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.     

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.     

Effects of X-rays and Colchicine on Pollen of Trichosanthes anguina L. (Cucurbitaceae)

Pollen grains of M, and C, generation plants of Trichosanthes anguina L. were studied after treatment of seeds with X-rays and colchicine respectively. Pollen sterility increased with increase in X-ray dose and colchicine concentration. The polar axis of X-irradiated populations was shorter than that of controls. But colchicine treatment resulted in larger pollen grains than the controls, although the exine did not increase as much. Ex-perimentally-produced tetraploids had larger pollen grains than diploids and triploids. The triploids were characterised by changes in pore morphology. Of 293 treated plants examined, 11 aberrant plants were isolated in the M, and C, generations. These plants had large and small fertile pollen grains, and also showed treatment effects in external morphology and chromosomal aberration during meiosis. The changes in polar diameter were not associated with variation in chromosomal material.     

Enhanced recovery of doubled haploid lines from parthenogenetic plants of melon (<Emphasis Type="Italic">Cucumis melo</Emphasis> L.)

Recovery of doubled haploid (DH) progeny from haploid melon plants for use in breeding programs requires efficient chromosome doubling procedures. We describe improved procedures for recovery of fruits and viable seeds from parthenogenetic melon plants. Plant regeneration from nodal explants treated with 500 mg/L colchicine for 12 h was increased from 40 to 88% by transferring the treated explants to medium supplemented with a combination of growth regulators [5 μM IAA; 5 μM BA; 1 μM ABA; 30 μM AgNO₃). Prolonged exposure (2–7 days) to colchicine inhibited regeneration from nodal explants but had less effect on shoot tip explants. Many colchicine-treated plantlets flowered in vitro, allowing early assessment of their male fertility. Production of stained pollen in plants from nodal explants was highest after 0.5–2 days of colchicine treatment and on plants from shoot tips after 1–2 days. In vitro pollen counts correlated well with counts from greenhouse grown plants and with fruit set. The fruit set rate for colchicine-treated plants with a high pollen number was 47%. Appropriate colchicine treatment and culture of nodal explants as well as tip explants can substantially increase the number of fertile plants and DH lines recovered from parthenogenetic melons.     

Inducing homozygosity in transgenic barley (<Emphasis Type="Italic">Hordeum vulgare</Emphasis> L.) by microspore culture

Homozygosity was induced in transgenic barley by microspore culture. Spikes of transgenic barley plants carrying microspores in the late uni-nucleate stage were cold pretreated. Teflon rod maceration and a density of 100 000 viable micropores per plate were used. The developed calli were regenerated and plantlets were treated with colchicine. The microspore culture of 16 mother plants (three transgenic lines) resulted in 927 green regenerants. Of these plants, 476 were transferred to soil, 380 were transgenic, 358 reached maturity and 350 were fertile with a normal seed-set carrying a yield of 6.9 kg. A production efficiency of 0.8 fertile transgenic doubled haploid barley plants per spike used for microspore isolation was recorded. The produced transgenic seeds were used in malting experiments.     

Effects of colchicine on polyploidy induction of Buddleja lindleyana seeds

Buddleja lindleyana Fort. is a garden ornamental plant with great potential for development and also a commonly used medicinal plant. To enrich its germplasm resources, the seeds of B. lindleyana were treated with colchicine solution with concentration gradients of 0.5%, 1.0%, 1.5%, 2.0% and 3.0% for 12-, 24- and 48-h respectively, and the water treatment was set as the control group. The purpose was to explore the effects of colchicine on the germination and mutagenic effect of B. lindleyana seeds at different concentrations and different times, to screen the appropriate combination of mutagenic concentration and time, to provide guidance for the construction of B. lindleyana mutation population in future research. The results were as follows: (1) Colchicine had an inhibitory effect on seed germination and seedling height of B. lindleyana seeds, and the higher the concentration, the more obvious the inhibitory effect. (2) After colchicine treatment, 30 mutant plants showed morphological variations such as leaf malformation, leaf color macular, early leaf bud germination, uneven leaf surface and leaf hyperplasia, among which 3.0%?+?48-h treatment group had great potential to produce yellow-leaf plants. (3) Detection and analysis by flow cytometry revealed that among the 30 morphologically variant plants, there were 22 diploid plants, 3 tetraploid plants, and 5 chimera plants. Among them, tetraploids were mainly from colchicine concentration of 3.0% (2 plants) and 1.5% (1 plant), chimeras were mainly from colchicine concentration of 1.0% (2 plants), 1.5% (1 plant) and 3.0% (2 plants), and the seed soaking time was 48-h. (4) The length and width of guard cells and stomata were significantly different between diploid and tetraploid, and there were significant differences in leaf width and leaf shape index between tetraploid and diploid, but there were no significant differences in leaf length among diploid, tetraploid and chimera. In short, we got tetraploids and chimeras materials which were potentially useful cultivars of B. lindleyana and provided an effective identification method for polyploids of B. lindleyana.

