The effect of colchicine on triticale anther-derived plants: Microspore pre-treatment and haploid-plant treatment using a hydroponic recovery system

In cereals, chromosome doubling of microspore-derived haploid plants is a critical step in producing doubled haploid plants. This investigation was undertaken to study the effect of incorporation of colchicine in the induction medium for anther culture, and the effect of colchicine on anther culture-derived plants of triticale grown under controlled greenhouse conditions. In the latter case, chromosome doubling of adult sterile plants derived from anther culture of fourteen triticale populations was attempted, where androgenetic plants with non-dehiscent anthers were cloned and subjected to the colchicine treatment, and then grown with the aid of hydroponics. The hydroponic system provided optimal conditions for recovery of the affected haploids from the toxic effects of colchicine treatment and all colchicine-treated plants survived. A topcross-F₁ (TC₁F₁) population with timopheevii cytoplasm produced the highest percentage of plants with seed-set either due to chromosome doubling by colchicine (98%) or spontaneous doubling of chromosome number (15%). Colchicine-treated anthers performed inferior than control in both induction and regeneration phases. One of the key observation of this study was the reversal from reproductive stage back to the vegetative stage which in turn enabled further cloning of haploid plants under hydroponic conditions once they were identified as sterile. The one hundred percent survival rate of in vitro-derived plants, 100% survival rate of colchicine treated haploid plants and the high chromosome doubling success rate (X = 82.3) observed in this study imply that a temperature-controlled greenhouse with an hydroponic system provides an efficient environment for inducing chromosome doubling of haploid plants in cereals. This revised version was published online in August 2006 with corrections to the Cover Date.     

开发实用的染色体加倍体系构建成烟草DH群体

通过对4种染色体加倍方法(烟草浸花药法、浸花培苗法,叶片再生法及浸腋芽法等)的比较研究表明：以4g／L浓度的秋水仙碱浸泡花药法加倍率最高达47．5％～75％,其次为叶片再生法(30％～36．67％)和浸苗法(16．67％～32．35％),而浸腋芽法较低(17．78％)。前两种方法加倍率虽高,但有较高畸形苗比率,叶片再生法工序较繁琐。作者认为烟草加倍单倍体产生,应以采用浸苗法为主。在使用秋水仙碱浸苗加倍时,添加DMSO可明显促进秋水仙碱的加倍效率,且促进作用随时间延长而提高：从高效、快捷和节约等原则考虑,我们开发了烟草有效的染色体加倍体系,以4g／L的秋水仙碱 20g／LDMSO溶液浸苗48h的效果最好。对两个组合烟草单倍体苗浸12h以上,其染色体加倍效率达到对照的2．30-2．93倍。本试验用较低浓度秋水仙碱添加DMSO有利于节约实验费用。通过完善染色体加倍技术程序已构建成2个DH群体,供基因定位研究。     

Production of Doubled Haploids by Anther Culture and Wheat X Maize Method in a Wheat Breeding Programme

Utilization of the doubled haploid method of breeding usually shortens the time to cultivar release, and methods of haploid production need evaluation in a breeding programme. Thirty-eight different three-way crosses were tested for anther culture response. On average 5.8 percent of the anthers cultured produced calli. Three crosses were found recalcitrant for callus induction. Overall, the anther culture method produced 0.6 plantlet per 100 anthers cultured. Five crosses with an average of 5.8 and 2.8 percent of anthers producing calli and plantlets, respectively, were compared using anther culture and wheat × maize crosses. Non-responsive genotypes for callus induction and plantlet formation in the anther culture method proved to be good parental material in wheat × maize crosses. The average percentages of embryo formation and plantlet production in wheat × maize crosses were 10.3 and 4.7, respectively. Anther-derived plants were cytologically unstable, whereas all the plants regenerated from wheat × maize crosses were haploids (n = 21 chromosomes). The chromosome numbers of the polyhaploids were doubled with a colchicine treatment. Improvement of the two haploid production methods to facilitate their efficient use in a breeding programme is discussed.     

Efficient Production of Doubled Haploid Plants through Chromosome Doubling of Isolated Microspores in Brassica napus

Three methods of chromosome doubling to produce doubled haploid plants from microspore cultures of Brassica napus were compared: colchicine treatment of microspore-derived plants, microspore-derived embryos, and isolated microspores. In the whole plant treatment, 53% of the treated plants set seed, but the treatment delayed plant growth and reduced seed set. When microspore-derived embryos were treated with colchicine, the doubling frequency was 32% (compared to 15% for spontaneous doubling). Direct colchicine treatment of isolated microspores resulted in a doubling efficiency of 70 % of the whole plants. This treatment also stimulated embryogenesis in microspore culture, leading to increased plant regeneration. Thus, direct chromosome doubling of isolated microspores is efficient and more than 10 000 doubled haploid plants have been produced in this manner in the past three years in order to accelerate the plant-breeding process.     

