Efficient production of doubled haploid plants through colchicine treatment of anther-derived maize callus

Summary A chromosome doubling technique, involving colchicine treatment of an embryogenic, haploid callus line of maize (Zea mays L., derived through anther culture), was evaluated. Two colchicine levels (0.025% and 0.05%) and three treatment durations (24, 48, and 72 h) were used and compared to untreated controls. Chromosome counts and seed recovery from regenerated plants were determined. No doubled haploid plants were regenerated from calli without colchicine treatment. After treatment with colchicine for 24 h, the callus tissue regenerated about 50% doubled haploid plants. All of the plants regenerated from the calli treated with colchicine for 72 h were doubled haploids, except for a few tetraploid plants. No significant difference in chromosome doubling was observed between the two colchicine levels. Most of the doubled haploid plants produced viable pollen and a total of 107 of 136 doubled haploid plants produced from 1 to 256 seeds. Less extensive studies with two other genotypes gave similar results. These results demonstrate that colchicine treatment of haploid callus tissue can be a very effective and relatively easy method of obtaining a high frequency of doubled haploid plants through anther culture.     

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.     

Pollen dimorphism in relation to pollen plant formation

Induction of haploid plants from pollen grains on culture of anthers has been possible in a number of angiosperms but it is not yet understood why only a fraction of pollen responds to form haploids. Noteworthy in this connection are the recent experiments on anther culture of barley, tobacco and wheat, where it has been pointed out that pollen populations are basically dimorphic. Pollen capable of forming haploids occur in a low frequency, arc smaller, and different from the majority of pollen destined to form gametes. Particularly in tobacco it has been possible to increase the frequency of pollen capable of forming embryos by subjecting plants to low temperature prior to flowering, and to achieve differentiation of embryogenic pollen by subjecting young buds from such plants to a prolonged cold treatment. On selective isolation, from the rest of the pollen, the embryogenic pollen from such buds readily form embryos at high frequency on a simple mineral-sucrose medium. The embryogenic pollen are repressed for gametophytic differentiation and in culture they differentiate to produce embryos. These experiments provide evidence that only certain pollen are capable of forming haploids.     

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     

Ontogenetic events in androgenesis of Brazilian barley genotypes

This paper describes a simple procedure for obtention of barley (Hordeum vulgare L.) doubled haploid plants from Brazilian hybrid genotypes. Anatomical and histological examinations showed the reversion of barley pollen to an sporophytic mode of development. A sequence of mitosis led to the formation of multicellular pollen grains. Regeneration of plants occurred either by direct embryogenesis or callus formation followed by differentiation through direct embryogenesis or organogenesis. Plants were formed in the same medium used for induction dispensing an additional regeneration step. This procedure makes doubled haploid production simpler and faster. Plantlets were transferred to another medium for rooting and after that planted in pots with vermiculite and nutrient solution.     

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.     

植物花粉培养研究进展

花粉培养又称为游离小孢子培养,指将发育到一定阶段的花粉从花药中游离出来成为分散或游离状态,通过培养使花粉粒脱分化,进而发育成完整植株的过程。花粉培养的主要目的是获得单倍体植株,进而得到双单倍体(double haploid,DH)植株,最终获得纯合系物种。本文对花粉培养形成植株的物种信息进行了收集整理,概述了国内外花粉培养的一些最新研究进展,包括影响花粉培养形成胚的因素以及提高花粉胚产量的措施,并对花粉培养的前景进行了展望。     

植物花粉培养研究进展

花粉培养又称为游离小孢子培养,指将发育到一定阶段的花粉从花药中游离出来成为分散或游离状态,通过培养使花粉粒脱分化,进而发育成完整植株的过程。花粉培养的主要目的是获得单倍体植株,进而得到双单倍体(double haploid,DH)植株,最终获得纯合系物种。本文对花粉培养形成植株的物种信息进行了收集整理,概述了国内外花粉培养的一些最新研究进展,包括影响花粉培养形成胚的因素以及提高花粉胚产量的措施,并对花粉培养的前景进行了展望。     

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     

Doubled haploid callus lines of Valencia sweet orange recovered from anther culture

