Arabidopsis thaliana chromosome III restores fertility in a cytoplasmic male-sterile Brassica napus line with A. thaliana mitochondrial DNA.

Somatic Brassica napus (+) Arabidopsis thaliana hybrids with a cytoplasmic male sterility (CMS)-inducing cytoplasm were screened for fertility-restored plants. One line was selected and recurrently backcrossed with the maintainer line, B. napus, resulting in fertile/sterile segregating populations. Restriction fragment length polymorphism mapping showed the co-segregation of A. thaliana chromosome (chr) III markers with the fertility trait. As it was not possible to stabilise the fertility trait via selfings, a dihaploidisation strategy was assessed. Ninety haploid plants were regenerated and analysed with numerous simple sequence length polymorphism (SSLP) markers. Markers covering both arms of A. thaliana chr III were present in two plants, whereas no A. thaliana DNA could be detected in the other plants. Following colchicine-induced chromosome doubling only these two plants with A. thaliana DNA produced fertile offspring. In one of the two lines, however, the A. thaliana-specific DNA markers and fertility were lost in subsequent generations. The other line remained fertile after repeated selfings. Using genomic in situ hybridisation (GISH) we were able to demonstrate that this latter line possessed a disomic addition of the A. thaliana chromosome. The restored line was comparable to the maintainer line with respect to flower morphology, but the petals and stamens were slightly reduced in size. The homeotic conversion of stamens to pistil-like structures, which is typical for the CMS line, was reversed, and stamens with a normal appearance with viable pollen appeared. Flowering time was as in the CMS line-in both lines it was delayed in comparison to the maintainer line. The introgressed chromosome also contributes to several pleiotropic effects, such as reduced leaf crinkling and shorter stems. The ability to restore fertility through the introgression of nuclear genes from the main cytoplasmic donor species indicates that the CMS trait in this system mainly is due to B. napus/ A. thaliana alloplasmic incompatibility and not mitochondrial DNA rearrangements. Further exploitation of the material is discussed.

Somatic hybrids between Arabidopsis thaliana and cytoplasmic male-sterile radish (Raphanus sativus).

Somatic hybrids were produced by protoplast fusion between Arabidopsis thaliana ecotype Columbia and a male-sterile radish line MS-Gensuke ( Raphanus sativus) with the Ogura cytoplasm. Forty-one shoots were differentiated from the regenerated calli and established as shoot cultures in vitro. About 20 of these shoots were judged to be hybrids based on growth characteristics and morphology. Molecular analyses of 11 shoots were performed, confirming the hybrid features. Of these 11 shoots, eight were established as rooted plants in the greenhouse. Polymerase chain reaction and randomly amplified polymorphic DNA analyses of the nuclear genomes of all analyzed shoots and plants confirmed that they contained hybrid DNA patterns. Their chromosome numbers also supported the hybrid nature of the plants. Investigations of the organelles in the hybrids revealed that the chloroplast (cp) genome was exclusively represented by radish cpDNA, while the mitochondrial DNA configuration showed a combination of both parental genomes as well as fragments unique to the hybrids. Hybrid plants that flowered were male-sterile independent of the presence of the Ogura CMS-gene orf138.

Brassica napus lines with rearranged Arabidopsis mitochondria display CMS and a range of developmental aberrations.