Assessment of different anther culture approaches to produce doubled haploids in cucumber (<Emphasis Type="Italic">Cucumis sativus</Emphasis> L.)

Cucumber is one of the most important vegetable crops worldwide, which makes it a good candidate to produce doubled haploid (DH) lines to accelerate plant breeding. Traditionally, these approaches involved induction of gynogenesis or parthenogenesis with irradiated pollen, which carries some disadvantages compared to androgenesis. Despite this, studies on anther/microspore cultures in cucumber are surprisingly scarce. Furthermore, most of them failed to unambiguously demonstrate the haploid origin of the individuals obtained. In this work we focused on anther cultures using two cucumber genotypes, different previously published protocols for anther culture, different in vitro culture variants to make it more efficient, and most importantly, a combination of flow cytometry and microsatellite molecular markers to evaluate the real androgenic potential and the impact of anther wall tissue proliferation. We developed a method to produce DH plants involving a bud pretreatment at 4 °C, a 35 °C treatment to anthers, culture with BAP and 2,4-D, and induction of callus morphogenesis by an additional 35 °C treatment and sequential culture first in liquid medium in darkness and second in solid medium with light. We also found that factors such as genotype, proliferation of anther wall tissues, orientation of anthers in the culture medium and growth regulator composition of the initial anther culture medium have a remarkable impact. Our rate of chromosome doubling (81%) was high enough to exclude additional chromosome doubling steps. Together, our results present androgenesis as an improvable but yet more convenient alternative to traditional gynogenesis and parthenogenesis-based approaches.     

The production of homozygous diploid plants of Solanum verrucosum by tissue culture techniques

Summary Monohaploid plants of S. verrucosum (2n=x=12) were induced in anther culture. Axillary buds from these plants were treated with colchicine in shoot tip culture for 48 hours and then transferred to a colchicine free medium. The resulting plantlets were scored for diploidy by stomatal chloroplast counts and root tip cytology and it was found that doubling of the chromosome number had occurred.     

Improving androgenesis‐mediated doubled haploid production efficiency of FCV tobacco (Nicotiana tabacum L.) through in vitro colchicine application

Production of doubled haploid plants through androgenesis in flue‐cured Virginia (FCV) tobacco is a promising and convenient alternative to conventional selfing techniques for the generation of absolute homozygous lines. Here, we show a robust in vitro haploid and doubled haploid development protocol in FCV tobacco with major emphasis on improving the efficiency of chromosome doubling using in vitro colchicine treatment. We used five FCV tobacco hybrids for comparison of colchicine treatments. The anther culture response varied with developmental stages of the buds, and the highest response was observed in stage 2 buds. The effect of cold pretreatment was significant, and 4 days of pretreatment was optimum for gametic embryogenesis. Among the methods used for determining the ploidy status of plants, flow cytometry was found to be easy, fast and reliable for high‐throughput screening of haploids. Doubled haploids regeneration percentage varied from 6.77 to 11.95 in in vivo treatment, while the range of variation was 22.11% to 28.40% in in vitro colchicine treatment. We observed a pronounced increase in plant survival and the proportion of doubled haploid plants in in vitro treatment compared with the standard in vivo approach.     

Oryzalin as an Efficient Agent for Chromosome Doubling of Haploid Apple Shoots in vitro

In an outbreeding species such as apple, haploid plants may be especially useful in breeding programmes for the production of homozygous material. However, methods must be available to induce chromosome doubling in the haploid plants. Two antimitotic agents, colchicine and oryzalin, were compared as regards their efficiency in inducing chromosome doubling of in vitro haploid apple shoots. Three colchicine levels (0.025, 0.25 and 1.25 mM) and three oryzalin levels (5, 15 and 30 μM) were evaluated. Three techniques were also used and compared. Survival rate and chromosome counts were determined. Differences were observed between the two antimitotic agents and between the three techniques. This study demonstrates that oryzalin could be a better choice than colchicine for chromosome doubling on haploid apple shoots in vitro.     

In vitro chromosome doubling with colchicine during microspore culture in wheat (Triticum aestivum L.)

