Efficient induction of microspore embryogenesis using abscisic acid,jasmonic acid and salicylic acid in Brassica napus L

The stress hormones abscisic acid (ABA), jasmonic acid (JA) and salicylic acid (SA) play an important role in the regulation of physiological processes and are often used in tissue culture to promote somatic embryogenesis and to enhance the quality of somatic embryos. Despite many studies on Brassica napus microspore culture, the effects of stress hormones (ABA, JA and SA) on microspore embryogenesis are not well explored. In this study, the effects of three incubation periods (6, 12 and 24 h) at different levels of ABA, JA and SA (0, 0.2, 0.5, 1.0, 2.0 and 5.0 mg l^?1) on microspore embryogenesis of rapeseed (B. napus L.) cv. ‘Regent’ were investigated. ABA (0.5 mg l^?1 for 12 h) enhanced microspore embryogenesis by about threefold compared with untreated cultures and increased normal plantlet regeneration by 68 %. ABA treatment also effectively reduced secondary embryo formation at all concentrations tested but enhanced callusing at high levels, for example 67 % at 1.0 mg l^?1 for 24 h. Highest embryo yield (286.0 embryos Petri dish^?1) was achieved using 1.0 mg l^?1 JA for 24 h and highest normal plantlet regeneration (54 %) was observed in cultures exposed to 0.5 mg l^?1 JA for 12 h. JA (5.0 mg l^?1 for 24 h) also reduced the germination of microspore-derived embryos on regeneration medium by 21 %. SA at 0.2 and 0.5 mg l^?1 for 6 h increased microspore embryogenesis (184.0 and 193.4 embryos Petri dish^?1) relative to the control (136.2 embryos Petri dish^?1). However, SA did not improve normal regeneration, secondary embryo formation or callusing. Microspore embryogenesis and plant regeneration could be improved by ABA, JA as well as SA when the appropriate level and duration of incubation were selected.     

Effects of culture density,conditioned medium and feeder cultures on microspore embryogenesis in Brassica napus L. cv. Topas

Summary In microspore cultures of Brassica napus L. cv. Topas, embryo yield increases with culture density up to about 40,000 microspores per ml. A much higher density (100,000 per ml) appears inhibitory to embryogenesis. A relatively high culture density (30,000 or 40,000 per ml) for the first 2–4 days of culture is crucial for embryogenesis, after which cultures may be diluted to allow better embryo growth.Medium conditioned by culturing microspores at 30,000 or 40,000 per ml for 1 day improved microspore-embryo yield in low density cultures (3,000 or 4,000 per ml) more than 3-fold. In contrast, media conditioned with microspores from 1–4 days or 0–4 days of culture were inhibitory.Use of feeder cultures resulted in up to 10-fold increase of embryo yield in low density microspore cultures, depending on the method used. Filter papers and other membranes placed on top of feeders greatly inhibited embryogenesis in the feeder layer as well as microspores cultured on the feeder, possibly due to poorer gaseous exchange.     

Cytoskeletal changes and induction of embryogenesis in microspore and pollen cultures of Brassica napus L.

Microspores and pollen of Brassica napus were cultured under conditions leading to embryo formation. Concomitant changes in cytoskeletal configurations were analysed. The microfilamental cytoskeleton exhibited a loss of polarity in embryogenic cells but cytochalasin treatment revealed that microfilaments do not influence embryogenesis. Two embryogenic pathways started from microspores and were either characterized by turned division planes or by division when the nucleus was in the cell centre. In both cases microtubules clearly exhibited new arrangements and likely played a major role in newly induced symmetrical division. In pollen, embryogenic development started in the vegetative cell provided the generative cell was arrested near the pollen wall. The concomitant disappearance of defined microtubular arrays is likely to be responsible for the positioning of the cell.     

Cold pretreatment enhances microspore embryogenesis in oilseed rape (Brassica napus L.)

