Morphogenesis in Isolated Microspore Cultures of <Emphasis Type="Italic">Brassica juncea</Emphasis>

Androgenesis is a phenomenon in which microspores are made to bypass the sexual pathway and follow the sporophytic mode of development to generate new plants without the intervention of fertilization under specialized in vitro conditions. Microspore culture provides an ideal system, with a large, relatively uniform population of haploid cells, for use in mutant selection, genetic transformation and in studies on the molecular mechanism of induction of androgenesis and embryogenesis. This paper involves a study on establishing a reproducible and efficient protocol for microspore embryogenesis in various varieties of Brassica juncea. The genotype had a pronounced effect on androgenic response in microspore cultures. The cultivar Rajat exhibited the most response, producing around 3500 embryos/100 buds. The microspores of B. juncea cv. PR-45 from ed plants maintained at a day/night temperature of 10 °C/5 °C form embryos with suspensors with varied morphology. The microspore embryos germinated to produce plants with frequencies. These plants exhibited 52% survival and 74% fertility.     

Effect of various exogenous and endogenous factors on microspore embryogenesis in Indian mustard (<Emphasis Type="Italic">Brassica juncea</Emphasis> (L.) Czern and Coss)

Summary The influence of donor plant growth environment, microspore development stage, culture media and incubation conditions on microspore embryogenesis was studied in three Indian B. juncea varieties. The donor plants were grown under varying environments: field conditions, controlled conditions, or a combination of the two. The correlation analysis between the bud size and microspore development stage revealed that the bud size is an accurate marker for donor plants grown under controlled conditions, however, the same does not hold true for the field-grown plants. The buds containing late uninucleate microspores collected from plants grown under normal field conditions up to bolting stage and then transferred to controlled environment were observed to be most responsive with genotypic variability ranging from 10 to 35 embryos per Petri dish, irrespective of the other factors. NLN medium containing 13% sucrose was found to be most suitable for induction of embryogenesis The fortification of this medium with activated charcoal, polyvinylpyrrolidone, colchicine, or growth regulators (6-benzylaminopurine and 1-naphthaleneacetic acid) was observed to be antagonistic for microspore embryogenesis, while silver nitrate (10 μM) had a significant synergistic effect. A post-culture high-temperature incubation of microspores at 32.5±1°C for 10–15 d was found most suitable for high-frequency production of microspore embryos. The highest frequency of microspore embryogenesis (78 embryos per Petri dish) was observed from the late uninucleate microspores (contained in bud sizes 3.1–3.5 nm irrespective of genotype) cultured on NLN medium containing 13% sucrose and silver nitrate (10 μM), and incubated at 32.5°C for 10–15 d.     

Microspore embryogenesis of high sn-2 erucic acid Brassica oleracea germplasm

Brassica oleracea accessions possess traits that would be useful in commercial Brassica crops. These traits can be studied more effectively through the production of doubled haploid plants. Nineteen B. oleracea accessions from several subspecies possessing significant sn-2 erucic acid were screened for suitability for microspore culture using techniques well established for Brassica. Fifteen of the 19 accessions produced embryos. Genotypic differences were observed with embryogenesis ranging from 0 to 3000 embryos/100 buds. Embryogenesis was improved for two of four accessions by initiating cultures in NLN medium with 17% sucrose, then reducing sucrose to 10% after 48 h. An increase in embryogenesis for the same two accessions was observed when microspores were cultured at a density of 100 000/ml rather than 50 000 microspores/ml. A culture temperature of 32 °C for 48 h was beneficial for three of the four accessions when compared to a longer incubation period (72 h) or a higher temperature (35 °C). One accession line, Bo-1, was found to produce microspore-derived embryos which contained triacylglycerols with significant proportions of erucic acid at the sn-2 position. This revised version was published online in June 2006 with corrections to the Cover Date.     