Isolated microspores of two DH lines of wheat were treated with 8 different colchicine concentrations up to 3 mM for either 24 h or 48 h during microspore culture. Untreated control cultures produced on average 220 embryos per spike (100,000 microspores), 68% of the regenerated plantlets were green, and 15% of the flowering plants were fertile. The colchicine treatments had a significant effect on chromosome doubling as measured by the percentage of fertile regenerants. Using colchicine concentrations around 1 mM the percentage of fertile plants among the regenerants was increased up to 53%. The highest number of embryos and regeneration rates were observed after 24 h colchicine treatment, while the highest frequencies of green plants and fertile plants were obtained with 48 h colchicine treatments. The highest number of DH plants per spike was found after treatment with colchicine concentrations of 300 to 1000 μM. Such treatments resulted in an estimated average between the two genotypes of 23 doubled haploid plants per spike. This revised version was published online in July 2006 with corrections to the Cover Date.     

In vitro chromosome doubling of Miscanthus sinensis

The aim was to develop an efficient chromosome doubling method for Miscanthus sinensis to enable the production of triploids and so avoid seed dispersal to the environment. Antimitotic treatments with colchicine or oryzalin were tested in M. sinensis cl. MS‐88‐110 on: (1) in vitro shoots and plants established in soil; (2) during propagation of embryogenic callus; and (c) during the initial stages of callus induction. All systems produced chromosome‐doubled plants. A higher percentage of tetraploids was found after antimitotic treatment at the explant or callus level compared with treatment of in vitro shoots or plants established in soil. In general, oryzalin was more toxic to plant material than colchicine. A higher frequency of chimeras was found among plants with altered ploidy level when the target was formed shoot buds compared with adventitious shoot formation from callus. Antimitotic treatment of embryogenic callus from shoot apices also resulted in a high degree of albinism.     

Comparative analysis of in vitro anther- and isolated microspore culture in hexaploid Triticale (X Triticosecale Wittmack) for androgenic parameters

Two haploid induction media (190-0 and W14mi) were tested in isolated microspore culture of two triticale (X Triticosecale Wittmack) genotypes. The W14mi medium proved superior for the production of green plantlets in both genotypes. This basic medium (W14) was used to compare two doubled haploid production methods (isolated microspore culture and anther culture) with the same genotypes. The induction of androgenesis was more effective in isolated microspore culture than in anther culture. The number of embryo-like structures was 9.2 times higher in microspore culture (511.0/100 anthers) compared to anther culture (55.5/100 anthers) and the number of regenerant plantlets was also 3.4 times higher (anther culture—20.15/100 anthers; isolated microspore culture—67.6/100 anthers). However, the regenerant plantlets from isolated microspore culture were mainly albinos while predominantly green plantlets were regenerated from anther culture. The production of green plantlets from anther culture (16.8/100 anthers) was 2.9 times higher than from isolated microspore culture (5.8/100 anthers). The efficiency of anther culture was tested with eight winter triticale genotypes. The phenomenon of albinism did not hinder the green plant production in anther culture. Mean green plantlet production was 10.87/100 anthers. This value was two times higher than the number of albinos (5.01/100 anthers) and higher than previously published reports. The anther culture protocol described in this study is an efficient tool for the production of microspore-derived green plantlets in triticale.     

马铃薯高效染色体加倍方法建立与抗寒资源创制

In this work, different treatment combinations including colchicine concentrations and treatment methods as well as different time points was used to investigate the survival rate and chromosome doubling efficiency of potato tissue culture plantlets. The potato chromosome doubling by using colchicine had been successfully optimized. The potato plantlet stems treated with 0.1% colchicine for three days shaking at 120 r min^-1 showed the highest doubling efficiency due to its better contact to the colchicine solution. Compared with other potato chromosome doubling techniques, this method has much higher chromosome doubling rate, shorter time treatment and easier to operate, so that it could provide a higher efficient method for potato ploidy operation. In the meantime, compared with the diploid, the tetraploid interspecific hybrids showed differences in the morphological characteristic, which had higher plants, thicker stem, bigger petals and pollen grain. In addition, no significant difference was found between diploid and tetraploid interspecific hybrids in terms of cold resistance, but both significantly enhanced cold resistance compared with the common potato cultivar. Taken together, the doubled interspecific hybrids could sever for improving cold resistance of potato cultivars.     