Numerous Brassica napus (+) Arabidopsis thaliana somatic hybrids were screened for male sterility and aberrant flower phenotypes. Nine hybrids were selected and backcrossed recurrently to B. napus. The resulting lines displayed stable maternal inheritance of flower phenotypes. Nuclear and organellar genomes were characterized molecularly using RFLP analysis. No DNA from A. thaliana was found in the nuclear genome after six back-crosses, whilst the mitochondrial genomes contained rearranged DNA from both A. thaliana and B. napus. Each line tested had a unique RFLP pattern of the mitochondrial DNA (mtDNA) that remained unchanged between the BC(3) and BC(6) generation. The plastid genomes consisted of B. napus DNA. Five lines of the BC(5) generation were subjected to more comprehensive investigations of growth, morphology and fertility. On the basis of these investigations, the five CMS lines could be assigned to two groups, one represented by three lines displaying reduced vegetative development, complete male sterility, and homeotic conversions of stamens into feminized structures. The second group, represented by the other two lines, were not completely male-sterile but still displayed severely affected flower morphologies. These two lines did not display any reduction in vegetative development. For both groups only stamens and petals suffered from the morphological and functional aberrations, while the sepals and pistils displayed normal morphology. All plants were fully female-fertile. Different rearrangements of the mitochondrial genome disturbed nuclear-mitochondrial interactions and led to various types of aberrant growth and flower development. The existence of numerous CMS lines with different mitochondrial patterns involving a species with a sequenced genome offers new opportunities to investigate the genetic regulation of CMS and its associated developmental perturbations.

Production of asymmetric hybrids between Arabidopsis thaliana and Brassica napus utilizing an efficient protoplast culture system.

Application of the protoplast culture method developed for Brassica protoplasts to protoplasts of Arabidopsis thaliana has increased the opportunities for interspecific hybridizations involving Arabidopsis. A more-efficient and much-simpler method was established compared to the earlier-reported protocol developed for A. thaliana protoplasts in which alginate beads were utilized. Mesophyll protoplasts of A. thaliana (ecotypes 'Landsberg erecta' and 'Wassilewskija') were cultured in the modified 8p liquid medium, which had been developed for Brassica protoplasts. For comparison, protoplasts were cultured in sodium alginate beads supplied with B5 medium according to the protocol for A. thaliana. The protoplasts divided with high frequencies in the 8p medium, and calli proliferated more rapidly than in the sodium alginate beads. High frequencies of shoot differentiation and regeneration were observed in calli of both ecotypes, from about 30% in the ecotype 'Wassilewskija' to about 60% for 'Landsberg erecta'. The more-rapidly the calli developed, the higher the regeneration frequencies were. Asymmetric hybrids between A. thaliana and Brassica napus were obtained by treating the protoplasts of A. thaliana with iodoacetamide (IOA) and B. napus protoplasts with UV-irradiation before fusion with polyethylene glycol (PEG). By using the culture procedure developed for Brassica protoplasts, calli developed and plants were regenerated. Although most of the plants regenerated after cell fusion were A. thaliana-like and were judged to be escapes from IOA treatment, more than ten plants showed hybrid features of both morphological and molecular characters. Among the hybrids that have flowered so far, both male-fertile and male-sterile plants have been obtained. Back-crossings to A. thaliana are now in progress as is morphological and molecular characterization of the plants.

Defective cell proliferation in the floral meristem of alloplasmic plants of Nicotiana tabacum leads to abnormal floral organ development and male sterility.

Flowers of an alloplasmic male-sterile tobacco line, comprised of the nuclear genome of Nicotiana tabacum and the cytoplasm of Nicotiana repanda, develop short, poorly-pigmented petals and abnormal sterile stamens that often are fused with the carpel wall. The development of flower organ primordia and establishment of boundaries between the different zones in the floral meristem were investigated by performing expression analysis of the tobacco orthologs of the organ identity genes GLO, AG and DEF. These studies support the conclusion that boundary formation was impaired between the organs produced in whorls 3 and 4 resulting in partial fusions between anthers and carpels. According to the investigations cell divisions and floral meristem size in the alloplasmic line were drastically reduced in comparison with the male-fertile tobacco line. The reduction in cell divisions leads to a discrepancy between cell number and cell determination at the stage when petal and stamen primordia should be initiated. At the same stage expression of the homeotic genes was delayed in comparison with the male-fertile line. However, the abnormal organ development was not due to a failure in the spatial expression of the organ identity genes. Instead the aberrant development in the floral organs of whorls 2, 3 and 4 appears to be caused by deficient floral meristem development at an earlier stage. Furthermore, defects in cell proliferation in the floral meristem of the alloplasmic male-sterile line correlates with presence of morphologically modified mitochondria. The putative causes of reduced cell number in the floral meristem and the consequences for floral development are discussed.