Microspore culture in wheat (Triticum aestivum) – doubled haploid production via induced embryogenesis

The inherent potential to produce plants from microspores or immature pollen exists naturally in many plant species. Some genotypes in hexaploid wheat (Triticum aestivum L.) also exhibit the trait for androgenesis. Under most circumstances, however, an artificial manipulation, in the form of physical, physiological and/or chemical treatment, need to be employed to switch microspores from gametophytic development to a sporophytic pathway. Induced embryogenic microspores, characterized by unique morphological features, undergo organized cell divisions and differentiation that lead to a direct formation of embryoids. Embryoids `germinate' to give rise to haploid or doubled haploid plants. The switch from terminal differentiation of pollen grain formation to sporophytic development of embryoid production involves a treatment that halts gametogenesis and initiates sporogenesis showing predictable cellular and molecular events. In principle, the inductive treatments may act to release microspores from cell cycle control that ensures mature pollen formation hence overcome a developmental block to embryogenesis. Isolated microspore culture, genetic analyses, and studies of cellular and molecular mechanisms related to microspore embryogenesis have yielded useful information for both understanding androgenesis and improving the efficiency of doubled haploid production. The precise mechanisms for microspore embryogenesis, however, must await more research.     

Application of trifluralin to embryogenic microspore cultures to generate doubled haploid plants in Brassica napus

Microspore or anther culture has been used to produce desirable meiotic recombinants in numerous species. However, the utilization of these recombinants relies on inefficient genome doubling procedures to obtain fertile doubled haploid plants. This study presents a simple and rapid procedure to generate fertile doubled haploids in Brassica napus cv. Topas using trifluralin (α,α,α-trifluoro-2,6-dinitro-N,N-dipropyl- p -toluidine), a plant specific microtubule inhibitor. The effects of trifluralin on microtubule depolymerization and chromosome doubling in embryogenic microspore cultures of B. napus were examined and compared with those of colchicine. Indirect immunofluorescence labeling of isolated microspores indicated that microtubules were depolymerized within 30 min of trifluralin treatment and after 3–8 h of colchicine treatment. The direct application of these microtubule inhibitors to microspore cultures resulted in the recovery of fertile doubled haploid plants. Continuous culture in the presence of colchicine, was more effective than 18-h treatments for fertile plant production but resulted in abnormal embryo formation and recalcitrant plant regeneration. The application of 1 or 10 μ M trifluralin during the first 18 h of microspore culture was found to be the superior method for doubled haploid production. The embryos generated after trifluralin treatment developed normally, germinated readily and of the plants produced, close to 60% were fertile. The use of trifluralin to double chromosomes very early in microspore cultures is a simple process requiring minimal manipulation and should be very useful for genetic studies and breeding programs of B. napus and possibly other species.     

Expression of the BnmNAP subfamily of napin genes coincides with the induction of Brassica microspore embryogenesis

Brassica napus cv. Topas microspores can be diverted from pollen development toward haploid embryo formation in culture by subjecting them to a heat stress treatment. We show that this switch in developmental pathways is accompanied by the induction of high levels of napin seed storage protein gene expression. Changes in the plant growth or microspore culture conditions were not by themselves sufficient to induce napin gene expression. Specific members of the napin multigene family were cloned from a cDNA library prepared from microspores that had been induced to undergo embryogenesis. The majority of napin clones represented three members (BnmNAP2, BnmNAP3 and BnmNAP4) that, along with a previously isolated napin genomic clone (BngNAP1), constitute the highly conserved BnmNAP subfamily of napin genes. Both RNA gel blot analysis, using a subfamily-specific probe, and histochemical analysis of transgenic plants expressing a BngNAP1 promoter--glucuronidase gene fusion demonstrated that the BnmNAP subfamily is expressed in embryogenic microspores as well as during subsequent stages of microsporic embryo development.     