Development of novel chromosome doubling strategies for wheat × maize system of wheat haploid production

Two chromosome doubling strategies were evaluated for producing wheat doubled haploids from wheat x maize crosses: (i) in vitro colchicine application to haploid embryos and (ii) colchicine treatment through postpollination tiller injections. In the in vitro approach the haploid embryos were rescued on medium containing colchicine (at concentrations of 0.2, 0.3, 0.4 and 0.5%) and moved to a colchicine‐free regeneration medium 48 h later. Embryos exposed to 0.5% colchicine had 91.67% of their regenerated plants showing chromosome doubling. In the tiller injection approach, different concentrations (0.5, 0.75 and 1.0%) of colchicine solution, which also contained 2,4‐D (100 ppm), were injected into the uppermost inter‐node of crossed tillers 48 and 72 h after pollination. The chromosome doubling efficiency varied from 33 to 100%, with 1% treatment being the most effective. No chimeras of doubled/haploid sectors were observed in the case of the tiller injection treatment and all the florets showed seed set in the doubled plants. Stomatal guard cell length provided rapid, early‐stage and unambiguous analysis of ploidy level on the basis of 10 guard cell observations per plant.     

Anther culture in connection with induced mutations for rice improvement

Doubled haploids have long been recognized as a valuable tool in plant breeding since it not only offers the quickest method of advancing heterozygous breeding lines to homozygosity, but also increases the selection efficiency over conventional procedures due to better discrimination between genotypes within any one generation. Ten cultivars of japonica rice and nine cultivars of indica rice were evaluated for androgenic response. Various doses (10–50 Gy) of gamma rays were applied to investigate the effect of radiation on callus formation, green plant regeneration and the frequency of selected doubled haploid mutants. Similarly, the effects of colchicine concentration (10–200 mg/l) on callus induction, regeneration and fertility of green plants were observed. It was demonstrated that the dose of 20 Gy gamma rays and 30 mg/l concentration of colchicine have significant stimulation effect on regeneration of green plants from rice anther culture. The high frequency of observed doubled haploid mutants indicates that anther culture applied in connection with gamma rays is an effective way to improve rice cultivars. This revised version was published online in August 2006 with corrections to the Cover Date.     

Retrospect on in vitro androgenesis of sorghum (Sorghum bicolor)

Development of sorghum hybrids can immensely benefit from an enhanced anther culture protocol since the resultant doubled haploids would accelerate, as in other major cereal crops, the attainment of homozygosity and fixation of alleles. Production of the hybrids that have got high yielding, stress tolerance and other traits of industrial significance in a shorter time as compared to the current trend can hence be realized. This review presents the advances that have been made in the development of such a protocol, with closer attention to androgenic induction components of pre-treatment, culture media composition and conditions as well as ploidy determination and eventual chromosome doubling. From the findings of this review, it is clear that further work is desired to ensure a protocol, that to a large degree, breaks the genotype dependency trend that has been widely cited to impede the usability of the tested protocols.     

Relative Efficiency of Anther Culture and Chromosome Elimination Techniques for Haploid Induction in Triticale × Wheat and Triticale × Triticale Hybrids

Summary The study was undertaken to evaluate the relative efficiency of anther culture and chromosome elimination (by crosses with maize) techniques of haploid induction in intergenotypic triticale and triticale × wheat hybrids. For this, 15 triticale × wheat and 8 triticale × triticale F₁ hybrids were subjected to anther culture and were also simultaneously crossed with the `Madgran Local' genotype of maize (Zea mays L.) to induce haploids through the chromosome elimination technique. The haploid embryo formation frequency through the chromosome elimination technique was significantly higher in both, triticale × wheat (20.4%) and triticale × triticale (17.0%) F₁ genotypes, as compared to the calli induction frequencies through anther culture (1.6 and 1.4%, respectively). Further, four triticale × wheat and three triticale × triticale F₁ genotypes failed to respond to anther culture, whereas, all the F₁ genotypes formed sufficient number of haploid embryos through the chromosome elimination technique with no recovery of albino plantlets. The haploid plantlet regeneration frequencies were also significantly higher through the latter technique in both triticale × wheat (42.7%) and triticale × triticale (49.4%) F₁s as compared to anther culture (8.2 and 4.0%, respectively), where the efficiency was drastically reduced by several constraints like, high genotypic specificity, low regeneration frequency and albinism. The overall success rates of obtaining doubled haploids per 100 pollinated florets/anthers cultured were also significantly higher through the chromosome elimination technique (1.1% in triticale × wheat and 1.5% in triticale × triticale hybrids), proving it to be a highly efficient and economically more viable technique of haploid induction as compared to anther culture, where the success rates were only 0.2% and 0.1%, respectively.     

