Production of doubled-haploid plants from tritordeum anther culture

The effects of different media and cold pretreatment of spikes on the androgenic response and regeneration capacity from anther culture of tritordeum was studied. L5 medium gave the highest frequency of anther response. The frequency of cultures regenerating green or albino plantlets was not affected by the composition of the medium tested. Cold pretreatment of the spikes significantly increased the frequency of anther response and also the percentage of cultures giving albino plantlets. A mean of four green plants was obtained per 100 subcultured calli/embryos. The percentage of spontaneous chromosome doubling was only 1%. The addition of colchicine at 0.02% to the induction medium significantly increased the frequency of doubled haploids regenerated without any effect on regeneration capacity. This technique proved more efficient than a conventional chromosome-doubling method.     

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.     

Haploid plants from in vitro anther culture of the leguminous tree,Peltophorum pterocarpum (DC) K. Hayne (Copper pod)

The development of haploid callus, embryos and plantlets from cultured anthers and the various factors affecting androgenesis in Peltophorum pterocarpum (Copper pod), a tropical legume tree is reported. A pretreatment of flower buds at moderate temperature of 14°C for 8 days was most effective for callus production. The colour of the anther was found to be a reliable and efficient indicator for identification of suitable stage of anther for culture. The frequency of anthers which produced callus and shoots was highest when anthers were cultured at mid or late-uninucleate stage. A high sucrose concentration of 10% is a specific media requirement for androgenesis. The haploid nature of the embryos, callus and regenerated plants (n=14) were confirmed by chromosome count.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - KN kinetin - NAA naphthaleneacetic acid - BAP bezylaminopurine     

Doubled haploids of wheat from wheat x maize crosses:genotypic influence, fertility and inheritance of the 1BL-1RS chromosome

The wheat x maize cross as a technique for haploid induction in wheat was evaluated in a replicated block design comprising 18 wheat F₁ hybrids and five Zea mays L. parents. Haploid plants were regenerated at an average of 9.1 (4.4–14.7) plants per 100 florets processed. Genotypic differences for haploid production efficiency were recorded for both wheat and Zea mays L. Interaction between parents was significant for number of plants/100 florets. All 610 of the 1,703 regenerated plantlets that were analyzed by flow cytometry were haploid. At maturity, 70% (60–81 %) of the colchicinetreated haploid plants were fertile, but the frequency of fertile and sterile plants was not consistent over the wheat hybrids from which they were derived. Flow cytometry performed using the first tiller which arose following colchicine treatment enabled prediction of fertility. The 1BL-1RS chromosome was found at the expected ratios in the F₂ and in the haploid progenies produced through the wheat x maize cross but deviated from the 11 ratio in the haploid progenies produced by anther culture.     

The auxins centrophenoxine and 2,4-D differ in their effects on non-directly induced chromosome doubling in anther culture of wheat (T. aestivum L.)

Doubled haploid technologies have become key tools for plant breeding. Using these techniques, the speed and efficiency of plant improvement processes can be significantly enhanced. Anther culture-based technologies have the potential to regenerate large numbers of doubled haploid plants without colchicine treatment. In an attempt to elucidate the influence of phytohormones on non-directly induced chromosome doubling, two synthetic auxins, 2,4-D and centrophenoxine, were tested in a wheat anther culture approach. Whereas the induction of androgenic embryo-like structures (ELSs) was efficient for both auxins, we observed a significantly higher frequency of chromosome doubling when using 2,4-D than when using centrophenoxine. When 2,4-D was added to the induction medium, a positive correlation between the size of ELSs and their ploidy level was detected by flow cytometry. The morphological selection of ELSs, a process that was included in routine operations of the method without significantly extending the input of time and effort, facilitates the production of fertile DH plants with a frequency of 60 %. Our findings may contribute to a more efficient production of doubled haploid wheat plants using a colchicine-free anther culture approach.     