Isolated microspore culture techniques and recent progress for haploid and doubled haploid plant production

An isolated microspore culture provides an excellent system for the study of microspore induction and embryogenesis, provides a platform for an ever-increasing array of molecular studies, and can produce doubled haploid (DH) plants, which are used to accelerate plant-breeding programs. Moreover, isolated microspore cultures have several advantages over anther culture, wherein presence of the anther walls can lead to the development of diploid, somatic calli and plants. Although protocols for isolated microspore culture vary from laboratory to laboratory, the basic steps of growing donor plants, harvesting floral organs, isolating microspores, culturing and inducing microspores, regenerating embryos, and doubling the chromosomes, remain the same. Over the past few years, a large proportion of the research reports on isolated microspore culture have focused on cereal and Brassica species. For some of these species, isolated microspore culture protocols are well established and routinely used in laboratories around the world for developing new varieties, as well as for basic research in areas such as genomics, gene expression, and genetic mapping. Although these species are considered highly responsive to microspore culture, improvements in efficiency are still being made. However, with many species, isolated microspore culture is simply not yet efficient enough at producing DH plants to be cost-effective for breeding programs. There has been a recent resurgence of haploidy research with response being reported in some species once considered recalcitrant. Future research programs aimed at elucidating pathways involved in microspore induction and embryogenesis will be of benefit, as will novel approaches to improve the efficiency of microspore culture for DH production. With many species, anther culture has proven to be more effective than isolated microspore culture, necessitating more research to clarify the contribution of the anther wall to embryogenesis. The development of molecular markers for use in determining the gametic origin of regenerated plants, irrespective of their ploidy, would also be beneficial. In this review, we aim to provide an overview of the basic isolated microspore culture protocol with an emphasis on recent progress in several crop species.     

Haploids and doubled haploids in <Emphasis Type="Italic">Brassica</Emphasis> spp<Emphasis Type="Italic">.</Emphasis> for genetic and genomic research

The availability of a highly efficient and reliable microspore culture protocol for many Brassica species makes this system useful for studying basic and applied research questions. Microspores and microspore-derived embryos are ideal targets for modification by mutagenesis and transformation. Regenerated doubled haploid plants are widely used in breeding programs and in genetic studies. Furthermore, the Brassica microspore culture system allows the identification of genomic regions and genes involved in the microspore embryogenic response, spontaneous diploidization and direct embryo to plant conversion. This review summarizes current achievements and discusses future perspectives.     

Microspore culture of radish (Raphanus sativus L.): influence of genotype and culture conditions on embryogenesis

A number of factors influencing embryogenesis from isolated microspores of radish (Raphanus sativus) were examined. Of 11 genotypes evaluated, six produced embryos ranging from 8.3 embryos per 10⁵ microspores for Chugoku-ao to 0.2 for Tenshun, but five genotypes were not responsive. An initial culture period at elevated temperature before incubation at 25°C was essential for induction of microspore embryogenesis. However, the optimum period of the treatment varied among genotypes and/or experiments. Bud size also influenced microspore embryogenesis. Though optimum bud size was different between genotypes, the microspore populations represented in these buds contained uninucleate and binucleate microspores. Selection of embryogenic microspores using percoll density gradient resulted in up to 1.3-fold increase of embryo yield. Though almost all embryos failed to develop directly into plantlets, plants were obtained by multiple subcultures. The regenerated plants had hyperploid chromosome numbers.     

Direct gene delivery into isolated microspores of rapeseed (Brassica napus L.) and the production of fertile transgenic plants

A procedure for direct gene transfer into isolated microspores of rapeseed (Brassica napus L.) and the production of fertile transgenic plants is presented. By modifying the microspore culture method and adopting the firefly luciferase (Luc) gene as a non-destructive marker, we could obtain stably transformed androgenetic embryos from bombarded microspores. Luc-positive embryos were easily isolated from the large non-transformed population using a high-sensitivity bioluminescent image analyzer. PCR and Southern blot analyses confirmed that the introduced transgene was integrated stably into the genome of the selected embryos. Diploidized plants obtained from the haploid embryos were self-pollinated, and all of the offspring tested were Luc-positive, indicating rapid fixation of the transgene which is characteristic of doubled haploids. Received: 14 May 1997 / Revision received: 15 July 1997 / Accepted: 28 July 1997     

Embryogenesis and plant regeneration from isolated microspores of Brassica rapa L. ssp. Oleifera