     

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.     

Improvement in efficiency of microspore culture to produce doubled haploid canola (<Emphasis Type="Italic">Brassica napus</Emphasis> L.) by flow cytometry

The efficiency of production of doubled haploid plants in canola (Brassica napus L.) breeding programmes is reduced when large numbers of haploid and infertile plants survive until flowering. We used flow cytometry to determine ploidy status and predict subsequent fertility of microspore-derived plantlets from three canola genotypes, with or without colchicine treatment of microspore suspensions. Young leaf tissue was sampled from microspore-derived plantlets within 1 week of transfer to soil, and processed immediately by flow cytometry. The process was repeated on the same plants 3–5 weeks later. Of the 519 plants transferred to soil, 57.2% were consistently haploid at both sample times, 33.5% were consistently diploid at both sample times, and the remainder (9.2%) were uncertain or inconsistent in ploidy status across sampling times. Of the 518 plants that survived to flowering, 32.4% were diploid at both times of sampling and fertile (set seed) and 46.3% were haploid at both sampling times and infertile. Another 10.8% were haploid at both sampling times and fertile, but had low pollen viability and seed set, and some were triploid or of uncertain ploidy level. Colchicine treatment of microspore suspensions significantly increased the proportion of diploid plants from 9.7 to 69.7%, with significant variation among genotypes. Evidence from simple sequence repeat marker loci indicated that diploid and fertile plants from the control treatment (no colchicine) were derived from spontaneously doubled haploid gametes, rather than unreduced gametes or somatic tissue. Flow cytometry at the first sample time was very efficient in detecting diploid plants of which 94.2% were subsequently fertile.     

In vitro induction of polyploidy in yacon (<Emphasis Type="Italic">Smallanthus sonchifolius</Emphasis>)

In vitro chromosome doubling was induced in octoploid (2n = 58) yacon using oryzalin and colchicine as mitotic spindle inhibitors. Nodal segments of in vitro cultured plants, 5–15 mm long, were exposed to 20, 25, or 30 μM oryzalin and 1, 3, or 5 mM colchicine for 24 or 48 h. The resulting ploidy level was determined by chromosome counting and flow cytometry. Out of 240 nodal segments, 3.33% hexadecaploid (2n = 116) plants were regenerated after the application of oryzalin. The greatest proportions of hexadecaploid plants (1.6%) were obtained after 48 h of 25 μM oryzalin treatment. With the colchicine treatment, only 0.42% hexadecaploid plants were detected and their survival rate was significantly lower in comparison with the oryzalin treatment. In hexadecaploid yacon, significantly higher levels of saccharides were detected (FOS 13.9 g/100 g FM, fructose 4.6 g/100 g FM and glucose 2.1 g/100 g FM) compared to the octoploid control (FOS 5.3 g/100 g FM, fructose 2.9 g/100 g FM and glucose 1.0 g/100 g FM). These results indicate that in vitro treatment of nodal segments with oryzalin solution could be an effective procedure for chromosome doubling and the polyploidy breeding can help to increase the FOS content in the tuberous roots.     

Effect of in vitro and in vivo colchicine treatments on pollen production and fruit set of melon plants obtained by pollination with irradiated pollen

Haploid/doubled haploid (DH) technology can aid plant breeding programs by accelerating production of homozygous lines, provided enough viable DH progeny can be obtained from diverse haploid genotypes. In cases where there is a low frequency of spontaneous doubling, chromosome doubling procedures are required to achieve fecundity. We produced 63 parthenogenetic melon plantlets via pollination with γ-irradiated pollen, cloned them by nodal cuttings, and tested the effects of in vitro and in vivo colchicine treatment on survival, ploidy, pollen production, and fruit recovery. The most effective procedure was in vitro exposure of 3 cm shoot tip explants to 500 mg/l colchicine for 3 h. This treatment gave 83% survival of explants and 26% conversion to diploidy. Fruit recovery rate was 60% among plants with good pollen production. In vivo exposure of the tops of young plants to 5000 mg/l for 2 and 4 h yielded some fruits but also resulted in less survival and more morphological abnormalities. Strategies for recovery of progeny from parthenogenetic melon plants are recommended. To our knowledge, this study represents the first comprehensive study of recovery of fruits and viable seeds from parthenogenetic melon plants.     

