In vitro chromosome doubling of nineZantedeschia cultivars

Tetraploid plants have been produced from nineZantedeschia cultivars usingin vitro colchicine treatment. Rapidly-multiplying shoot cultures were treated on a medium containing 0.05% colchicine for 1, 2 or 4 days to induce chromosome doubling. Following the treatment, most shoots were killed but the surviving shoots were multiplied for several subcultures. These shoots were then rootedin vitro and transferred to a greenhouse. Plants were screened 2 months later by measuring stomatal length, and 110 out of 565 plants were selected as putative tetraploids with a stomatal length significantly greater than in diploid control plants. Chromosome counts were carried out on root tips from 44 plants and confirmed that 38 were tetraploids, 2 were chimeras (predominantly tetraploid with a few octoploid cells), and 4 were diploids. Stomatal length has been rechecked in mature tetraploid plants of the cultivar Black Magic, demonstrating that stomatal length is a good indicator of ploidy level inZantedeschia. This study has shown that multiplying colchicine-treated shootsin vitro for several subcultures prior to transfer to soil produced very few chimeras. The stomatal length measurements are non-destructive and allow the rapid screening of a population for tetraploids.     

In vitro chromosome doubling of nineZantedeschia cultivars

Tetraploid plants have been produced from nineZantedeschia cultivars usingin vitro colchicine treatment. Rapidly-multiplying shoot cultures were treated on a medium containing 0.05% colchicine for 1, 2 or 4 days to induce chromosome doubling. Following the treatment, most shoots were killed but the surviving shoots were multiplied for several subcultures. These shoots were then rootedin vitro and transferred to a greenhouse. Plants were screened 2 months later by measuring stomatal length, and 110 out of 565 plants were selected as putative tetraploids with a stomatal length significantly greater than in diploid control plants. Chromosome counts were carried out on root tips from 44 plants and confirmed that 38 were tetraploids, 2 were chimeras (predominantly tetraploid with a few octoploid cells), and 4 were diploids. Stomatal length has been rechecked in mature tetraploid plants of the cultivar Black Magic, demonstrating that stomatal length is a good indicator of ploidy level inZantedeschia. This study has shown that multiplying colchicine-treated shootsin vitro for several subcultures prior to transfer to soil produced very few chimeras. The stomatal length measurements are non-destructive and allow the rapid screening of a population for tetraploids.     

In vitro induction of tetraploids in Arachis paraguariensis

In this study, an efficient procedure was established for successful induction of tetraploid Arachis paraguariensis by treating diploid explants with colchicine. Quartered-seed, callus and shoot-tips were treated with colchicine at concentrations of 0.05, 0.1, 0.2 and 0.5?% (w/v) for 4, 8, 16, 20 and 24?h before they were transferred unto modified Murashige and Skoog medium for either callus induction or shoot regeneration. Results showed that quartered-seed displayed the highest frequency of in vitro plantlet regeneration and tetraploid induction, as well as the lowest mortality rate. Flow cytometric analysis also confirmed that the induced tetraploids from quartered-seed were true-to-type. The 0.5?% colchicine treatment for 4 to 8?h gave the best results with 39 and 43?% of the explants yielding tetraploid plants, respectively. Two?months following transfer to ex vitro environment, morphological and growth characteristics of the induced tetraploids were measured. Overall, increasing the ploidy level from 2× to 4× resulted in fewer stomata but more trichomes per unit leaf area. Tetraploid plants obtained in this study should expand the genetic base of Arachis, and can also be used in overcoming the existing hybridization barriers that may be due to ploidy differences within the genus Arachis.     

In vitro induction and identification of tetraploid plants of <Emphasis Type="Italic">Paulownia tomentosa</Emphasis>

Polyploidization is a major trend in plant evolution that has many advantages over diploid. In particular, the enlargement and lower fertility of polyploids are very attractive traits in forest tree breeding programs. We report here a system for the in vitro induction and identification of tetraploid plants of Paulownia tomentosa induced by colchicine treatment. Embryonic calluses derived from placentas were transferred to liquid Murashige and Skoog (MS) medium containing different concentrations of colchicine (0.01, 0.05, or 0.1%) and incubated for 24, 48, or 72 h on an orbital shaker at 110 rpm. The best result in terms of the production of tetraploid plantlets was obtained in the 48 h + 0.05% colchicine treatment, with more than 100 tetraploid plantlets being produced. The ploidy level of plantlets was verified by chromosome counts, flow cytometry, and morphology. The chromosome number of tetraploids was 2n = 4x = 80 and that of diploid plantlets was 2n = 2x = 40. The relative fluorescence intensity of tetraploids was twofold higher than that of diploids. The tetraploid and diploid plantlets differed significantly in leaf shape, with those of the former being round and those of the latter pentagonal. The mean length of the stomata was longer in tetraploid plants than diploid plants, and stomatal frequency was reduced with the increased ploidy level. The tetraploids had large floral organs that were easily distinguishable from those of diploid plants.     