Summary Conditions favourable to embryogenesis from isolated microspores of Brassica rapa L. ssp. oleifera (canola quality) were identified. A population with enhanced responsiveness for microspore embryogenesis (C200) was synthesized by crossing individual plants showing microspore embryogenic potential. For optimal microspore embryogenesis, buds (2–3mm in length, containing mid-late uninucieate microspores) were collected from older plants (2 months old) and microspores isolated and washed in iron-free B5 medium. NLN medium with its iron content reduced to half was beneficial for initial microspore culture. An elevated temperature(33–35°C) during the first day of culture, followed by maintenance at 25°C resulted in dozens of embryos from each isolation (about 100 buds). Seeds were obtained from plants regenerated from microsporederived embryos after colchicine treatment.     

Pro-embryos induction from <Emphasis Type="Italic">Olea europaea</Emphasis> L. isolated microspore culture

Studies were undertaken with one olive (Olea europaea L.) cultivar to identify buds with microspores competent to embryogenesis in vitro. Isolated microspore cultures were performed for the induction of gametic embryogenesis. Different pollen development stages and stress conditions (heat or cold shock) were evaluated. The correlation of inflorescence, anther morphology and the suitable stage of microspore development were analysed. The morphology of responsive buds was identified which corresponded with microspores from the late uni-nucleate to early bi-nucleate pollen stages. Symmetrical divisions of microspores as well as resulting multinucleate structures and pro-embryos were observed. In this paper, a new method of isolated microspore culture that leads to cell division and pro-embryos in olive, is reported.     

Stress-induced microspore embryogenesis in tobacco: an optimized system for molecular studies

Summary Specific stress treatments applied to isolated tobacco (Nicotiana tabacum L.) microspores efficiently induced haploid embryo formation in vitro. A heat shock at 33 or 37°C in the presence of sugar, as well as sucrose-starvation at 25°C, resulted in the formation of embryogenic microspores. A combination of both treatments had an additive effect. Under optimal induction conditions all viable microspores in the culture were embryogenic and developed subsequently into pollen embryos by culture at 25°C in a sugar-containing medium, with induction frequencies of more than 70% with respect to the initial microspore population. A high fraction of the early pollen embryos continued their development in vitro, giving rise to haploid plants. In contrast to other available systems for microspore/pollen embryogenesis, the new protocol allows the production of homogeneous populations of embryogenic microspores and early globular embryos in large-scale cultures, without any purification step, and is therefore well suited for biochemical and molecular work.Abbreviations EDTA ethylenediaminetetraacetate - DAPI 4,6-diamidino-2-phenylindole     

An overview of preliminary studies on the development of doubled haploid protocols for nutraceutical species

There is very little activity underway to improve the genetics of herbs, spices, and nutraceutical crops. Much of the industry relies on the harvest of “wild” plants; therefore, the potential for variability in performance and active ingredients is high. This presents significant challenges for an industry that is striving to achieve market credibility and meet current regulatory standards. Uniform varieties would also be beneficial for use in clinical trials. The development of plants performing consistently in cultivation under various environmental conditions and producing a stable quality and quantity of desired active ingredients cannot solely rely on traditional plant breeding, but must be supported by the development of tissue culture methods targeted to the species of interest. We have screened over 80 herb, spice, and nutraceutical species for microspore culture response using the Brassica napus microspore culture protocol. The majority of the species did not respond. Swelling and initial divisions of the microspores were observed in some species. Embryogenesis, however, was observed in the Apiaceae and the Caryophyllaceae. Species within these families were selected for further optimization. Improvements in embryogenic frequency were observed in both families. Haploid and doubled haploid plants have been regenerated in anise (Pimpinella anisum), carrot (Daucus carota), caraway (Carum carvi), dill (Anethum graveolens), fennel (Foeniculum vulgare), lovage (Levisticum officinale), laceflower (Amni majus), parsnip (Petroselinum crispum), and cow cockle (Saponaria vaccaria).     