Stress is an essential component during embryogenesis induction in microspore culture. Cold pretreatment has been used in cereal microspore culture but very seldom attempted in Brassica microspore culture. The effect of cold pretreatment of flower buds subjected to a liquid medium on microspore embryogenesis was investigated in spring and winter Brassica napus, as well as in B. rapa and B. oleracea. Cold pretreatment significantly enhanced microspore embryogenesis (by 1–7 fold) compared to commonly used microspore culture protocol in B. napus, while it was less effective in B. rapa or even negative in B. oleracea. The appropriate duration of cold pretreatment was found to be 2–4 days, which stimulated the best microspore embryogenesis. Cold pretreatment was also able to promote embryo development including the improvement of embryo quality and acceleration of embryogenesis. When incorporating with medium refreshing, cold pretreatment could initiate the most microspore embryogenesis than any other treatment used. With further improvement cold pretreatment method may have a positive potential in Brassica breeding programmes.     

Improved microspore embryogenesis induction and plantlet regeneration using putrescine,cefotaxime and vancomycin in Brassica napus L.

The effects of three periods of exposure (12, 24 and 48 h) to different levels of putrescine (0, 0.2, 0.5, 1.0, 2.0 and 5.0 mg l^?1), as well as three incubation periods (24, 48 and 72 h) to different levels of cefotaxime and vancomycin (0, 50, 100, 200 and 500 mg l^?1) on microspore embryogenesis of rapeseed cv. ‘Hyola 401’ were assessed. Microspore embryogenesis was enhanced about threefold compared with untreated culture following 48 h treatment with 0.2 mg l^?1 putrescine. Putrescine treatment at 0.5 mg l^?1 for 48 h effectively induced root formation and increased normal plantlet regeneration by 92 % when microspore-derived embryos (MDEs) were transferred to regeneration medium. The highest embryo yield (184.2 embryos Petri dish^?1) was possible when induction medium was supplemented with 50 mg l^?1 cefotaxime for 24 h and the highest normal regeneration was observed in cultures exposed to 50 and 100 mg l^?1 at all durations tested. More abnormal MDEs (76 and 82 %) were observed when microspores treated with 200 and 500 mg l^?1 cefotaxime many of which failed to regenerate normally and resulted in callusing. Vancomycin at 100 mg l^?1 during the 48 h exposure increased the number of MDEs (181.6 embryos Petri dish^?1) in contrast to untreated cultures (93.6 embryos Petri dish^?1) but, normal plantlet regeneration decreased as vancomycin level increased and high callusing (84 and 90 %) was observed with 200 and 500 mg l^?1 for 72 h. Microspore embryogenesis and plant regeneration could be improved by putrescine, cefotaxime and vancomycin when appropriate levels and durations of incubation were selected.     

Mitogen-activated protein kinases are developmentally regulated during stress-induced microspore embryogenesis in Brassica napus L

Plant mitogen-activated protein kinase (MAPK) cascades are involved in extracellular stress signalling pathways, leading to different cellular responses. Stress-induced microspore embryogenesis involves the internalization of an extracellular stress signal, generating a number of cellular responses where MAPK cascades might be involved. These responses include a change of the developmental programme, the entry into an early proliferative stage and, subsequently, into differentiation stages during haploid embryogenesis. In this work we studied the expression during microspore embryogenesis of several kinases, to assess their putative role in these events. The known Brassica napus MAP kinase kinase kinases (MAP3Ks BnMAP3K1, BnMAP3K1 and BnMAP3K, the BnBSK kinase and B. napus extracellular signal-regulated kinase (ERK) homologues were analysed by electron microscope (EM) in situ hybridization, immuno-gold labelling, immunofluorescence and western blotting. The differential in situ expression of these kinases suggests a role for them during embryogenesis. Two different expression patterns were observed, indicating a different regulation. BnMAP3K1, BnMAP3K, and the ERKs showed a pattern consistent with a role mainly in proliferative events. Conversely, BnMAP3K1 and BnBSK, presented a pattern that suggested an involvement in differentiation stages. In addition, ERK homologues migrate to the nucleus immediately after induction, being found in a phosphorylated state in a larger amount.     