Male-sterile tobacco displays abnormal mitochondrial atp1 transcript accumulation and reduced floral ATP/ADP ratio.

Alloplasmic male sterility is commonly obtained in Nicotiana by combining the nucleus from N. tabacum with the cytoplasm from other Nicotiana species. Besides being male-sterile, most of these cultivars also display changes in floral organ structure. Flowers from male-sterile plants containing the nucleus from N. tabacum combined with N. repanda cytoplasm develop stamen with shortened filaments and shrivelled anthers capped with stigmatoids. Male fertility and normal floral development can be restored by introduction of a restorer chromosome fragment from the cytoplasmic donor N. repanda into the N. tabacum nucleus. A novel reading frame, orf274, located upstream of atp1 in the mitochondrial genomes of both N. tabacum and N. repanda, as well as in the male-sterile and fertility-restored plants was identified. Co-transcripts of orf274 and atp1 were detected by RT-PCR in all four cultivars, but these transcripts accumulate to levels detectable by northern hybridization only in male-sterile plants. These co-transcripts neither generate detectable levels of an ORF274 polypeptide nor lead to altered expression of the ATP synthase subunit alpha. Measurement of ATP and ADP steady-state levels, however, revealed that the ATP/ADP ratio is significantly lower in young floral buds of male-sterile plants than in fertile plants.

Characterization of sexual progenies of male-sterile somatic cybrids between Brassica napus and Brassica tournefortii.

Cytogenetic studies were performed on four male-sterile progenies derived from four different cybrids produced between Brassica napus and B. tournefortii using the donor-recipient protoplast fusion method. The objective of these studies was to characterize the nuclear constitution of the plants. Mitotic investigation revealed that three of the four male-sterile lines had 38 chromosomes, which is equal to that of B. napus. The fourth line, C6, had variable chromosome numbers, ranging from 39 to 42 in different plants. The meiotic behavior in each progeny varied distinctly. Of the plants having 38 chromosomes, fairly high chromosome pairing, on average 18.08 bivalents per cell, was detected at metaphase-I. However, univalents with an average of 1.39 per cell, and very low frequencies of trivalents and/or tetravalents, were also observed in the lines. These results revealed that male-sterile cybrid lines were obtained with 38 chromosomes and a relatively high level of chromosome-pairing ability, indicating their potential for establishing a stable male-sterile rapeseed line.

Microdissection and amplification of coding sequences from a chromosome fragment restoring male fertility in alloplasmic male-sterile tobacco.

An alloplasmic male-sterile line of tobacco, containing the nucleus of Nicotiana tabacum and the cytoplasm of Nicotiana repanda, is restored to fertility by introgression of an alien chromosome fragment obtained from the cytoplasm donor. To isolate the restorer gene(s), the alien chromosome fragment was microdissected from metaphase plates of the restored line. The microdissected chromosomes represented only 0.1 pg of DNA, which was amplified using a degenerate oligonucleotide-primed PCR method (DOP-PCR), from which a chromosome fragment specific library was created. Compared with previous strategies used for microcloning, a modified and improved method was developed by the subsequent isolation of expressed sequences. The library was screened with cDNA probes synthesized by reverse transcription and DOP-PCR amplification (RT/DOP-PCR), of total RNAs isolated from early developing restored and male-sterile flower buds. By this strategy, transcribed DNA sequences specific for the restored line were cloned.

Alloplasmic male-sterile Brassica lines containing B. tournefortii mitochondria express an ORF 3' of the atp6 gene and a 32 kDa protein. off.