Flower Bud Culture of Shallot (Allium cepa L. Aggregatum group) with Cytogenetic Analysis of Resulting Gynogenic Plants and Somaclones

Unpollinated flower culture was applied for induction of gynogenesis and somatic organogenesis in three shallot strains, ‘Dili-white’, ‘Yogya’ and ‘Dili-red’, from Indonesia. Chromosome surveys were performed on the plants obtained. From a total of 6,812 flowers, 89 plantlets were obtained by gynogenesis, of which 10 could be acclimated. Most of the plantlets were induced from ‘Dili-white’. Of the gynogenetic plants examined, two were haploid (2n = 8), four were naturally doubled haploid (2n = 16) and the remaining four were mixoploid (2n = 8, 16 or 2n = 16, 32, 64). ‘Dili-red’ showed the highest frequency of somatic organogenesis. Fifty-nine directly regenerated plants and 293 callus-derived plants were obtained from somatic organogenesis from the cultured flowers. Based on the chromosome number, frequencies of somaclonal variation were high both in the directly regenerated plants and the callus-derived plants. The frequency of tetraploid plants (2n = 32) in the former (50%) was higher than in the latter (33%). From these results we conclude that unpollinated flower culture is an effective method for chromosome doubling simultaneously with haploid induction in shallot.     

Ploidy stability of maize anther culture-derived callus lines

Summary Ploidy levels of 26Zea mays L. anther culture-derived callus lines of the F1 hybrids (H99 × Pa91, Pa91 × FR16, and H99 × FR16) were determined at various times after culture initiation using flow cytometry (for 21 lines) or chromosome counting of callus cells or regenerated plants (for the remaining 5 lines). Twenty of the lines remained haploid, whereas 6 were diploid. The results from flow cytometry, after examining the DNA content of 5000 nuclei of each callus line, show that each callus line consisted of homogenous haploid or diploid cells. Thus for diploid callus lines, spontaneous chromosome doubling must have occurred before or in the early stages of androgenesis, before the initiation of callus cultures. These long-term callus cultures (growing for up to 38 mo.) have stably maintained their ploidy levels so it is unlikely that the culture conditions have caused chromosome doubling. The restriction fragment length polymorphism pattern obtained with 52 to 58 markers for each diploid callus line shows that all the diploid lines are homozygous diploid so each originated from a microspore and not from diploid maternal F1 hybrid tissue.     

石刁柏花粉植株诱导及其起源鉴定的研究

采用高渗蔗糖溶液预处理石刁柏花药可以显著抑制花药体细胞分裂和提高花粉愈伤组织诱导率。愈伤组织在转入含低浓度激素的培养基中分化得到了花粉植株。其中单倍体、二倍体、四倍体和非整洁体分别占４．３％、６４．５％、１７．２％和１４．０％。单倍体的频率随愈伤组织培养时间延长而下降,石刁柏幼茎中莽草酸脱氢酶同工酶的多态性表现稳定,用其作为遗传标记结合细胞学方法可以鉴定花粉植株的起源。     

Studies on the Induction of Pollen Sporophyte of Coix lacryma Jobic L.

The developmental pathways of pollen sporophyte in anther culture of Coix were observed. The types of androgenesis are different, and are relative to the degree of the differentiation in pollen cells. Pollen-inductors develop via multicellular mass into embryoids or calli. Both of them can develop into plantlets, but the frequency of the regeneration of the plantlets in calli is higher than that of in embryoids, because there are a lot of aberrant embryoids in the latter, which cannot develop further. It was found that the induction frequency of the polleninductors can be increased apparently by the pretreatment in a short time with a hypertonic sucrose solution. The chromosomes of the somatic cells in l0 plantlets were examined. It was found that all the plantlets derived from the embryoids are haploids, while there are haploid, diploid and mixoploid in the plantlets from the calli. The effects of anther wall cells and the stability of haploid cells were discussed.     

l-Ascorbic acid sodium salt promotes microspore embryogenesis and chromosome doubling by colchicine in ornamental kale (Brassica oleracea var. acephala)

Isolated microspore culture (IMC) represents a potential alternative technique in the plant breeding process, as it allows the effective production of doubled haploid (DH) homozygous lines. However, the implementation of this technique is limited by a low rate of embryogenesis, high level of embryo death, and low frequency of chromosome doubling. Thus, we investigated the effects of using different concentrations of L-ascorbic acid sodium salt (VcNa), which has never been applied for kale, to enhance the embryogenesis and regeneration by IMC. Specifically, 1 to 5 μM VcNa was added to the NLN-13 medium of four kale genotypes, while control was grown on VcNa-free medium. Overall, 1–4 μM VcNa at pH 5.84 increased embryogenesis, with 4 μM VcNa being the optimum concentration (12.92-fold increase). The proportion of embryo deaths declined when using appropriate VcNa concentrations. To increase the frequency of chromosome doubling, an artificial chromosome doubling protocol was developed for kale microspore-derived haploids. This protocol involved dipping roots of haploid plantlets in colchicine solution and adding colchicine treatment to solid Murashige and Skoog (MS) medium. Optimum chromosome doubling of haploids was achieved by dipping their roots in 750 mg/L colchicine solution for 4–6 h and 1000 mg/L colchicine solution for 2 h (doubling for nearly 50% of haploids). In conclusion, this study delineated an effective tissue culture process in promoting chromosomal ploidy of microspore-derived regenerated plants, allowing more microspores to be maintained that have excellent ornamental characteristics through crossbreeding.