Homozygous genotypes are valuable for genetic and genomic studies in higher plants. However, obtaining homozygous perennial plants using conventional breeding techniques is currently a challenge because of a long juvenile period, high heterozygosity and the substantial inbreeding depression. In vitro androgenesis has been used to develop haploid and doubled haploid plants. In this study, we report the regeneration of doubled haploid lines of Valencia sweet orange cv. Rohde Red (Citrus sinensis [L.] Osbeck) via anther culture. Anthers at the uninucleate stage were induced and two embryogenic calli were obtained that further regenerated to embryoids (2/400). Plantlets were obtained after transferring the embryoids to a shoot regeneration medium, but were short-lived. Ploidy analysis via both flow cytometry and chromosome counting verified that these two lines were diploids. Additionally, 43 simple sequence repeat (SSR) markers which showed to be heterozygous in the Valencia sweet orange donor line confirmed homozygosity and doubled haploids in the anther-derived lines. Furthermore, analysis of the doubled haploids via cleaved amplified polymorphic sequence (CAPS) markers and target region sequencing confirmed the allelic state of two genes (LCYE and LCYB) involved in the carotenoid biosynthesis of sweet oranges.     

Differentiation of embryogenic pollen in cold-treated buds ofNicotiana tabacum var. Badischer burley and nutritional requirements of the isolated pollen to form embryos

Summary Embryogenic pollen were selectively isolated from buds after cold treatment at 10 °C for 10 days; it was immaterial whether the buds were taken from short day and low temperature (SD and LT; 8 hours light, 18 °C) or long day and high temperature (LD and HT; 16 hours light, 24 °C) plants. However, in buds from SD and LT plants the differentiation of embryogenic pollen could be detected as early as 7 days after the cold treatment, and pollen from these plants formed embryos at higher frequency (up to 4% of cultured pollen) than those from LD and HT plants (up to 1% only).The embryogenic pollen, in isolated buds, differentiated by way of pollen dimorphism. During cold treatment a fraction of pollen remained small, retained clear cytoplasm and was capable of embryogenesis in comparison to gametophytic pollen which enlarged and acquired granular cytoplasm. In our experiments cold treatment was a key factor in the induction of pollen dimorphism. This aspect of cold treatment in pollen embryogenesis is reported for the first time and was possible on the basis of selection of embryogenic pollen by density gradient centrifugation. The ratio of embryogenic pollen was about one fifth of the total population.The nutritional requirements of isolated pollen for embryogenesis were rather simple. These pollen formed embryos which readily developed into plantlets on a mineral medium supplemented with sucrose provided the pH was 6.8.     

An improved system to establish highly embryogenic haploid cell and protoplast cultures from pollen calluses of maize (Zea mays L.)

Regenerable, embryogenic haploid cell suspensions were initiated and established from type II pollen calluses of two selected Chinese maize genotypes (No 592 Y and 592.A2 LY). The induction frequency of friable, embryogenic callus (type II) was highly dependent on three factors: genotype, medium, cold pretreatment, and on their interactions. Repeated callus and cell selection during the culture procedure led to stable haploid suspensions consisting of fine clusters each containing 20–50 cells. The selected cell lines were able to maintain their morphogenic ability during long-term subculture (2 years). Protoplasts were successfully isolated from subcultured, friable, embryogenic pollen calluses and cultured on N₆BM and N₆K media using a feeder layer, obtained from 2-day-old suspension culture. Healthy plants were regenerated from protoplast-derived calluses.     