Analyses of mitochondrial transcription and in organello translation were performed with the Brassica tournefortii cytoplasm. This cytoplasm causes alloplasmic male sterility when combined with the nuclear genomes of B. napus and B. juncea. Mitochondrial RNA and protein banding patterns were compared between the fertile wild species B. tournefortii, an alloplasmic male-sterile B. juncea line, an alloplasmic male-sterile B. napus line and an alloplasmic B. napus line with restored fertility. The analyses were carried out to identify differences in gene expression and to investigate whether alterations in gene expression accompanied male sterility. A difference in transcription patterns between the fertile B. tournefortii and the alloplasmic lines was found for the atp6 gene. The atp6 region was investigated further, since a similar alteration in atp6 transcription has been observed in two other Brassica cytoplasms which are associated with cytoplasmic male sterility (CMS). The additional longer atp6 transcript detected in the alloplasmic lines in the present study was found to contain an open reading frame (ORF) located downstream of the atp6 gene. DNA sequencing revealed that the ORF, orf263, could encode a protein with a predicted molecular weight of about 29 kDa. In organello analysis detected two proteins of 29 and 32 kDa respectively, which were found only in the alloplasmic lines. Furthermore, the 32 kDa protein accompanied male sterility since it was absent in alloplasmic plants restored to fertility. The protein analysis might indicate that orf263 is translated and causes CMS.

Production of intertribal somatic hybrids between Brassica napus L. and Lesquerella fendleri (Gray) Wats.

Intertribal Brassica napus (+) Lesquerella fendleri hybrids have been produced by polyethylene glycol-induced fusions of B. napus hypocotyl and L. fendleri mesophyll protoplasts. Two series of experiments were performed. In the first, symmetric fusion experiments, protoplasts from the two materials were fused without any pretreatments. In the second, asymmetric fusion experiments, X-ray irradiation at doses of 180 and 200 Gy were used to limit the transfer of the L. fendleri genome to the hybrids. X-ray irradiation of L. fendleri mesophyll protoplasts did not suppress the proliferation rate and callus formation of the fusion products but did significantly decrease growth and differentiation of non-fused L. fendleri protoplasts. In total, 128 regenerated plants were identified as intertribal somatic hybrids on the basis of morphological criteria. Nuclear DNA analysis performed on 80 plants, using species specific sequences, demonstrated that 33 plants from the symmetric fusions and 43 plants from the asymmetric fusions were hybrids. Chloroplast and mitochondrial DNA analysis revealed a biased segregation that favoured B. napus organelles in the hybrids from the symmetric fusion experiments. The bias was even stronger in the hybrids from the asymmetric fusion experiments where no hybrids with L. fendleri organelles were found. X-ray irradiation of L. fendleri protoplasts increased the possibility of obtaining mature somatic hybrid plants with improved fertility. Five plants from the symmetric and 24 plants from the asymmetric fusion experiments were established in the greenhouse. From the symmetric fusions 2 plants could be fertilised and set seeds after cross-pollination with B. napus. From the asymmetric fusions 9 plants could be selfed as well as fertilised when backcrossed with B. napus. Chromosome analysis was performed on all of the plants but 1 that were transferred to the greenhouse. Three plants from the symmetric fusions contained 50 chromosomes, which corresponded to the sum of the parental genomes. From the asymmetric fusions, 11 hybrids contained 38 chromosomes. Among the other asymmetric hybrids, plants with 50 chromosomes and with chromosome numbers higher than the sum of the parental chromosomes were found. When different root squashes of the same plant were analysed, a total of 6 plants were found that had different chromosome numbers.

A chimeric and truncated mitochondrial atpA gene is transcribed in alloplasmic cytoplasmic male-sterile tobacco with Nicotiana bigelovii mitochondria.

