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.     

Activated charcoal induced high frequency microspore embryogenesis and efficient doubled haploid production in Brassica juncea

Three Indian Brassica juncea cultivars were studied for embryogenic response of microspores, microspore embryo regeneration, ploidy assessment of microspore-derived plants and their diploidization. Genotype dependence for microspore totipotency was observed and a significant effect of genotype by bud size selection was established. The addition of activated charcoal in NLN medium containing 13% (w/v) sucrose and 10 μM silver nitrate resulted in a fourfold increase in microspore embryogenesis, ranging from 100 to 405 embryos per Petri dish corresponding to 2,700–10,935 embryos per 100 buds. Conversion/germination of embryos produced in presence or absence of activated charcoal was similar but air-drying of microspore embryos was essential. Incubation of microspore embryos at 4 ± 1°C for 10 days in dark resulted in 82.3% conversion. The majority of plants produced from these embryos was haploid. Treating microspore-derived plants at the 3–4 leaf growth stage with 0.34% colchicine for 2–3 h resulted in greatest survival (70%) and chromosome doubling (75%) frequencies. Doubled haploid plants were self-pollinated and grown to maturity under field conditions.     

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.     

Induction conditions for somatic and microspore-derived structures and detection of haploid status by isozyme analysis in anther culture of caraway (Carum carvi L.)

Plant regeneration was obtained from cultured anthers and hypocotyl segments of caraway (Carum carvi L.). Microspore- and somatic tissue-derived embryos were compared by observation of the regeneration process under identical induction conditions. Fluorescent microscopy with DAPI staining showed initiation of cell divisions and formation of embryogenic callus and somatic embryos from anther sacs, with production of embryos of both microspore and somatic origin. Induction of somatic embryos from hypocotyl-derived callus was also demonstrated. Isozyme native polyacrylamide gel electrophoresis was used to identify haploids and doubled haploids, and to determine the frequency of spontaneous diploidization of regenerated plants of microspore origin. Donor plants (2n = 20) and their anther-derived derivative plants (n = 10, 2n = 20, 4n = 40) in callus stage or leafy rosette stage were compared. The esterase (EST) band patterns of regenerated plants differed from the heterozygous parental material, suggesting that the regenerated plants were microspore-derived haploid/doubled haploid plants. The similar profile of EST bands between the diploid anther-derived plants and a sample of the donor plants corresponded to a somatic regeneration pathway. Although the selected induction conditions revealed no preference for induction of microspore embryogenesis, the anther culture protocol established for caraway utilizing isozyme segregating EST loci markers is suitable for DH production.     

Production of doubled haploid rice plants (Oryza sativa L.) by anther culture

The results of anther culture of F₂ pollen issued from 23 single crosses are presented. A relation between the morphology of the panicle and the microspore stage was established. After cold-pretreatment (8 days at 4°C), the anthers were cultured on the callus-induction medium N6 supplemented with 1 mg l^–1 naphthaleneacetic acid. The calli were transferred to MS plant regeneration medium supplemented with 3 mg l^–1 kinetin + 0.5 mg l^–1 naphthaleneacetic acid. The induction frequency varied from 0.22% to 29% and the regeneration frequency from 0% to 144.4%, dependent upon the crosses used. On average, 27% of the plants obtained were albinos and 59% of the green plants underwent spontaneous chromosome doubling. Thirtynine doubled haploid lines were evaluated and multiplied in the field. Lines with an excellent behaviour in upland culture conditions were selected from two crosses.     

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.     

Twinned microspore-derived embryos of canola (<Emphasis Type="Italic">Brassica napus</Emphasis> L.) are genetically identical

Microspore culture is used extensively in several crop species to generate diverse populations of homozygous, doubled haploid lines for breeding and genetic analyses. In our canola (Brassica napus L.) doubled haploid breeding programme we regularly observe conjoined microspore-derived embryos, most commonly twins, joined either at the base of the hypocotyl or along the length of the hypocotyl axis. The aim of this study was to determine if twinned embryos were genetically identical or non-identical in order to gauge their value for breeding and linkage analysis. Microsatellite marker fingerprinting of 12 pairs of twinned embryos produced by microspore culture of heterozygous F₁ lines revealed that pairs of twins were genetically identical. Based on this finding, we recommend breeders and geneticists using microspore culture technology to retain only one embryo from each pair of twinned embryos.     