Induction of microspore embryogenesis in Brassica napus L. is accompanied by specific changes in protein synthesis

Culture temperature determines the developmental fate of isolated microspores from Brassica napus L. At 18°C, tricellular pollen develops, whereas culture at 32°C for 8 h leads to the quantitative and synchronous induction of embryogenesis, and ultimately to the formation of embryos. We investigated the changes in protein synthesis that are associated with this 8-h inductive period by using in-situ [³⁵S]methionine labeling, followed by two-dimensional (2-D) gel electrophoretic analysis of the radiolabeled proteins. Qualitative and quantitative computer analyses of 2-D [³⁵S]methionine protein patterns showed six polypeptides specifically labeled under embryogenic culture conditions. Eighteen polypeptides incorporated [³⁵S]methionine at a statistically significant higher rate under embryogenic culture conditions (32°C) than in the controls (18°C), whereas one protein was preferentially labeled under non-embryogenic culture conditions (18°C). These results indicate that only a limited number of proteins detectable in the 2-D gels of microspore extracts are associated with the early induction of embryogenesis. The reproducible identification of the differentially radiolabeled proteins in the 2-D gels allow the sequencing of representative peptides and the isolation of the corresponding cDNAs. This may lead to the identification and characterization of proteins associated with the very first stages of plant embryogenesis.Abbreviations 2-D two-dimensional We would like to thank Dr. H. Van Steeg (Rijks Instituut voor Milieubeheer (RIVM), Bilthoven, The Netherlands) for use of the PhosphorImager apparatus. This research was carried out as part of the EC-Bridge project Regulation of the inductive phase of microspore embryogenesis and EC-Science project The role of mitotic and cytoskeletal genes in the induction of plant cell division.     

Effects of Bleomycin on microspore embryogenesis in Brassica napus and detection of somaclonal variation using AFLP molecular markers

Bleomycin, a glycopeptide antibiotic produced by the bacterium Streptomyces verticillus, has been demonstrated to be an effective mutagen in Arabidopsis thaliana. The objective of the present study was to determine the effect of bleomycin on embryo production and to assess the genetic variation of the doubled haploid (DH) populations by amplified fragment length polymorphism (AFLP). The effects of bleomycin on microspore embryogenesis and cell division were investigated using three concentrations of bleomycin in five semi-winter genotypes of Brassica napus viz. T8, T10, B409, P30, and DH1142. Inclusion of bleomycin in the culture medium at a concentration of 0.1 μg ml⁻¹ for 30 min significantly improved embryo production and cell division in all five genotypes. Embryo production was induced at rates two- and four-fold higher than controls after bleomycin treatment. Fifty plants regenerated by microspore embryogenesis treated with bleomycin in addition to non-treated controls of T8, T10, and B409 were selected for AFLP analysis. The results suggest that microspore culture is capable of producing 0.095–0.114% genetic variation, and there was no effect of bleomycin treatment on genetic stabilisation of doubled haploid populations versus the non-treated control.     

Hsp70 and Hsp90 change their expression and subcellular localization after microspore embryogenesis induction in Brassica napus L

A stress treatment of 32 degrees C for at least 8h was able to change the gametophytic program of the microspore, switching it to embryogenesis in Brassica napus, an interesting model for studying this process in vitro. After induction, some microspores started symmetric divisions and became haploid embryos after a few days, whereas other microspores, not sensitive to induction, followed their original gametophytic development. In this work the distribution and ultrastructural localization of two heat-shock proteins (Hsp70 and Hsp90) throughout key stages before and after embryogenesis induction were studied. Both Hsp proteins are rapidly induced, localizing in the nucleus and the cytoplasm. Immunogold labeling showed changes in the distribution patterns of these proteins, these changes being assessed by a quantitative analysis. Inside the nucleus, Hsp70 was found in association with RNP structures in the interchromatin region and in the nucleolus, whereas nuclear Hsp90 was mostly found in the interchromatin region. For Hsp70, the accumulation after the inductive treatment was accompanied by a reversible translocation from the cytoplasm to the nucleus, in both induced (embryogenic) and noninduced (gametophytic) microspores. However, the translocation was higher in embryogenic microspores, suggesting a possible additional role for Hsp70 in the switch to embryogenesis. In contrast, Hsp90 increase was similar in all microspores, occurring faster than for Hsp70 and suggesting a more specific role for Hsp90 in the stress response. Hsp70 and Hsp90 colocalized in clusters in the cytoplasm and the nucleus, but not in the nucleolus. Results indicated that stress proteins are involved in the process of microspore embryogenesis induction. The differential appearance and distribution of the two proteins and their association at specific stages have been determined between the two systems coexisting in the same culture: embryogenic development (induced cells) and development of gametes (noninduced cells).     