Efficient production of doubled haploid wheat plants by in vitro treatment of microspores with trifluralin or APM

Isolated microspore cultures from two doubled haploid (DH) lines of wheat, Triticum aestivum L., were used to develop an in vitro chromosome-doubling protocol. During the initial 24 h or 48 h of culture the microspores were treated with either of the two antimicrotubule herbicides trifluralin or amiprophos-methyl (APM) in concentrations ranging from 0.1 μM to 10μM. Untreated control cultures yielded 209 embryos per 100000 microspores, which is the equivalent of one spike. Among the regenerated plantlets 67% were green, and 15% of the flowering plants were spontaneously chromosome doubled. Treatments with both the herbicides had a significant effect on chromosome doubling, measured as the percentage of fertile regenerants. With the best combination of treatment duration (48 h) and herbicide concentration (10/μM) the percentage of fertile plants among regenerants could be increased up to 74% with APM and up to 65% with trifluralin. The largest numbers of DH plants per spike could be obtained with herbicide concentrations at 1–3 μM. Treatments with either herbicide at these concentrations resulted in an estimated average between the two genotypes of 27 DH plants per 100 000 microspores. These results demonstrate the high potential of APM and trifluralin as chromosome-doubling agents in isolated microspore cultures. The in vitro treatment integrated into tissue culture procedures will constitute an efficient method for chromosome doubling in future wheat breeding     

Antimicrotubule herbicides for in vitro chromosome doubling in Beta vulgaris L. ovule culture

In vitro chromosome doubling during ovule culture of sugar and fodder beets (Beta vulgaris L.) was studied with four anti-microtubule herbicides: amiprophos-methyl (APM), oryzalin, pronamide, and trifluralin at concentrations of 0–300 μM. Best chromosome doubling results were obtained by treatment of the ovules with 100 μM APM which produced 4.7 diploid plants per 100 ovules. Highest chromosome doubling was found with oryzalin using 1 μM, with trifluralin at 10 μM, and with pronamide at 10 μM producing 2.8, 2.0, and 2.0 diploid plants per 100 ovules, respectively. The APM treatments showed relatively low toxicity on embryo formation which in combination with a high chromosome doubling effect, resulted in up to 89 diploids per 100 plants regenerated. Oryzalin and trifluralin had more severe toxic effects, which reduced embryo formation, thereby lower percentages of chromosome doubled plants were obtained from these treatments. Pronamide had no significant toxic effect but it induced chromosome doubling at lower frequencies. Compared to colchicine, APM seems to be as efficient for chromosome doubling during beet ovule culture, but at molar concentrations 100 times lower than those used for chromosome doubling with colchicine. This revised version was published online in July 2006 with corrections to the Cover Date.     

芦笋单倍体染色体加倍技术研究

研究了芦笋单倍体染色体加倍的方法。在离体培养条件下,以秋水仙素为诱变剂,分别用浸泡法和培养基添加法处理芦笋单倍体幼苗的茎尖,比较了秋水仙素不同浓度、不同处理时间的诱导效果。结果表明,培养基添加法的诱导效果好于浸泡法,当在培养基中添加0.3%秋水仙素并处理7天时诱导效果最佳,染色体加倍频率与成活率分别可达82.50%和80%。加倍后的二倍体植株与单倍体植株相比,茎干变粗,气孔与保卫细胞增大,保卫细胞内的叶绿体数增多。     

Spontaneous and induced chromosome doubling in gynogenic lines of onion (Allium cepa L.)

The presence of 2,4-dichlorophenoxyacetic acid (2,4-D) or naphthaleneacetic acid (NAA) and 6-benzyladenine (6—BA) in the medium is required to induce an acceptable yield of gynogenic embryos from unfertilized ovary and flower cultures in onion. Four different exposure times of ovary and flower cultures to exogenous growth regulators (15, 30, and 45 days, and the entire culture period) were assayed. The objective was to ascertain the effect of these substances and of their period of application on the formation of gynogenic embryos and on the yield of haploids. An exposure of 15 days was sufficient for ovaries and flowers to be stimulated towards the gynogenic response, whereas, for the remaining period of 30—80 days, the pro-embryos could easily grow on a growth-regulator-free medium. In the gynogenic material obtained, phenotypic differences were visible between genetically independent lines but not between plants within each line, even when they had a different ploidy level (n or 2n). Almost all lines obtained by gynogenesis were sterile. Only a small percentage (1%) became fertile through spontaneous chromosome doubling, and these produced 2—20 seeds each, giving normal plants. The recovery of fertility occurred more often during the generations of bulbils. To exploit this natural propensity towards diploidization in this phase, different amounts and numbers of applications of colchicine were evaluated in two experiments. The treatments corresponding to 10 and 100 mg/1 of colchicine applied for 24h gave the highest number of diploid cells in root tips but no diploidization occurred in the shoot apices. Three days of colchicine treatment at 10 mg/1 produced 46% of plants completely diploid in the shoot apex. The flower fertility of these doubled haploid plants is being evaluated.