Combination of reversible male sterility and doubled haploid production by targeted inactivation of cytoplasmic glutamine synthetase in developing anthers and pollen

Reversible male sterility and doubled haploid plant production are two valuable technologies in F₁-hybrid breeding. F₁-hybrids combine uniformity with high yield and improved agronomic traits, and provide self-acting intellectual property protection. We have developed an F₁-hybrid seed technology based on the metabolic engineering of glutamine in developing tobacco anthers and pollen. Cytosolic glutamine synthetase (GS1) was inactivated in tobacco by introducing mutated tobacco GS genes fused to the tapetum-specific TA29 and microspore-specific NTM19 promoters. Pollen in primary transformants aborted close to the first pollen mitosis, resulting in male sterility. A non-segregating population of homozygous doubled haploid male-sterile plants was generated through microspore embryogenesis. Fertility restoration was achieved by spraying plants with glutamine, or by pollination with pollen matured in vitro in glutamine-containing medium. The combination of reversible male sterility with doubled haploid production results in an innovative environmentally friendly breeding technology. Tapetum-mediated sporophytic male sterility is of use in foliage crops, whereas microspore-specific gametophytic male sterility can be applied to any field crop. Both types of sterility preclude the release of transgenic pollen into the environment.     

Entwicklung von Embryonen und embryogenem Kallus aus Pollenkörnern vonDatura meteloides undDatura innoxia

Zusammenfassung Die Entwicklung von Pflanzen aus Pollenkörnern in Antherenkulturen vonDatura meteloides undDatura innoxia kann auf verschiedenen Wegen erfolgen, die sich schon hinsichtlich der ersten Zellteilungen im Pollen voneinander unterscheiden. Während Mitosen ohne Streckungswachstum in direkter Folge zur Bildung von Einzelembryonen führen, entstehen durch Zellteilungen in Kombination mit stärkerem Streckungswachstum Verbände aus Kalluszellen, an denen sich früher oder später zum Teil sehr zahlreiche Adventivembryonen entwickeln. Eine weitere Möglichkeit zur Bildung von embryogenem Kallus besteht darin, daß durch Platzen der Pollenwand teilweise oder ganz voneinander isolierte dickwandige Zellen freigesetzt werden.Aus einzelnen Pollen-Embryonen herangewachsene Pflanzen vonDatura meteloides sind stets haploid, wohingegen aus embryogenem Pollen-Kallus hervorgegangene Individuen unterschiedliche Ploidiestufen von haploid bis triploid aufweisen. Der im Verlauf des Kalluswachstums eintretende Verlust der Haploidie beruht vermutlich auf endomitotischer Chromosomenverdopplung und gelegentlichen Kernfusionen.

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Development of embryos and embryogenic callus from pollen grains ofDatura meteloides andDatura innoxia

Summary Development of pollen plants in anther cultures ofDatura meteloides andDatura innoxia occurs either from single embryos, formed directly by pollen grains, or from embryogenic pollen callus. Histological observations revealed the presence of different modes of cell division in pollen grains undergoing andromorphogenesis. Divisions in the absence of cell enlargement lead to the formation of multicellular pollen grains, in which cells become progressively smaller. Cell aggregates formed in this manner will develop into single embryos when liberated from the exine. On the other hand, when divisions in pollen grains are associated with cell enlargement, aggregates of parenchymatous callus cells will emerge from the ruptured pollen wall. Less commonly callus is produced after spreading a number of partially or totally isolated thick walled cells out of the bursting exine.The development of embryos from both, pollen grains and cells of pollen callus, in many respects resembles to embryo formation in callus cultures of somatic tissues, especially when starting from isolated callus cells. The occurence of a spectrum of intermediate morphological shapes between single pollen embryos and embryogenic pollen callus provides some additional information for the discussion of questions concerning the suspensor problem and the induction of polarity.Chromosome counts in squashed root tips of pollen plants ofDatura meteloides proved plants, which arose from single embryos, to be haploid, whereas plants regenerated from pollen callus are of different ploidy levels ranging from haploid to triploid. Cytological observations confirmed the presence of a mixture of various ploidy and some multinucleated cells in pollen callus. It is presumed, that chromosome multiplication in callus cells may arise from endomitotic doubling and occasional nuclear fusions.