Induction of microspore embryogenesis inBrassica napus L. by gamma irradiation and ethanol stress

Summary Gamma irradiation and ethanol stress treatments redirected pollen development to an embryo formation pathway inBrassica napus. Less than 0.01% of microspores developed into embryos at 25°C compared to approximately 2% at 32°C. However, subsequent to gamma irradiation and ethanol treatments up to 1% and 0.7% of microspores formed embryos at 25°C, respectively. Gamma irradiation also enhanced embryogenesis at 32°C. The possible importance of these findings is discussed in relation to microspore embryogenesis.     

Arabinogalactan protein profiles and distribution patterns during microspore embryogenesis and pollen development in Brassica napus

Arabinogalactan proteins (AGPs), present in cell walls, plasma membranes and extracellular secretions, are massively glycosylated hydroxyproline-rich proteins that play a key role in several plant developmental processes. After stress treatment, microspores cultured in vitro can reprogramme and change their gametophytic developmental pathways towards embryogenesis, thereby producing embryos which can further give rise to haploid and double haploid plants, important biotechnological tools in plant breeding. Microspore embryogenesis constitutes a convenient system for studying the mechanisms underlying cell reprogramming and embryo formation. In this work, the dynamics of both AGP presence and distribution were studied during pollen development and microspore embryogenesis in Brassica napus, by employing a multidisciplinary approach using monoclonal antibodies for AGPs (LM2, LM6, JIM13, JIM14, MAC207) and analysing the expression pattern of the BnAGP Sta 39–4 gene. Results showed the developmental regulation and defined localization of the studied AGP epitopes during the two microspore developmental pathways, revealing different distribution patterns for AGPs with different antigenic reactivity. AGPs recognized by JIM13, JIM14 and MAC207 antibodies were related to pollen maturation, whereas AGPs labelled by LM2 and LM6 were associated with embryo development. Interestingly, the AGPs labelled by JIM13 and JIM14 were induced with the change of microspore fate. Increases in the expression of the Sta 39–4 gene, JIM13 and JIM14 epitopes found specifically in 2–4 cell stage embryo cell walls, suggested that AGPs are early molecular markers of microspore embryogenesis. Later, LM2 and LM6 antigens increased progressively with embryo development and localized on cell walls and cytoplasmic spots, suggesting an active production and secretion of AGPs during in vitro embryo formation. These results give new insights into the involvement of AGPs as potential regulating/signalling molecules in microspore reprogramming and embryogenesis.     

Effects of genotypes and culture conditions on microspore embryogenesis and plant regeneration in several subspecies of Brassica rapa L.

A number of factors influencing microspore embryogenesis and plant regeneration were examined in five subspecies (rapa, oleifera, niposinica, perviridis, broccoletto) of B. rapa. Addition of 6-benzylaminopurine (BA) in 1/2 NLN-10 medium improved the embryo yield by 2?C12 fold. Addition of activated charcoal (AC) in the medium was not effective for microspore embryogenesis. Moreover, AC canceled the positive effect of BA, when the medium containing both BA and AC was used. Of 24 genotypes examined for microspore embryogenesis, 22 genotypes of all five subspecies produced embryos ranging from 0.02 to 15.0 per 2?×?10⁵ microspores, but two genotypes were not responsive. Low temperature pretreatment of flower buds significantly improved the microspore embryogenesis. When cotyledonary embryos were subcultured on a filter paper placed on top of 0.8?% agar-solidified B5-2 medium and 1.6?% agar B5-2 medium, plant regenerations were increased 4?C8 fold compared to 0.8?% agar medium. The ploidy levels of regenerated plants in three genotypes were determined by flow cytometry, revealing that 66?C100?% of them were diploid. The results enable the advancement of breeding programs and genetic studies in B. rapa.     

