimized conditions leads to the regeneration of microspore-derived embryoids that, at the late cotyledonary stage, contain large amounts of storage lipids, equal or similar in composition to those found in seeds of the homozygous donor plants. At that stage, the microspore-derived embryoids are large enough to allow the dissection of one cotyledon under aseptic conditions and the determination of its fatty-acid composition. The remaining part of the embryoid can be cultured further and regenerated to give a plant. This offers the possibility of early selection for fatty-acid composition in segregating populations of microspore-derived embryoids. In order to verify this hypothesis, embryoids were generated from microspores of F| plants derived from a cross between doubled haploid lines of the low-erucicacid cv. ‘Duplo’ and the high-erucic-acid cv. ‘Janetzki’. The contents of eicosenoic acid (C20: 1) and erucic acid (C22: 1) in the cotyledons and in the seeds derived from plants regenerated from the remaining parts of the embryoids were highly correlated (rs = 0.85**, P = 0.01). This indicates that, in breeding programmes for high erucic acid, the majority of the microspore—derived embryoids can be discarded at an early stage in vitro. Only microspore-derived embryoids with a high content of C20: 1+C22:1 in the cotyledons need to be transferred to the greenhouse. This report also deals with the addition of abscisic acid (ABA) to the embryoid culture medium to increase the correlation, and discusses the possible application of this system for the selection of high-oleic or low-linolenic types in corresponding microspore-derived embryoid populations.     

Genetic variation of yellow-seeded rapeseed lines (Brassica napus L.) from different genetic sources

In order to breed yellow-seeded rapeseed, 16 yellow-seeded lines of Brassica napus L. derived from eight genetic sources were used. The genetic variation of the seedcoat ratio, the cellulose content of the seedcoat, the oil content of the seedcoat and of the embryo, and also the correlations between these characters of the yellow- and brown-seeded plants from the same line, were analysed by variance analysis and path analysis. The results show that the seedcoat ratio and cellulose content of brown seeds are 4.2% and 17.74%, respectively, higher than that of yellow seeds and the oil content of the seedcoat of brown seeds is 3% lower than that of the yellow seeds, these differences all being highly significant. However, the differences between yellow and brown seeds in 1000-seed weight and oil content of the embryo were very small. Both characters are determined mainly by the genetic background and not by seed colour or seedcoat thickness. The correlation analysis revealed that the seedcoat thickness has a highly significant positive correlation with the cellulose content of the seedcoat and is highly significantly negatively correlated with the seedcoat oil content and the 1000-seed weight. The oil content of the embryo alone has a highly significant negative correlation with 1000-seed weight. In yellow seeds, the seedcoat thickness has a large and directly positive effect on the oil content of the embryo whereas the 1000-seed weight has a negative one; the opposite was found in brown seeds. Selection objectives in breeding yellow seeds in Brassica napus are also discussed.     

Genetic and genotype × environment interaction effects analysis for erucic acid content in rapeseed (Brassica napus L.)

Genetic main effects and genotype × environment (GE) interaction effects for erucic acid content (EAC) in rapeseed(Brassica napus L.) were analyzed for two year data by using the genetic models and corresponding statistical approaches for quantitative traits of diploid plant seeds. Eight parents were included in adiallel mating design in two environments. It was found that the embryo, cytoplasmic and maternal main effects and their GE interaction effects could simultaneously affect the performance of EAC, especially for the cytoplasmic and maternal effects. Since the amount of genetic main effects from the expression of genes in different genetic systems accounted for about 64.1%of the total genetic effects, EAC of rapeseed was mainly controlled by genetic main effects. The total narrow-sense heritability for EAC was 83.6% with the general heritability being 51.9% and the interaction heritability being 31.7%. It was suggested by the predicted genetic effects, that Tower and Youcai 601 were better than other parents for reducing EAC in rapeseed quality breeding. This revised version was published online in July 2006 with corrections to the Cover Date.     

The Inheritance of Polima Cytoplasmic Male Sterility in Brassica napus L.

The restores tested in this study have only one pair of fertility-restoring genes (Rf) but many temperature-sensitive genes (Ts). The Rf genes are alleles at the same locus. The cytoplasm of the restorers RC₁, RC₂, RC₃ and ‘Huaie’ is male sterile, but that of RC₄, is normal.     