Reflexions sur nos cultures d'antheres de plantes cultivées

Abstract

Considerations about our anther cultures of cultivated plants. – One of the main activities performed at the Casaccia Nuclear Centre, in the framework of a contract between CNEN and the European Communities, centers on the induction of haploid plants by anther culture and the subsequent chromosome doubling in order to obtain completely homozygous diploid plants. In tobacco, it is now possible to obtain haploid plants from any cultivar; we perform in vitro culture of internodes from which homozygous diploid plants are regenerated, taking advantage of natural phenomenon of endopolyploidy. In order to try to generalize this method of producing haploid plants in other plant species, we are studying the mechanism involved in haploid embryogenesis which occurs in vitro in the microspores. Datura, Nicotiana and Atropa are among the genera in which a direct embryogenesis from the microspore is observed; it is interesting to note that all three genera belong to the family Solanaceae and are very rich in alkaloids. In almost all the other cases of in vitro induction of haploids, microspores produce calli from which plantlets can be differentiated, but this way of plant regeneration is less interesting because only few plantlets are obtained and it is not sure that each haploid comes from a single microspore. We examined the factors which could influence the transformation of microspores into embryoids in tobacco, namely: the developmental stage of microspore, the degeneration of tapaetal cells, the genotype of microspore, the composition of cultural media, the physiological conditions of the plant from which the anthers were taken. From a practical point of view, it would be desirable to have informations on methods giving a maximum number of haploid plants from one embryogenic anther and the greatest number of embryogenic anthers from the cultured anthers. Our recent experiments on anther culture in liquid shaken medium have yielded good results (about 7,000 embryoids from 25 embryogenic anthers). Further, we are conducting several experiments in order to synchronize the development of the microspores in the anthers; to this end, we analyse the effect of cold treatment, ionizing radiation and gravity force. Experiments are being performed with other cultivated species, beside tobacco, in order to solve some problems of plant breeding more easily and quickly through haploidy. With the aim of introducing, in cultivated tomato, some desirable characters from the wild species, Lycopersicum peruvianum, (self-incompatibility, disease resistance, simultaneous flowering), we have obtained the interspecific hybrid through in vitro culture of young embryos. Haploid production from this hybrid could allow to quickly obtain various genetic recombinations from these two species. For this purpose we are carrying out anther cultures as well as single microspore cultures. In rice, strawberry and L. peruvianum, several diploid and tetraploid plantlets were obtained from our anther cultures. Work is in progress to ascertain the mode of their origin.     

Efficient production of doubled haploid plants by immediate colchicine treatment of isolated microspores in winter Brassica napus

The effect of colchicine on embryogenesis induction and chromosomedoubling during microspore culture was evaluated in two F₁ hybridsofwinter oilseed rape (Brassica napus L.). Colchicinetreatment (50 and 500 mg/L) of isolated microspores during thefirst 15 h in culture stimulated embryogenesis and produced large amounts ofhealthy-looking embryos. These normal embryos germinated well at 24°C after being transferred to solid regeneration medium and aninitial period of low temperature (2 °C) for 10 days, andcoulddirectly and rapidly regenerate vigorous plants. A high doubling efficiency of84–88% was obtained from 500 mg/L colchicine treatment for15h with low frequency of polyploid and chimeric plants. Acolchicinetreatment duration of 6 h was less effective on embryogenesis anddoubling efficiency. The present experiment also showed that changing of induction medium 15h after microspore isolation produced higher spontaneous doublingefficiency, as compared with medium change 6 h after isolation.     