     

Production of doubled haploids in durum wheat (Triticum turgidum L.) through isolated microspore culture

The objective of this work was to produce doubled haploid plants from durum wheat through the induction of androgenesis. A microspore culture technique was developed and used to produce fertile doubled haploid plants of agronomic interest. Five cultivars, one selected line, plus a collection of 20 F₁ crosses between different genotypes of high breeding value were used. Studies on several factors such as pre-treatments and media components were carried out in order to develop a protocol to regenerate green haploid plantlets. Anthers were pre-treated in 0.7 M mannitol. Microspores, from anther maceration, were plated on a C₁₇ induction culture medium with ovary co-culture. The optimum regeneration medium J25–8 was used. From 35 microspore isolations, 407 green plantlets were obtained. With this technique mature embryos were obtained. Green plants were regenerated from all genotypes used and approximately 67% of them were spontaneously doubled haploids. Some haploids and a very few polyploids plants were obtained. From the 407 plants, 275 were completely fertile and gave enough seeds to be assayed in the field. This protocol could be used complementary to or instead of the intergeneric crossing with maize as an economically feasible method to obtain doubled haploids from most durum wheat genotypes.     

Isolated microspore culture of oat (Avena sativa L.) for the production of doubled haploids: effect of pre-culture and post-culture conditions

The production of doubled haploid (DH) plants from microspores is an important technique used in plant breeding programs and basic research. Although doubled haploidy efficiencies in wheat and barley are sufficient for breeding purposes, oat (Avena sativa L.) is considered recalcitrant. The objective of this project was to develop a protocol for the production of microspore-derived embryos of oat and further develop these embryos into fertile DH plants. A number of experiments were conducted evaluating the factors influencing microspore embryogenesis, i.e. donor plant conditions, pretreatments, media composition, and culture conditions. The initial studies yielded little response, and it was not until high microspore densities (10⁶ microspores/mL and greater) were used that embryogenesis was achieved. Depending on the treatment, yields of over 5,000 embryos/10⁶ microspores were obtained for breeding line 2000QiON43. The doubled haploidy protocol includes: a 0.3 M mannitol pretreatment of the tillers for 7 days, culture in W14 basal medium with a pH of 6.5–7.5, a microspore density of 10⁶ microspores/mL, and continuous incubation at 28 °C incubation. The resulting embryos observed after 28 days were plated onto solidified W14 medium with 0.8 or 1.0 g/L activated charcoal. A colchicine treatment of 0.2 % colchicine for 4 h resulted in conversion of 80 % of the plants from haploid to DH. This protocol was successful for the production of oat microspore-derived embryos and DH green plants with minimal albinism. DH seed was produced and planted for evaluation in a field nursery.     

In vitro differentiation of embryogenic pollen,control by cold treatment and embryo formation inab initio pollen cultures ofNicotiana tabacum var. badischer burley

Summary InNicotiana cold treatment causes differentiation of embryogenic pollen. This differentiation initiates on the plant and is completed in culture. Differentiation on the plant results in pollen dimorphism and differentiation in culture leads to pollen embryogenesis. An increased number of pollen capable of embryogenesis is possible on plants induced to flower in short days and low temperature (8 hours light, 18 °C). These embryogenic pollen on selective isolation, from buds at a petal length of 3.4±0.1 cm, fail to form embryos but do so in the cultures which receive cold treatment at 10 °C for 10 days. To some extent the differentiation of embryogenic pollen can be completed on plants induced to flower at 15 °C and embryogenic pollen from such plants form embryos at a low frequency which can be substantially increased on giving the cultures a cold treatment. The frequency of embryogenesis is higher in cultures of 15 °C plants than those of 18 °C plants. Low temperature requirements at two stages—to the plant and to the culture—are essential and complimentary for embryogenesis inab initio pollen cultures.Cold treatment causes repression of gametophytic differentiation and this results in the differentiation of embryogenic potential. The embryogenic pollen, unlike gametophytic pollen, are not fully differentiated structures. They are unable to divide and form embryos in presence of metabolic inhibitors such as actinomycin-D and cycloheximide.     

First stages of microspore reprogramming to embryogenesis through anther culture in Prunus armeniaca L.