In vivo haploid induction in maize

Two haploid-inducing lines, MHI and M741H, were used for the production of maternal haploids. Haploids were obtained from all maternal genotypes involved in the experiment, including dent, flint and flint×dent maize. The maternal genotype had a significant influence on the frequency of haploids obtained. The frequency ranged from 2.7% to 8.0%. For chromosome-doubling seedlings were treated with colchicine solution, and 49.4% of the haploid plants produced fertile pollen, 39.0% could be selfed and 27.3% produced seeds after selfing. Synthetic populations, improved by haploid sib recurrent selection, were tested in a field trial. The results show that the utilization of maternal haploid plants has great potential for maize breeding and maize genetics. Received: 14 May 2001 / Accepted: 3 August 2001     

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.     

Influence of colchicine treatment on chromosome number and growth rate of tissue cultures of Valeriana wallichii DC

Cell cultures of Valeriana wallichii were treated with 0.05%, 0.2% and 0.5% of colchicine. The treatment with 0.05% and 0.2% colchicine resulted in well growing cultures. At the highest dose the cells died. The colchicine treatment could be repeated after six alkaloid free passages. The chromosome numbers shifted to polyploidy (n>96) under the treatment but had a strong tendency to the initial pattern.Part VI of a series on tissue cultures of Valerianaceae species.     

Manipulation of ploidy for kiwifruit breeding: in vitro chromosome doubling in diploid <Emphasis Type="Italic">Actinidia chinensis</Emphasis> Planch.

Tetraploid plants were induced by colchicine treatment of in vitro leaf petiole segment cultures of five diploid Actinidia chinensis Planch. genotypes, including the commercially important, yellow-fleshed cultivar ‘Hort16A’, three female selections with red-fleshed fruit and one male pollinizer. Petiole segments were incubated on a shoot regeneration medium for a period of 4 weeks, and subsequently microshoots were treated with 0.05 or 0.1% colchicine. About one-third of the regenerated shoots were tetraploid following 0.05% colchicine treatment, more than with 0.1% colchicine treatment. Similar rates of tetraploid induction were achieved with all the genotypes tested. The efficiency of induction of polyploidy depended on the interaction between the types of in vitro culture chosen and the concentration of colchicine used. There are no previous reports of colchicine being used so successfully to induce polyploidy in Actinidia.     

A protocol for fertility restoration of F<Subscript>1</Subscript> hybrid derived from <Emphasis Type="Italic">Lilium</Emphasis> × <Emphasis Type="Italic">formolongi</Emphasis> ‘Raizan 3’ × Oriental hybrid ‘Sorbonne’

The present study was an attempt to develop an in vitro colchicine chromosome doubling protocol to restore the fertility of an F₁ interspecific hybrid in Lilium. Basal scale segments of Lilium?×?formolongi?×?Oriental hybrid (FO) bulblets were pre-cultured for three durations (6, 15 and 25 days) and soaked in three colchicine concentrations (0.00, 1.25 and 2.50 mM) for 18, 24 and 36 h. To separate mixoploids, three cycles of adventitious bud induction were performed. The ploidy levels of the surviving plantlets were detected by flow cytometry at 30–31 weeks after induction and were confirmed by chromosome counts. The results indicated that the pre-culture duration, colchicine concentration and exposure time all had significant impacts on the tetraploid induction rate. The preferred procedure was to pre-culture the segments for 6 days and then treat them with 1.25 mM colchicine for 24 h. The morphological traits of rosette leaves were significantly different between the tetraploid and diploid plants. The adult tetraploid plants had considerably longer and wider leaves, larger flowers, and delayed flowering time (8 days later) than did diploid plants. Pollen viability tests and backcross trials of FO hybrids demonstrated fertility restoration at the tetraploid level. This protocol provides a feasible method for inducing fertile tetraploid FO hybrids for further breeding.     