     

Regeneration capacity of microspore-derived structures produced in anther cultures of maize (<Emphasis Type="Italic">Zea mays</Emphasis> L.)

The regeneration capacity of microspore-derived structures, with various morphological characteristics produced in anther cultures of maize (Zea mays L.) were studied in order to identify the morphotype resulting in the highest yield of spontaneous doubled haploid regenerants. Parallel to the morphological studies the ploidy level of microspore-derived structures and regenerants was analysed by flow cytometry. Neither the growth conditions of the anther donor plants nor the media used in the experiment had any effect on the frequency distribution of different morphotypes. The highest number of spontaneous doubled haploid plants was regenerated from white compact structures 2–3 mm in size, derived from the anthers of phytotron-grown donor plants.     

Origin of plantlets and callus obtained from chile pepper anther cultures

Summary Androgenesis occurred from chile pepper (Capsicum annuum L.) anthers incubated in a continuous warm environment (29° C) with continuous light. Forty plantes and embryoids were retrieved from anther cultures and anllyzed for isozyme markers. Of these, 35 exhibited a single allele for markers suggesting microspore origin, while 5 were heterozygous indicating somatic tissue origin. Chromosome numbers were confirmed for 21 plantlets, of which 16 were haploid and 5 were diploid. However, two plants exhibited a single allele for an isozyme marker but possessed the diploid chromosome number, suggesting spontaneous doubling. Anther cultures also produced callus. Nearly 92% of the slow-growing calli sampled were heterozygous for the isozyme marker, suggesting somatic tissue origin. More than 46% of the fast-growing calli exhibited only one allele for the marker, indicating microspore origin. Callus did not regenerate plantlets. The occurrence of both heterozygous and homozygous diploid plantlets from pepper anther cultures has important implications for applied breeding programs.     

Haploid and doubled haploid plants from developing male and female gametes of Gentiana triflora

Protocols were developed for the generation of haploid or doubled haploid plants from developing microspores and ovules of Gentiana triflora. Plant regeneration was achieved using flower buds harvested at the mid to late uninucleate stages of microspore development and then treated at 4°C for 48 h prior to culture. Anthers and ovaries were cultured on modified Nitsch and Nitsch medium supplemented with a combination of naphthoxyacetic acid and benzylaminopurine. The explants either regenerated new plantlets directly or produced callus that regenerated into plantlets upon transfer to basal media supplemented with benzylaminopurine. Among seven genotypes of different ploidy levels used, 0–32.6% of cultured ovary pieces and 0–18.4% of cultured anthers regenerated plants, with all the genotypes responding either through ovary or anther culture. Flow cytometry confirmed that 98% of regenerated plants were either diploid or haploid. Diploid regenerants were shown to be gamete-derived by observing parental band loss using RAPD markers. Haploid plants were propagated on a proliferation medium and then treated with oryzalin for 4 weeks before transfer back to proliferation medium. Most of the resulting plants were diploids. Over 150 independently derived diploidised haploid plants have been deflasked. The protocol has been successfully used to regenerate plants from developing gametes of seven different diploid, triploid and tetraploid G. triflora genotypes.     

Antimitotic and hormone effects on green double haploid plant production through anther culture of Mediterranean japonica rice

Rice double haploid (DH) plants are produced mainly through anther culture. In order to improve the anther culture protocol, microspores of two japonica rice genotypes (NRVC980385 and H28) were subjected to three growth regulator combinations and four colchicine treatments on induction medium. In addition, a post anther culture procedure using colchicine or oryzalin was tested to induce double haploid plantlets from haploid plantlets. A cold pre-treatment of microspores for 9 days at 10 °C increased callus induction 50-fold in the NRCV980385 genotype. For both genotypes, 2 mg L^?1 2,4-D and 1 mg L^?1 kinetin on colchicine-free induction medium gave the best culture responses. The culturability of both genotypes changed on colchicine-supplemented induction media. A high genotype dependency was recorded for callus induction, callus regenerating green plantlets and regeneration of green double haploid plantlets. Colchicine at 300 mg L^?1 for 48 h enhanced callus induction 100-fold in H28. Colchicine-supplemented media clearly improved green double haploid plantlet regeneration. We showed that the post-anther culture treatment of haploid plantlets at 500 mg L^?1 of colchicine permitted fertile double haploid plantlets to be generated. Finally, an enhanced medium-throughput flow cytometry protocol for rice was tested to analyse all the plantlets from anther and post anther culture.     