In vitro tetraploid induction and generation of tetraploids from mixoploids in hop (Humulus lupulus L.)

This paper describes an efficient colchicine-mediated technique for the in vitro induction of hop tetraploids and its confirmation by flow cytometry. A window of conditions generated a high percentage (>20%) of tetraploid induction, with the highest induction (25.6%) achieved with 0.05% colchicine for 48 h. Colchicine-induced tetraploids remained stable after 6 months in soil. Leaf characteristics of diploid and tetraploid hops were compared, and it was determined that stomatal length and width are suitable parameters for identifying putative hop tetraploids. As well as generating tetraploids, this technique generates mixoploid hops. Calli, derived from mixoploid leaves, were induced to form shoot buds and shoots. Individual shoots were classed as diploid, mixoploid or tetraploid after screening by flow cytometry. This callus-based technique can be employed when a genome-doubling agent generates mixoploids but fails to generate tetraploids.     

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.     

Colchicine and oryzalin mediated chromosome doubling in different genotypes of Miscanthus sinensis

Different explant materials were treated with antimitotic agents to induce chromosome doubling in several Miscanthus sinensis clones. In vitro propagated plants established in soil, in vitro shoots, embryogenic callus, shoot apices and leaf explants were treated with different concentrations of colchicine or oryzalin. No tetraploids were obtained after antimitotic treatment of plants established in soil. The percentage of chromosome doubled plants after antimitotic treatment of single in vitro shoots was genotype dependent. Rooted in vitro plantlets were not a suitable target for antimitotic treatment, due to a high frequency of ploidy chimeras. Many tetraploid plants were regenerated after antimitotic treatment at the callus and explant level, but the efficiency was genotype dependent, primarily due to differences in the ability to form regenerable callus and to regenerate plants from embryogenic callus. Treatment of shoot apices with colchicine was the most efficient and reproducible system in the four genotypes tested. It was possible to repeatedly use the same colchicine-containing medium without any reduction in the induction of regenerable callus or in the percentage of tetraploids, thereby minimising the handling of this very toxic compound.     

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.     

<Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation of protocorm-like bodies in <Emphasis Type="Italic">Cattleya</Emphasis>

A protocol for in vitro induction of crape myrtle tetraploids using nodes from in vitro-grown shoots (2n = 48) was established. Nodal buds were excised from in vitro-grown shoots, maintained on proliferation medium containing Murashige and Skoog medium supplemented with 4.44 μM 6-benzyladenine , 0.54 μM α-naphthaleneacetic acid, and treated with a range of concentrations of colchicine under three different conditions. Nodal bud explants treated in liquid proliferation medium supplemented with either 15 or 20 mM colchicine for 24 h turned necrotic and died; whereas, those cultured on solid proliferation medium supplemented with either 125 or 250 μM colchicine for 30 days survived, but no tetraploid plants were obtained. However, when explants were cultured in liquid proliferation medium containing 250, 500 or 750 μM colchicine for 10 days, tetraploid plants (2n = 96) were obtained. Incubation of explants in medium containing 750 μM colchicine promoted the highest frequency of survival (40%) of explants and of recovered tetraploids (60%). Morphological and anatomical characteristics of leaves, including leaf index, stomata size and number, stomata index (length/width), and number of chloroplasts in guard cells correlated with ploidy of crape myrtle plants. The number of chloroplasts in guard cells of stomata was a stable and reliable marker in discriminating plants of different ploidy levels. Chromosome counts and flow cytometry confirmed these findings.     