Protoplast fusions were performed between two sexually produced alloplasmic male-sterile tobacco cultivars, with cytoplasms from Nicotiana bigelovii [Nta (big)S] and N. undulata[Nta(und)S], both of which exhibit homeotic-like phenotypes affecting the petal and stamen whorls. Among the fusion products obtained, both novel male-sterile and pollen-producing cybrid plants were identified. Of the pollen-producing cybrid plants, all of which were indehiscent, some had flowers with stamens that appeared normal when compared to male-fertile tobacco plants. Other hybrid plants were incompletely restored as they exhibited petaloid structures on the anther-bearing pollen-producing stamens. In this study, gel-blot analyses with mitochondrial geneprobes were conducted comparing the mitochondrial DNA of cybrids and male-sterile parents. It was found that the flower morphology typical of the Nta(big)S parental plants, as well as of the novel male-sterile cybrids, coincided with the presence of a chimeric atpA gene copy where an open reading frame of unknown origin was found to be linked in-frame to the 3'-end of a truncated atpA gene. RNA gel-blot hybridizations revealed the presence of atpA transcripts in the malesterile parent Nta(big)S and novel male-sterile cybrids, but which were absent in cybrids capable of pollen production.

Intertribal somatic hybrids between Brassica napus and Thlaspi perfoliatum with high content of the T. perfoliatum-specific nervonic acid.

Protoplast fusions were performed between hypocotyl protoplasts of Brassica napus and mesophyll protoplasts of Thlaspi perfoliatum. The two species are members of the Lepidieae and Brassiceae tribes, respectively, in the family of Brassicaceae. Seeds of T. perfoliatum are rich in the fatty acid C24∶1 (nervonic acid), an oil valuable for technical purposes. In the search for renewable oils to replace the mineral oils, plant breeders have been trying to develop oil crops with a high content of long-chain fatty acids. After fusion of B. napus protoplasts with non-irradiated as well as irradiated protoplasts of T. perfoliatum selection was carried out by flow cytometry and cell sorting. Of the shoots regenerated from different calli 27 were verified as hybrids or partial hybrids using the isoenzyme phosphoglucose isomerase (PGI) as a marker. Another 6 plants were identified as partial hybrids using a T. perfoliatum-specific repetitive DNA sequence. Slot blot experiments were performed to estimate the copy number of the repetitive DNA sequence in the parental species and in the hybrids. In T. perfoliatum there were approximately 10(5) copies per haploid genome, and the range in the hybrids was 1-37% of the value in T. perfoliatum. When the nuclear DNA content of the regenerated shoots was analysed we found partial as well as symmetric hybrids. Even though the rooting and establishment of hybrid shoots in the greenhouse were difficult, resulting in the death of many plants, 19 plants were cultured to full maturity. Seeds obtained from 15 plants were analysed to determine whether they contained nervonic acid, and 5 of the hybrids were found to contain significantly greater amounts of nervonic acid than B. napus.

A high frequency of intergenomic mitochondrial recombination and an overall biased segregation of B. campestris or recombined B. campestris mitochondria were found in somatic hybrids made within Brassicaceae.

Mitochondrial segregation and rearrangements were studied in regenerated somatic hybrids from seven different species combinations produced using reproducible and uniform methods. The interspecific hybridizations were made between closely or more distantly related species within the Brassicaceae and were exemplified by three intrageneric, two intergeneric and two intertribal species combinations. The intrageneric combinations were represented by Brassica campestris (+) B. oleracea, B. napus (+) B. nigra and B. napus (+) B. juncea (tournefortii) hybrids, the intergeneric combinations by B. napus (+) Raphanus sativus and B. napus (+) Eruca sativa hybrids, and the intertribal combinations by B. napus (+) Thlaspi perfoliatum and B. napus (+) Arabidopsis thaliana hybrids. In each species combination, one of the two mitochondrial genotypes was B. campestris since the B. napus cultivar used in the fusions contained this cytoplasm. Mitochondrial DNA (mtDNA) analyses were performed using DNA hybridization with nine different mitochondrial genes as probes. Among the various species combinations, 43-95% of the hybrids demonstrated mtDNA rearrangements. All examined B. campestris mtDNA regions could undergo intergenomic recombination since hybrid-specific fragments were found for all of the mtDNA probes analysed. Furthermore, hybrids with identical hybrid-specific fragments were found for all probes except cox II and rrn18/rrn5, supporting the suggestion that intergenomic recombination can involve specific sequences. A strong bias of hybrids having new atp A-or atp9-associated fragments observed in the intra- and intergeneric combinations could imply that these regions contain sequences that have a high reiteration number, which gives them a higher probability of recombining. A biased segregation of B. campestris-or B. campestris-like mitochondria was found in all combinations. A different degree of phylogenetic relatedness between the fusion partners did not have a significant influence on mitochondrial segregation in the hybrids in this study.