Efficient tissue culture and <Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation of haploid poplar derived from anthers

Calli were induced from anthers of Populus simonii × P. nigra. Haploid plants were then regenerated from the callus and multiplied efficiently by culturing leaf explants. The presence of both haploid and diploid cells in the same plant revealed spontaneous chromosome doubling in haploid cells. The haploid plants were transformed with the nptII gene by Agrobacterium-mediated method using leaf explants, and five independent kanamycin-resistant lines were obtained, with a transformation frequency more than 6%. Further PCR test indicated that the exogenous betA gene was transferred into these kanamycin-resistant lines, which were still haploid. Thus, the efficient tissue culture system and transformation of haploid poplar plants were achieved. Our study will contribute to forest improvement via the haploid culture and transgenic technology. Published in Russian in Fiziologiya Rastenii, 2007, Vol. 54, No. 4, pp. 629–633. The text was submitted by the authors in English.     

Heterozygous diploid plants regenerated from anther culture of F1 rice plants

Summary Plants derived from anther culture are theoretically haploid, but diploid plants are also known to arise. Anther culture-derived diploid plants are usually homozygous and are believed to be due to spontaneous doubling of chromosomes in either microsporocytes or callus cells during the culture process. However, heterozygous diploid regenerants may also arise from a) regeneration from cultured somatic cells, b) mutation occurring during or after a spontaneous doubling event, c) fusion of unlike haploid cells in chimeric callus, and d) regeneration from diploid microsporocytes resulting from aberrant meioses. This study was designed to elucidate the frequency and origin of diploid regenerants from rice anther culture. Regenerants were obtained from 11 F₁ genotypes. Progeny testing detected heterozygosity in 7 out of 211 regenerants. Each of the heterozygous regenerants were from ‘Calrose 76’/waxy ‘M-101’, Half of the diploid regenerants from this cross were heterozygous. No heterozygous regenerants arose from the other 10 F₁ genotypes. Progeny testing indicated that two of the heterozygous regenerants were as heterozygous as the F₁ plants for three parental characters. The other five regenerants exhibited decreased levels of heterozygosity. One of the heterozygous regenerants exhibited evidence of mutation for a non-parental character. However, mutation is an unlikely cause of the observed high levels of parental-type heterozygosity. No evidence for the occurrence of chimeric callus was detected, making this an unlikely cause as well. The most likely origin of the observed partial heterozygosity is regeneration from diploid microspores, which could also produce plants exhibiting complete parental-type heterozygosity.     

Ploidy variation of pronamide-treated maize calli during long term culture

Summary Anther-derived calli of corn were treated with 10 M pronamide for 2, 3 and 4 days. The ploidy level of the calli was then evaluated using flow cytometry, at different times after the treatment. Untreated haploid calli did not change in ploidy level for 97 days but by 466 days, there were up to 50% diploid or higher ploidy cells thus showing that spontaneous doubling may occur during corn calli subculture with this genotype. Pronamide treatment did increase the percentage of diploid and tetraploid cells and by 466 days, all of the lines showed an additional change toward higher ploidy levels. This change may be due to spontaneous chromosome doubling or to differential cell cycle times of cells with different ploidy levels. The ploidy level of plants regenerated from the cultures was determined by counting the guard cell chloroplast numbers and the correlation with the ploidy level of the cultures was r²=0.84. These studies show that pronamide treatments can increase haploid maize callus chromosome numbers and that spontaneous chromosome doubling can occur with time in maize callus.     