Prospects for the Development of Rapeseed (B. napus L.) with Improved Linoleic and Linolenic Acid Content

The special aspects of the Western Australian rape-seed breeding programme for the improvement of C₁₈ fatty acids (FA) have been highlighted. Progress made through the use of ‘Oro’-mutant and IXLIN (interspecific X derived) as sources of genes fur improved C₁₈ FA is discussed. These two donor lines were crossed or intercrossed with high yielding, disease resistant B. napus lines (summer and winter type) or their early generation progenies from interspecific crosses with B. juncea or B. carinata. Tins provided suitable genetic diversity and favourable agronomic background for the introgression of target genes or gene system for improved C₁₈ fatty acids. Many of the polyenoic lines selected from these crosses have indicated scope for combining high linoleic and low linolenic acid levels, with maintenance of good growths and seed development in plants well adapted to the environment.     

Resynthesis of Brassica napus L. for self-incompatibility: self-incompatibility reaction, inheritance and breeding potential

Self-incompatibility (SI) in Brassica has been considered as a pollination control mechanism for commercial hybrid seed production, and so far has been extensively used in vegetable types of Brassicas. Oilseed rape Brassica napus (AACC) is naturally self-compatible in contrast to its parental species that are generally self-incompatible. Introduction of S-alleles from its parental species into oilseed rape is therefore needed to use this pollination control mechanism in commercial hybrid seed production. Self-incompatible lines of B. napus , carrying SI alleles in both A and C genomes, were resynthesized from self-incompatible B. oleracea var. italica (CC) cv.'Green Duke' and self-incompatible B. rapa ssp. oleifera (AA) cv. 'Horizon', 'Colt' and 'AC Parkland'. All resynthesized B. napus lines exhibited strong dominant SI phenotype. Reciprocal cross-compatibility was found between some of these self-incompatible lines. The inheritance of S-alleles in these resynthesized B. napus was digenic confirming that each of the parental genomes contributed one S-locus in the resynthesized B. napus lines. However, the presence of two S-loci in the two genomes was found not to be essential for imparting a strong SI phenotype. Possible use of these dominant self-incompatible resynthesized B. napus lines in hybrid breeding is discussed.     

Production of fertile transgenic Brassica napus by Agrobacterium-mediated transformation of protoplasts

A protocol for Agrobacterium tumefaciens‐mediated transformation of Brassica napus mesophyll protoplasts is described. A strain with a neomycin phosphotransferase (nptII) gene and a KCS gene under control of a napin promoter was used at co‐cultivation. Transformed protoplasts were regenerated to fertile and morphologically normal transgenic plants. Transformants were confirmed by PCR of the nptII gene and NAP/KCS expression cassette, and Southern blot analysis. Seeds of the transformants showed a changed fatty acid profile: two transformants had a higher erucic acid level and differed significantly from that of B. napus. Genetic analysis of the progeny revealed that the kanamycin resistance introduced was inherited in a Mendelian fashion.     

Genetic variation in phytosterol content of winter rapeseed (Brassica napus L.) and development of NIRS calibration equations

Rapeseed oil is one of the richest natural sources of phytosterols, known to reduce the LDL-cholesterol levels, one of the major cardiovascular disease risk factors. Increasing the phytosterol content in rapeseed could give an added value to the oil and derived products. Our objective was to analyse the genetic variation of phytosterol content in modern winter rapeseed cultivars and resynthesized lines following field experiments and to develop a near-infrared reflectance spectroscopic (NIRS) calibration for high throughput estimation of phytosterol content. Phytosterol content as analysed by gas–liquid chromatography ranged from 3565 to 4800 mg/kg seed for modern cultivars and from 2079 to 4329 mg/kg seed for resynthesized lines. The NIRS calibration showed a high fraction of explained variance in cross-validation of 0.81 for total phytosterol content and the standard error of cross-validation was 241 mg/kg. The results show that the cultivars contain already high phytosterol contents. The NIRS calibrations developed for total phytosterol content should be useful for germplasm screening and in breeding programmes aimed at increasing the phytosterol content in rapeseed.