Intertribal somatic hybrids between Brassica napus and Barbarea vulgaris - production of in vitro plantlets.

Intertribal somatic hybrids were produced between Brassica napus and Barbarea vulgaris. The two species belong to the tribes Arabidae and Brassiceae, respectively, B. vulgaris is known to be cold tolerant and of interest to use as a gene donor to rapeseed. Of the plants produced in five fusion experiments six plants were verified to be hybrids by RFLP analysis utilizing one B. vulgaris-specific repetitive DNA sequence and two nuclear probes (rDNA and cruciferin) as markers. When analysing nuclear DNA content in four of these six hybrids, all had a higher DNA content than B. napus. However, mature plants could not be established outside in vitro conditions, indicating problems with compatibility between the species.

Extensive nuclear influence on mitochondrial transcription and genome structure in male-fertile and male-sterile alloplasmic Nicotiana materials.

Nuclear influences on mitochondrial transcription and genome organization were analysed in six different male-fertile and male-sterile alloplasmic Nicotiana cultivars. The alloplasmic materials were compared with the corresponding nuclear species (N. tabacum) and cytoplasmic donor species (N. debneyi, N. rapanda or N. suaveolens) in Northern and Southern analyses using twelve different mitochondrial genes as probes. The investigation revealed that the nucleus exerts extensive influence on the expression and structure of the mitochondrial genome. For the majority of the probes, changes in both mitochondrial transcription and DNA patterns in alloplasmic cultivars were detected. Even though changes in transcription patterns, which correlated with male sterility, were detected for three of the probes (atpA, orf25 and coxII), the changes were not consistent for all the male-sterile materials. Likewise, no consistent association between mtDNA restriction patterns and cytoplasmic male sterility (CMS) was detected.

Modifications of Mitochondrial DNA Cause Changes in Floral Development in Homeotic-like Mutants of Tobacco.

To investigate the influence of mitochondrial genes on stamen development of higher plants, protoplasts from three different, male-sterile tobacco cultivars were fused. The fused cells were cultured individually into calli, from which plants were regenerated. Cybrid plants were obtained that exhibited flowers with recombined biparental male-sterile morphology and with novel male-sterile stamens that differed from any types from sexual or somatic hybridizations described previously. The male-sterile morphologies of these cybrids and their parents support the hypothesis that nuclear-mitochondrial interaction occurs at several stages in tobacco floral development and that several mitochondrial genes are necessary for normal stamen and corolla development. Analysis by restriction endonuclease digestion of mitochondrial DNA of male-sterile cybrids and their parents revealed that the mitochondrial DNA of male-sterile cybrids with parental floral morphology was unchanged when compared with parental mitochondrial DNA. Cybrids that were morphologically similar to one parent's male-sterile phenotype had mitochondrial DNA almost identical to that parent, whereas cybrids with recombined biparental or novel male-sterile phenotypes contained mitochondrial DNA different from both male-sterile parents and from each other. A set of mitochondrial DNA fragments could be correlated with split corollas, a feature found in several tobacco male-sterile cultivars. DNA gel blot analysis using a number of mitochondrial genes confirmed the conclusions based on ethidium bromide staining of mitochondrial DNA restriction digests.