Significance of preprophase bands of microtubules in the induction of microspore embryogenesis of Brassica napus

Microspores of Brassica napus L. cv. Topas, undergo embryogenesis when cultured at 32.5 °C for the first 18–24 h and then at 25 °C. The first division in heat-treated microspores is a symmetric division in contrast to the asymmetric division found after the first pollen mitosis in-planta or in microspores cultured continuously at 25 °C. This asymmetric division is unique in higher plants as it results in daughter cells separated by a non-consolidated wall. The cytoskeleton has an important role in such morphological changes. We examined microtubule (MT) organization during the first 24 h of heat induction in the embryogenic B. napus cv. Topas and the non-embryogenic B. napus breeding line 0025. Preprophase bands (PPBs) of MTs appeared in cv. Topas microspores in late uninucleate microspores and in prophase figures after 4–8 h of heat treatment. However, more than 60% of the PPBs were not continuous bands. In contrast, PPBs were never observed in pollen mitosis; MT strands radiated from the surface of the nuclear envelope throughout microspore maturation to the end of prophase of pollen mitosis I, during in-planta development and in microspores cultured at 25 °C. Following 24 h of heat treatment, over 95% of the microspores appeared to have divided symmetrically as indicated by the similar size of the daughter nuclei, but only 7–16% of the microspores eventually formed embryos. Discontinuous walls were observed in more than 50% of the divisions and it is probable that the discontinuous PPBs gave rise to such wall abnormalities which may then obstruct embryo development. Preprophase bands were not formed in heat-treated microspores of the non-embryogenic line 0025 and the ensuing divisions showed discontinuous walls. It is concluded that the appearance of PPBs in heat-induced microspores marks sporophytic development and that continuous PPBs are required for cell wall consolidation and embryogenesis. It follows that induced structures with two equally condensed nuclei, do not necessarily denote symmetric divisions. Received: 22 October 1998 / Accepted: 28 November 1998     

Uptake and distribution of sinigrin in microspore derived embryos of Brassica napus L

In Brassica napus, glucosinolates are transported from all parts of the plant into the embryo during seed development. In this study we describe the uptake of the alkenyl glucosinolate sinigrin by microspore derived embryos from high and low glucosinolate genotypes. Microspore derived embryos develop completely isolated from maternal tissues unlike zygotic embryos, which contains glucosinolates transported into the embryo synthesised in the vegetative tissues. The sinigrin in the culture medium was almost completely absorbed by the embryos after three days of culture. The embryos of high and low glucosinolate genotypes were equally capable of absorbing sinigrin from the medium. A significant increase in different alkenyl glucosinolates following feeding of sinigrin suggests induction of biosynthetic enzymes in the embryos. Following excess feeding of sinigrin, we found a strong uptake against a concentration gradient and stable accumulation by the embryos. The glucosinolate was detected in single dissected cotyledons by a photometric test and by HPLC. This test could potentially be useful for screening mutants defective in glucosinolate uptake into the embryo.     

Hormones in zygotic and microspore embryos of Brassica napus

A number of studies have used microspore-derived embryos (MDEs) as amodel for examining a range of processes, including hormonal regulation ofembryo development. We examined the hormonal physiology of MDEs with theprimaryobjective of testing the validity of using the MDE system as a model forhormonally-regulated development in zygotic embryos, through late stages. To dothis we identified and quantified endogenous levels of abscisic acid (ABA),indole-3-acetic acid (IAA) and a number of gibberellins (GAs), includingGA₁₉, GA₂₀, GA₁ and GA₈ in bothMDEsand zygotic embryos. The presence of GA₁₉, together with itsC₁₉ metabolites indicates that the early-13 hydroxylation pathway isoperative in both embryo systems. Gibberellins A₄ and GA₉were also identified, thereby confirming the presence of the earlynon-hydroxylation pathway in B. napus MDEs and zygoticembryos. In general, the pattern of change of hormone (ABA, IAA, GA₁and GA₂₀) content per embryo through embryogenesis was similar forMDEs and zygotic embryos. Indole-3-acetic acid and GA₁ increased toamaximum at day 30 after culture (DAC) before decreasing. Abscisicacid levels increased to a maximum at day 35, and declined in zygoticembryos but not in MDEs. GA₂₀ increased to the final harvest atmaturity, or day 40. The absolute content (g/embryo) of each hormone, howeverwas appreciably lower (5- to 15- fold) in the MDEs. This was not the result ofdilution into surrounding medium for ABA or IAA; GA₁, however, didaccumulate in the medium. Although there were absolute quantitative differencesin the levels of IAA and ABA found in the two embryo systems, the similaritiesin the pattern of hormone changes suggests that the MDE system can serve as auseful model for examining the physiological roles of hormones duringembryogenesis.