Doubled haploid production via anther culture in annual,winter type of caraway (<Emphasis Type="Italic">Carum carvi</Emphasis> L.)

Caraway (Carum carvi L.) is a traditional medicinal and spice cross-pollinated plant species. Although in vitro techniques are recently extensively applied in plant breeding programmes, these are not commonly utilized in caraway. Therefore, based on the protocol for anther culture in carrot (Daucus carota L., a closely related species of caraway in Daucaceae family), in vitro androgenesis in caraway has been studied with the aim to produce completely homozygous inbred lines. Various induction conditions, such as temperature pretreatments, carbon sources and combination of growth regulators in a culture medium as well as the effect of genotype on in vitro androgenesis were examined. Ten breeding lines of winter caraway representing third generation of forced (artificial) self-pollination were used as donor plant material. Cultured anthers produced embryogenic calli, and subsequently two types of regenerated plants were obtained, namely haploids with evident microspore origin, and diploids which may represent somatic (anther wall) regenerants or spontaneous doubled haploids. The ploidy status of regenerated plants was determined by flow cytometry. This is the first report on androgenic doubled haploid production in caraway.     

Stable haploid poplar callus lines from immature pollen culture

Embryogenesis and plant regeneration have been obtained from isolated immature pollen of two poplar hybrids ( Populus nigra L. × hybrid 'Aue1' and 'Aue2'). In total, 1487 calli or embryos, respectively, larger than 1 mm were generated in a 2-year study. By using a cytokinin containing induction medium, on average 19 calli per responsive immature catkin were formed. Additional supplementation with auxin in 2002 increased the frequency to 72 calli per catkin. Microsatellite marker analyses confirmed haploid origin in most regenerants studied. So far six out of eight obtained regenerative callus lines have maintained their haploid level up to 24 months of development. A number of haploid and doubled haploid plants of different lines are available and have been transferred to soil.     

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.     

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.     

A milestone in the doubled haploid pathway of cassava

This study was aimed at inducing androgenesis in cultured anthers of cassava (Manihot esculenta Crantz) to develop a protocol for the production of doubled haploids. Microspore reprogramming was induced in cassava by cold or heat stress of anthers. Since the anthers contain both haploid microspores and diploid somatic cells, it was essential to verify the origin of anther-derived calli. The origin of anther-derived calli was assessed by morphological screening followed by histological analysis and flow cytometry (FCM). Additionally, simple sequence repeat (SSR) and amplified fragmented length polymorphism (AFLP) assays were used for the molecular identification of the microspore-derived calli. The study clearly demonstrated the feasibility of producing microspore-derived calli using heat- or cold-pretreated anthers. Histological studies revealed reprogramming of the developmental pathway of microspores by symmetrical division of the nucleus. Flow cytometry analysis revealed different ploidy level cell types including haploids, which confirmed their origin from the microspores. The SSR and AFLP marker assays independently confirmed the histological and FCM results of a haploid origin of the calli at the DNA level. The presence of multicellular microspores in the in vitro system indicated a switch of developmental program, which constitutes a crucial step in the design of protocols for the regeneration of microspore-derived embryos and plants. This is the first detailed report of calli, embryos, and abnormal shoots originated from the haploid cells in cassava, leading to the development of a protocol for the production of doubled haploid plants in cassava.     

Genetic manipulation of microspores and microspore-derived embryos

Summary Recent advances in plant cell and molecular biology have furthered the genetic manipulation of many plant species and advanced the options for crop improvement. Among the many targets for genetic manipulation, microspores offer several unique advantages: they are haploid, single-celled, and highly synchronized. In many plant species microspores develop into haploid embryos, and eventually haploid and doubled haploid plants, after in vitro anther or microspore culture. This induced in vitro developmental pathway of microspores, termed microspore embryogenesis, can be used to recover individual homozygous plants from microspores and microspore-derived embryos after genetic manipulation such as mutagenesis and gene transfer. The highly efficient microspore embryogenesis system inBrassica napus has been used successfully to obtain various mutants after microspore mutagenesis, and to achieve gene transfer mediated byAgrobacterium tumefaciens. Presented in the Session-in-Depth In Vitro Gametophyte Biology at the 1991 World Congress on Cell and Tissue Culture held in Anaheim, California, June 16–20, 1991.     