Effects of parental ploidy level and genetic divergence on chromosome elimination and chloroplast segregation in somatic hybrids within Brassicaceae.

Chromosome and organelle segregation after the somatic hybridization of related species with different degrees of genetic divergence were studied by comparing the interspecific somatic hybrids Brassica oleracea (CC) (+) B. campestris (AA), B. napus (AACC) (+) B. oleracea (CC) B. napus (AACC) (+) B. nigra (BB) and B. napus (AACC) (+) B. juncea (AABB) with the intergeneric somatic hybrids B. napus (AACC) (+) Raphanus sativus (RR) and B. napus (AACC) (+) Eruca sativa (EE). Within each combination, some hybrids were found whose DNA content was equal to the sum of parental chromosomes, others had a relatively higher DNA content and in most of the cases, some had a relatively lower content. However, the frequency distribution in these three classes differed significantly between the combinations. A positive correlation between the frequency of hybrids with eliminated chromosomes and the genetic distance between the species in each combination was found. Furthermore, by combining species with different ploidy levels we found a significantly higher degree of chromosome elimination compared to combinations of species with the same ploidy level. In the B. napus (+) B. Nigra, B. napus (+) R. sativus and B. napus (+) E. sativa combinations chromosomes from the B, R and E genomes appeared to be preferentially sorted out, as indicated by the fact that some of the nuclear markers from these genomes were missing in 7-46% of the plants, whereas no plants were lacking B. napus nuclear markers. Fertile hybrids were found in all but the B. napus (+) R. sativus fusion combination; the latter hybrids were male sterile, but female fertile. Hybrids between the A and C genomes were more fertile than hybrids obtained between the distantly related AC and B, R or E genomes, respectively. Analysis of the chloroplast RFLP pattern revealed that chloroplasts in the B. oleracea (+) B. campestris hybrids segregated randomly. A slightly biased segregation, favouring B. napus chloroplasts, was found in the B. napus (+) B. oleracea combination, whereas B. napus chloroplasts were strongly selected for in the B. napus (+) B. juncea, B. napus (+) B. nigra, B. napus (+) R. sativus and B. napus (+) E. sativa somatic hybrids.

The microspore-derived embryo ofBrassica napus L. as a tool for studying embryo-specific lipid biogenesis and regulation of oil quality.

A time-course study of lipid accumulation in microspore-derived embryos and developing zygotic embryos of rapeseed (Brassica napus L. ssp.oleifera) is presented. Rapid storage fat (triacylglycerol) biosynthesis was induced in microspore-derived embryos of oilseed rape (cv 'Topas') when the embryos were transferred from standing cultures (10 ml) to fresh medium (75 ml) and shake cultured. Triacylglycerols accumulated, after a lag period of 7 days, at a linear rate of approximately twice that of the developing zygotic embryo. The fatty acid composition of triacylglycerols in microspore-derived embryos closely parallelled that of the developing zygotic embryos. In the microspore-derived embryos, the amount of phosphatidylcholine, the major substrate for the production of polyunsaturated fatty acids in oilseeds, remained constant during the linear phase of triacylglycerol production, whereas it increased steadily in the zygotic embryos. The fatty acid composition of individual cotyledons from microspore embryos shake cultured for 15 days was compared with that of individual mature seeds. Relative amounts of the major fatty acids, i.e. palmitic, oleic and linoleic acids, were essentially the same, whereas the microspore-derived embryos had about 35% less stearic acid and 35% more linolenic acid than the mature seeds. Variation in the amounts of oleic, linoleic and linolenic acids between seeds was similar to that found between cotyledons of microspore-derived embryos, whereas variation in palmitic and stearic acid levels was significantly lower between microsporederived cotyledons than between the seeds. The results indicate that microspore-derived embryos from shake cultures should be convenient for use in studying the regulation of oil biosynthesis and for rapidly screening for oil quality in genetically altered rapeseed.