An efficient procedure for embryogenic callus induction and double haploid plant regeneration through anther culture of Thai aromatic rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L. subsp. <Emphasis Type="Italic">indica</Emphasis>)

Anther culture is a biotechnology technique that can be used for the production of pure lines. The aims of this investigation were to induce embryogenic callus from major and minor culms of Thai aromatic rice cultivars and to subsequently regenerate double-haploid green plantlets by the application of exogenous polyamines. Embryogenic callus derived from anther culture was successfully induced in varieties KDML105, Homjan (HJ), and Pathumthani 1 (PT1). Production of embryogenic callus from anthers collected from the major culms was greater than those collected from the minor culms, especially in cultivar HJ. Plantlet regeneration in the three rice cultivars was observed from embryogenic callus and was highest, at 12.1%, from variety HJ treated with 0.5 mM spermidine. Plantlet regeneration from anther-derived embryogenic callus was dependent on the plant genotype, the types of exogenous polyamines, and the interactions of these factors. The percentage of haploid plantlets regenerated in PT1, KDML105, and HJ were 68.1%, 70.7%, and 78.5%, respectively. Only haploid plantlets were treated with colchicine for double-haploid production. This investigation has increased the knowledge of both embryogenic callus induction and plantlet regeneration in aromatic rice and has lead to the development of a pure, double-haploid line for the use in rice breeding programs in Thailand.     

Colchicine-mediated chromosome doubling during anther culture of maize (Zea mays L.)

Efficient methods of chromosome doubling are critical for the production of microspore-derived, doubled-haploid (=DH) plants, especially if, as in maize anther culture, spontaneous chromosome doubling occurs infrequently. In the present study, colchicine (5–1000 mg/l) was added to the induction medium and maize anthers were incubated in the colchicine-containing medium for different durations (1–7 days). In order to improve overall anther culture response, the culture temperature was adjusted to 14°C during the first 7 days. Colchicine applied at low concentration, i.e. 5 mg/l (7 days), or for short duration, i.e. 1–3 days (250 mg/l), showed beneficial effects on the formation of embryolike structures (=ES) and thus led to increased plant production, but was comparatively ineffective regarding chromosome doubling. Optimal doubling effects were observed when anthers had been exposed to culture medium containing 250 and 1000 mg/l of colchicine (7 days); in these treatments the doubling index (=DI), defined as the quotient of the number of DH plants and the number of totally regenerated plants in a specific treatment, rose to 0.56 and 0.53, respectively, compared to 0.20 in the untreated control. However, colchicine administered at concentrations higher than 250 mg/l seemed to be detrimental to general plant production; thus, in spite of a high DI, the overall DH plant production was even lower than in the control treatment. Maximum DH plant production for three different genotypes was accomplished with culture medium containing 250 mg/l of colchicine (7 days). With the best-responding genotype (ETH-M 36) a DH plant production of 9.9 DH plants/100 anthers was accomplished, i.e. a 7-fold increase compared to the non-treated anthers. This is the first report on efficient chromosome doubling in anther culture by subjecting anthers to colchicinecontaining induction medium during a post-plating cold treatment. Chromosome doubling as described here becomes an integral part of the maize anther culture protocol and thus represents a rapid and economical way to produce DH plants.     

Improved production of doubled haploids of winter and spring triticale hybrids via combination of colchicine treatments on anthers and regenerated plants

Double haploids (DH), obtained during androgenesis in vitro or by genome diploidisation in regenerated haploids, are one type of basic materials used in triticale breeding programmes. The aim of this study was to improve DH production by a combination of colchicine treatment methods on a sample of five winter and five spring triticale hybrids. Colchicine was applied in vitro either in the C17 medium to induce embryo-like structures (ELS) or in the 190-2 medium for green plant (GP) development. Regenerants which remained haploid were immersed in a colchicine solution either when placed on the medium prior to transferring to soil or when growing in pots, followed by the application or absence of cooling. Colchicine treatment during anther culture affected neither ELS nor GP development, but significantly increased the number of DH plants in comparison to spontaneous chromosome doubling. The highest efficiency was recorded when colchicine was applied in the induction medium (55%) versus the regeneration medium (44.5%) or no colchicine treatment (30%). The effectiveness of chromosome duplication in haploid plants ranged from 32 to 64.5% and it was the highest for the treatment on the medium followed by cooling. Individual hybrids differed regarding their capability of regeneration and chromosome doubling, which were consistent only to a low or moderate extent. However, taken together, winter and spring hybrids did not differ significantly. Combined colchicine application resulted in a high yield of DH production, 82.6% for all triticale hybrids, and can provide a considerable number of fertile DH lines for triticale breeding programmes.