Evaluation of Brassica rapa L. genotypes for microspore culture response and identification of a highly embryogenic line

Isolated microspore culture techniques are being widely used in Brassica breeding programs to generate haploid and doubled haploid plants. A number of factors influence regeneration response in vitro including genotype. In order to assess the effect of genotype on microspore embryogenesis in B. rapa L. var. oleifera, 17 cultivars and breeding lines were evaluated. Embryos developed from all but one genotype when using NLN medium with 17% sucrose, followed by a reduction in sucrose concentration to 10%, 48 h later. The number of embryos /100 buds differed between genotypes, ranging from 0 to 70. Further studies indicated that sucrose concentration and incubation time influenced embryogenesis. Selection studies carried out with an Agriculture and Agri-Food Canada breeding line have resulted in the identification of a highly embryogenic B. rapa line. This line produced thousands of microspore-derived embryos /100 buds and will be useful in mutant selection and gene transfer as well as biochemical and developmental studies.     

Somatic embryogenesis and plant regeneration in Triticum aestivum x Leymus angustus F1 hybrids and the parental lines

Somatic embryos and plants were produced from cultured inflorescence and leaf segments of Triticum aestivum X Leymus anaustus F₁ hybrids and the parental lines. Inflorescences showed a better capacity for somatic embryogenesis and plant regeneration than leaves. Leymus anaustus produced the highest number of embryogenic calli, while the hybrids were intermediate between this species and Triticum aestivum. Presence of 2,4-D was shown to be essential for induction and maintenance of somatic embryogenesis. Addition of five amino acids (glutamine, proline, asparagine, aspartic acid and glutamic acid) did not have any marked effect when they were used in the callus induction medium. The regenerated plants had the same morphology as the original plants. No cytological modification was observed in the examined plants.     

Influence of anther pretreatment and culture medium composition on the production of barley doubled haploids from model and low responding cultivars

Different pretreatments were given to anthers of barley before culturing, and their effects assessed on the frequency of embryos and green doubled haploid plants produced. Mannitol pretreatment was better than cold pretreatment for some low responding cultivars. Optimal concentration of mannitol for pretreatment depended on cultivar. Low responding genotypes needed a higher concentration of mannitol than responsive ones. The addition of Ficoll to liquid medium increased the number of embryos and green plants. The influence of the growth regulators 2,4-D and TIBA was assayed using ten cultivars of barley grown in Spain. The anti-auxin TIBA gave good embryo production with some of the low responding cultivars. Two row-type cultivars always produced higher number of embryos and green plantlets than six row-type. The application of these modifications to 10 F₁ hybrids with potential agronomic value, allowed the production of almost 1000 doubled haploid plants from only 3500 anthers. Up to two doubled haploid plants per flower were produced from the cross Monlon × Sonja. This revised version was published online in June 2006 with corrections to the Cover Date.     

PCIB an Antiauxin Enhances Microspore Embryogenesis in Microspore Culture of Brassica juncea

An efficient protocol to improve microspore embryogenesis is established in an important oleiferous crop, Brassica juncea (Indian mustard). Colchicine was used for enhancing microspore embryogenesis and also to obtain doubled haploid embryos. Colchicine at high concentrations (>10 mg l⁻¹), for 24 h, proved convenient for direct recovery of diploid embryos. Higher temperature treatment and an antiauxin PCIB (p-chlorophenoxyisobutyric acid) enhanced microspore embryogenesis significantly as compared to colchicine. An increase in temperature from 32°C to 35°C proved very efficient in increasing embryogenesis by 10-fold. The highest embryogenesis rate was obtained when PCIB was added at 35°C in the culture after 1 day of culture initiation. 20 μM PCIB could enhance microspore embryogenesis by 5-fold. Different abnormal shapes of embryos like lemon, banana, flask and fused cotyledons were observed. Both normal and fused cotyledonous embryos showed normal germination when transferred on the B₅ basal medium.     