In vitro induction of tetraploid in pomegranate (Punica granatum)

Tetraploid plants were obtained in pomegranate (Punica granatum L. var. `Nana') by colchicine treatment of shoots propagated in vitro. Shoots cultured on MS medium supplemented with 10 mg l^–1 colchicine, 1.0 mg l^–1 BA and 0.1 mg l^–1 NAA for 30 days produced tetraploids at a high frequency of 20%. No tetraploids were detected by treating the shoots in 5000 mg l^–1 colchicine for 114 h. Shoots treated by 5000 mg l^–1 colchicine for 96 h produced three morphological mutants with narrow leaves, which were later confirmed as mixoploids that separated into diploids and tetraploids after further subculture. In vitro tetraploid plants had shorter roots, wider and shorter leaves than the diploid ones. Tetraploid pomegranate plants grew and flowered normally in pots, but possessed flowers with increased diameter and decreased length compared to diploids. The number of pollen grains per anther was higher in tetraploids, but the viability of pollen decreased significantly.     

Improvements in the production of doubled haploids in durum wheat (<Emphasis Type="Italic">Triticum turgidum</Emphasis> L<Emphasis Type="Italic">.</Emphasis>) through isolated microspore culture

The objective of this study was to produce durum wheat doubled haploid (DH) plants through the induction of microspore embryogenesis. The microspore culture technique was improved to maximize production of green plants per spike using three commercial cultivars. Studies on factors such as induction media composition, induction media support and the stage and growth of donor plants were carried out in order to develop an efficient protocol to regenerate green and fertile DH plants. Microspores were plated on a C₁₇ induction culture medium with ovary co-culture and a supplement of glutathione plus glutamine; 300 g/l Ficoll Type-400 was incorporated to the induction medium support. Donor plants were fertilized with a combination of macro and microelements. With the cultivars ‘Ciccio’ and ‘Claudio’ an average of 36.5 and 148.5 fertile plants were produced, respectively, from 1,000 anthers inoculated. This technique was then used to produce fertile DH plants of potential agronomic interest from a collection of ten F₁ crosses involving cultivars of high breeding value. From these crosses 849 green plants were obtained and seed was harvested from 702 plants indicating that 83% of green plants were fertile and therefore were spontaneously DHs. No aneuploid plant was obtained. The 702 plants yielded enough seeds to be field tested. One of the DH lines obtained by microspore embryogenesis, named ‘Lanuza’, has been sent to the Spanish Plant Variety Office for Registration by the Batlle Seed Company. This protocol can be used instead of the labor-intensive inter-generic crossing with maize as an economically feasible method to obtain DHs for most crosses involving the durum wheat cultivars grown in Spain.     

Stable inheritance and expression of the CMS traits introduced by asymmetric protoplast fusion

The donor-recipient protoplast fusion method was used to produce cybrid plants and to transfer cytoplasmic male sterility (CMS) from two cytoplasmic male-sterile lines MTC-5A and MTC-9A into a fertile japonica cultivar, Sasanishiki. The CMS was expressed in the cybrid plants and was stably transmitted to their progenies. Only cytoplasmic traits of the male-sterile lines, especially the mitochondrial DNAs, were introduced into the cells of the fertile rice cultivar. More than 80% of the cybrid plants did not set any seeds upon selfing. Sterile cybrid plants set seeds only when they were fertilized with normal pollen by hand and yielded only sterile progenies. This maternally inherited sterility of the cybrid plants showed that they were characterized by CMS. The CMS of cybrid plants could be restored completely by crossing with MTC-10R which had the single dominant gene Rf-1 for restoring fertility. These results indicated that CMS was caused by the mitochondrial genome introduced through protoplast fusion. The introduced CMS was stably transmitted to their progenies during at least eight backcross generations. These results demonstrate that cybrids generated by the donor-recipient protoplast fusion technique can be used in hybrid rice breeding for the creation of new cytoplasmic male-sterile rice lines.     

Cytogenetic analysis of plants regenerated from colchicine-treated callus cultures of an interspecificHordeum hybrid

Summary Hybrids of Hordeum vulgare (HV) x H. jubatum (HJ) were synthesized for purposes of introgressive breeding, but were sterile and the recovery of pure diploid tillers by colchicine applications in vivo was difficult. Plant regeneration from colchicine-treated callus cultures of the hybrid (HV x HJ) was investigated as a means to produce high numbers of pure diploid, fertile intermediates. 10 of 50 plants regenerated in this manner exhibited variable chromosome numbers with means of approximately 37 (expected diploid number = 42). Cytological examinations of microsporogenesis in all such plants revealed a high incidence of bivalent formation at metaphase I (as compared to nearly complete asynapsis in the F₁), but spindle and chromosome abnormalities in later meiotic stages led to complete sterility. Approximately 40% of HJ plants regenerated from colchicine-treated calli appeared to be pure tetraploids of high fertility. These techniques are hence useful for high frequency production of diploid or polyploid 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.