Prunus armeniaca L. is a worldwide known species, very important particularly in the Mediterranean basin. Microspore embryogenesis through in vitro anther culture is a widely used method to obtain haploid and doubled haploid (DHs) plants which are being routinely used in breeding programmes for new superior cultivar development in many crops. Haploid-diploidization through gametic embryogenesis allows single-step development of complete homozygous lines from heterozygous parents. In the case of fruit crops, with long reproductive cycle, a high degree of heterozygosity, large size, and, often, self-incompatibility, there is no way to obtain haploidization through conventional methods. Induction of microspore embryogenesis in vitro is switched by a stress treatment. In many species, heat or cold stress has been reported to trigger pollen embryogenesis, the response being genotype dependent. In the present work we analyzed whether microspore reprogramming could be induced in apricot cultivars by cold stress through anther culture. We report the development of an in vitro anther culture protocol in P. armeniaca L. and analyse the response of several cultivars to stress treatments and culture media for inducing pollen embryogenesis. Results showed the formation of multicellular pollen and proembryos. The effect of two culture media in the embryogenic response was also analyzed, being the responses genotype-dependent. Monitoring of the cellular changes on the microspores was performed by structural and confocal microscopy analyses. Results indicated that the reprogramming of the microspore and the first steps of the embryogenic pathway have been achieved in different varieties of P. armeniaca, which constitutes a crucial step in the design of protocols for the regeneration of microspore-derived embryos and DH plants, for future potential applications in breeding programmes of this economically important fruit tree.     

The elimination of a selectable marker gene in the doubled haploid progeny of co-transformed barley plants

Following the production of transgenic plants, the selectable marker gene(s) used in the process are redundant, and their retention may be undesirable. They can be removed by exploiting segregation among the progeny of co-transformants carrying both the selectable marker gene and the effector transgene. Here we show that the doubled haploid technology widely used in conventional barley breeding programmes represents a useful means of fixing a transgene, while simultaneously removing the unwanted selectable marker gene. Primary barley co-transformants involving hpt::gfp (the selectable marker) and gus (a model transgene of interest) were produced via Agrobacterium-mediated gene transfer to immature embryos using two respective T-DNAs. These plants were then subjected to embryogenic pollen culture to separate independently integrated transgenes in doubled haploid progeny. A comparison between 14 combinations, involving two Agrobacterium strains carrying various plasmids, revealed that the highest rate of independent co-transformation was achieved when a single Agrobacterium clone carried two binary vectors. Using this principle along with Agrobacterium strain LBA4404, selectable marker-free, gus homozygous lines were eventually obtained from 1.5 per 100 immature embryos inoculated. Compared to the segregation of uncoupled T-DNAs in conventionally produced progeny, the incorporation of haploid technology improves the time and resource efficiency of producing true-breeding, selectable marker-free transgenic barley.     

Production of haploid and doubled haploid plants of melon (<Emphasis Type="Italic">Cucumis melo</Emphasis> L.) for use in breeding for multiple virus resistance

We have developed improved procedures for recovery of haploid and doubled haploid (DH) melon plants, using hybrids derived from crosses of lines with multiple virus resistance. Seeds formed after pollination with irradiated pollen were cultured in liquid medium for 10 days before excision of the embryos for further culture. This made it easier to identify the seeds containing parthenogenetic embryos, thereby reducing the effort required and increasing the percentage of plants recovered. The plants obtained (approximately 175) were transferred to a greenhouse for evaluation. Three fertile lines were identified, and selfed seeds were obtained for evaluating virus resistance. Flow cytometry of leaf tissues showed that two of these lines were spontaneous DH and the third was a mixoploid containing haploid and diploid cells. The other plants remained sterile through the flowering stage. Flow cytometry of 20 sterile plants showed that all were haploid. Attempts to induce chromosome doubling by applying colchicine to greenhouse-grown plants were unsuccessful. Shoot tips from the haploid plants were used to establish new in vitro cultures. In vitro treatment of 167 micropropagated haploid shoots with colchicine produced 10 diploid plants as well as 100 mixoploid plants. Pollen from male flowers that formed in vitro on the colchicine-treated plants was examined. High percentages of viable pollen that stained with acetocarmine were found not only in the diploids but also in >60% of the plants scored as mixoploid or haploid by flow cytometry. Efficient recovery of DH from hybrid melon lines carrying combinations of important horticultural traits will be a valuable tool for melon breeders.