Non-ionic surfactants improved microspore embryogenesis and plant regeneration of recalcitrant purple flowering stalk (Brassica campestris ssp. chinensis var. purpurea Bailey)

As Brassicaceae species are mostly cross-pollinated, breeding homozygous parental lines by traditional approaches is time-consuming and costly. Alternatively, microspore culture has been widely applied to produce double haploid lines in a short time. This study aimed to establish a highly efficient microspore culture protocol for purple flowering stalk. Among the five genotypes studied, the highest and lowest embryo induction rates were observed in J18 and J17 (13.5 and 7.67 embryos per bud, respectively). Microspores of genotypes J17 and J18 were successfully induced to produce embryos in NLN-13 medium, but the frequency of microspore embryogenesis was low. Three non-ionic surfactants (Pluronic F-68, Triton X-100, Tween-20) were evaluated independently for their effect on microspore embryogenesis of purple flowering stalk. Microspores of the two genotypes were cultivated in NLN-13 medium supplemented with different concentrations (0.0001%, 0.001%, 0.01%, 0.1%, 0.5%, and 1% (w/v)) of the three non-ionic surfactants to enhance microspore embryogenesis and plant regeneration. In both genotypes, supplementation with any of the three non-ionic surfactants at 0.0001% significantly increased the frequency of microspore embryogenesis; furthermore, at that concentration, Tween-20 significantly increased the number of plants regenerated from induced embryoids by 29.9% and 30% in J17 and J18, respectively. Moreover, the rate of double haploid formation among regenerated plants of the five genotypes was above 60%, which allowed the creation of 93 double haploid lines.

     

A simple wheat haploid and doubled haploid production system using anther culture

Summary Wheat (Triticum aestivum L.) haploids and doubled haploids have been used in breeding programs and genetic studies. Wheat haploids and doubled haploids via anther culture are usually produced by a multiple step culture procedure. We improved a wheat haploid and doubled haploid production system via anther culture in which plants are produced from microspore-derived embryos using one medium and one culture environment. In the improved protocol, tillers of donor plants were pretreated at 4°C for 1–2 wk before anthers were plated on a modified 85D12 basal medium with phenylacetic acid (PAA) and zeatin and cultured at 30°C with a 12-h daylength (43 μEs⁻¹m⁻²) in an incubator. Microspore-derived embryos developed in 2–3 wk and the plants were produced 3–4 wk after anther plating. In the improved system, as much as 53% of the anthers of Pavon 76 were responsive with multiple embryos. For plant regeneration, as many as 22 green and 25 albino plants were produced from 100 anthers. Sixty-five green plants were grown to maturity and 32 (49%) plants were fertile and produced seeds (indicating spontaneous chromosome doubling) while 33 plants did not produce seed. Of five Nebraska breeding lines tested using the protocol, NE96675 was very responsive and the other lines less so, indicating that the protocol is genotype-dependent.     

Endogenous phytohormone profile during oat (Avena sativa L.) haploid embryo development

The development of embryos requires interaction of many endogenous hormones. The aim of the study was to determine which endogenous phytohormones are involved in the process of oat (Avena sativa L.) haploidization. Oat haploids were obtained by wide crossing with Zea mays L. The hormonal profiles of the ovaries with (OE) and without developed embryo (OWE) were compared. Phytohormone contents were measured by UHPLC coupled with mass spectrometer. The total content of indole-3-acetic acid (IAA), trans-zeatin (tZ), and kinetin (KN) in OE was significantly higher than in OWE. 4-Chloroindole-3-acetic acid was detected only in OWE. There were no differences between OE and OWE in the content of gibberellins (GA₁, GA₃, GA₄, GA₆, GA₇) and stress hormones (abscisic, salicylic, jasmonic acids). Content of endogenous KN was highly negatively correlated with the percentage of haploid embryos, germinated haploid embryos, haploid plants on MS (in vitro), haploid plants in soil (ex vitro), and doubled haploid lines. The tZ content negatively correlated with the frequency of haploid embryo formation, germination, and haploid plants obtained in vitro, as opposed to GA₁, which correlated positively. A positive correlation was found between IAA and tZ in OE, whereas in OWE it was a negative correlation. The profiles of phytohormones in OE and OWE were determined; however, their mode of action needs to be clarified.