Efficient embryogenesis and regeneration in freshly isolated and cultured wheat (Triticum aestivum L.) microspores without stress pretreatment

The major advantage of doubled haploids in plant breeding is the immediate achievement of complete homozygosity. Desired genotypes are thus fixed in one generation, reducing time and cost for cultivar or inbred development. Among the different technologies to produce doubled haploids, microspore embryogenesis is by far the most common. It usually requires reprogramming of microspores by stress such as cold, heat, and starvation, followed by embryo development under stress-free conditions. We report here the development of a simple and efficient isolated microspore culture system for producing doubled haploid wheat plants in a wide spectrum of genotypes, in which embryogenic microspores and embryos are formed without any apparent stress treatment. Microspores were isolated from fresh spikes in a nutrient-free medium by stirring and cultured in medium A2 in the dark at 25°C. Once embryogenic microspores were formed, ovaries and phytohormones were added directly to the cultures without changing the medium. The cultures were incubated in the dark at 25–27°C until the formation of embryos and then the embryos were transferred to regeneration medium. The regeneration frequency and percentage of green plants increased significantly using this protocol compared to the shed microspore culture method.Communicated by W. Harwood     

High frequency production of doubled haploid plants of Brassica napus cv. Topas derived from colchicine-induced microspore embryogenesis without heat shock

This report describes a very high genome doubling efficiency of Brassica napus cv. Topas plants, derived from microspores induced to undergo embryogenesis with a colchicine treatment, without the use of a heat treatment. The plants showed normal growth and development, and 90% were fertile. In contrast, only 6% of the plants derived from heat-induced embryos were fertile diploids. All cytological analysis of the progeny of fertile plants showed 2n=38 chromosomes. These results show that colchicine can simultaneously induce microspore embryogenesis and double the ploidy level to produce doubled haploid plants.     

Polyploidization in embryogenic microspore cultures ofBrassica napus L. cv. Topas enables the generation of doubled haploid clones by somatic embryogenesis

Summary Embryogenic microspore and pollen culture followed by subculture of microspore-derived plantlets enabled the production of clones ofBrassica napus cv. Topas. Flow-cytometric analysis revealed that most microspore- and pollen-derived embryos (pEMs) were haploid initially. Spontaneous diploidization occurred at the globular stage of the pEMs, and was expressed as the relative increase of the 2C and 4C nuclear DNA content. Diploidization occurred throughout various organs of the pEMs and resulted in the formation of haploid and doubled haploid chimerics. In some embryos, nearly all cells were doubled haploid. From early cotyledon stage onward, pure haploid embryos were not observed anymore. At late cotyledon and germination stages, pure doubled haploid embryos and plantlets increased in number. Tetraploid pEMs were found occasionally. A culture regime was established to induce somatic embryos on the pEM-derived young plantlets. The ploidy of the somatic embryos varied highly and tended to be the same as that of the tissue at the initiation site on the pEM-plant. The results show that during the embryogenic development ofB. napus microspores, spontaneous diploidization occurs at globular stage, and increases progressively, resulting in the formation of chimerical haploid and doubled haploid plants as well as pure doubled haploid plants; ploidy neither affects pEM development at embryo developmental stages nor somatic embryogenesis, that starts on young pEM-derived plantlets; doubled haploid somatic embryos can be cloned from single pEM-derived plantlets; and doubled haploid embryos develop to fertile plants.     

Isolated wheat microspore culture

The use of doubled haploid plants in a wheat breeding program requires an efficient haploid production system. While the techniques for producing doubled haploids from anther culture are well established, those for isolated microspores are complicated and inefficient. Four methods of isolating microspores from anthers (blending, stirring, macerating, and floating) were compared. Isolated microspores were washed and cultured in liquid medium. The effects of pre-isolation mannitol conditioning, cell density, culture dilution, and sucrose centrifugation on microspore viability were evaluated. Isolation by blending gave the highest initial microspore viability (75%). Mannitol conditioning and purification by sucrose centrifugation had a detrimental effect on initial viability. An initial microspore density of 2 × 10⁵ microspores per ml was necessary for continued microspore viability. One hundred and nine haploid or spontancously doubled haploid plants were regenerated from microspores isolated without mannitol conditioning using the blending method. Based on this research, blender isolation with an initial density of 2 × 10⁵ microspores per ml is recommended for isolated microspore culture.Abbreviations LSmean least square mean - MES 2-N-morpholinoethane sulfonic acid - 2,4-d 2,4-dichlorophenoxyacetic acid - NAA -naphtaleneacetic acid