The effects of colchicine-induced autotetraploidy on selected characteristics of nuruozak (<Emphasis Type="Italic">Salvia leriifolia</Emphasis>)

Nuruozak (Salvia leriifolia Benth), is a perennial herbaceous plant that is endemic to Iran and has recently been introduced as a medicinal plant. Artificial polyploidy is an efficient method to increase the production of secondary metabolites and can result in a whole spectrum of genetic, molecular and physiological modifications. In order to produce an autotetraploid population of nuruozak, various concentrations of colchicine (0.00, 0.05, 0.10, 0.20 or 0.50% w/v) were applied to the seeds and shoot apical meristems of young seedlings at the fourth leaf-stage. Microscopic studies, flow cytometry analysis and chromosome counting were conducted to select tetraploid nuruozak plants. Furthermore, the effects of ploidy level on the essential oil content and composition and biomass production of nuruozak plants, as well as selected structural and physiological characteristics were studied. Based on the number of the obtained tetraploids, treatment of shoot apical meristems was more efficient than seed treatment. Structural and phytochemical characteristics, chlorophyll content and photosynthetic rate were affected by the increase in ploidy level. In addition to the higher potential in biomass production, tetraploid plants produced eight new compounds which were absent in diploids.     

Induction of tetraploid poplar and black locust plants using colchicine: chloroplast number as an early marker for selecting polyploids in vitro

Tetraploid plants were produced by inducing chromosome doubling using colchicine in in vitro shoot tips of poplar and black locust clones. Many of the plants treated with colchicine showed modified morphological characteristics like stunted growth, thicker leaves and modified leaf morphology. The counting of chloroplast number in the epidermal guard cells of stomata was used for the rapid screening of tetraploids. The differences in mean chloroplast numbers between diploid and tetraploid plants were highly significant. For all plants tested, the tetraploid genotype had almost double the number of chloroplasts per guard cell compared to the diploid origin. Some plants were further analysed by flow cytometry to verify their ploidy status that was determined by chloroplast numbers. The results of this study demonstrated for the first time that chloroplast counting in poplar and black locust could be an effective and reliable method for pre-screening large numbers of plants for their ploidy level. The protocol might be applicable in a wide scope of breeding programs.     

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.     

Somatic chromosome number doubling of selected potato genotypes using callus culture or the colchicine treatment of shoot nodes in vitro

Experiments were carried out to double the somatic cell chromosome numbers of a monoploid and dihaploid of Solanum tuberosum and a genotype of S. circaeifolium subsp. quimense. Colchicine was used in vitro on shoot nodes from which the axillary meristems had been removed. Plants with doubled chromosome numbers were obtained from shoots grown from the tertiary, sub-axillary meristems of all three genotypes. The callus culture of stem and leaf explants was found to produce more shoots with doubled chromosome numbers than the colchicine treatment in the case of the dihaploid and quimense genotypes but no shoots were obtained from callus culture of the monoploid. Fifty-two % of the shoots from the dihaploid and 63% from the quimense clone were ploidy doubled in the case of the best callus culture system. Using a sub-lethal dose of colchicine, the dihaploid yielded 37% ploidy-doubled shoots whereas all the shoots produced from the monoploid were doubled and the quimense clone produced 27% doubled plants. Callus culture was highly dependent upon the type of growth medium and other, unknown, factors. The colchicine treatment, although yielding fewer products, was more reliable for achieving ploidy doubling in selected clones if the number of plants produced is not important.     

In vitro induction of tetraploid plants from diploid Zizyphus jujuba Mill. cv. Zhanhua

Tetraploid plants of Zizyphus jujuba Mill. cv. Zhanhua were obtained with in vitro colchicine treatment. Shoot tips from in vitro-grown plants were treated with five different concentrations of colchicine (0.01, 0.03, 0.05, 0.1, 0.3%) in liquid MS medium (Murashige and Skoog 1962), and shaken (100 rpm) at 25 °C in darkness for 24, 48, 72 or 96 h, respectively. Tetraploids were obtained at a frequency of over 3% by using 0.05% colchicine (48 h, 72 h) and 0.1% colchicine (24 h, 48 h) treatment as determined by flow cytometry. Cytological and morphological evidence confirmed the results of flow cytometric analysis. The chromosome number of diploid plants was 24 and that of tetraploid plants was 48. The stomata sizes of tetraploid plants were significantly larger than those of diploid plants, while the frequency of stomata were reduced significantly. Similarly, the chloroplast number of guard cells of tetraploid plants increased significantly. The selected tetraploid plants were grafted onto mature trees of Z. jujuba Mill. cv. Zhanhua in the field, resulted in thicker stems, rounder and succulent leaves, larger flowers and a delay in florescence time (3–4 days later) than diploid plants.     

Long-term ploidy stability of shoot primordium cultures and produced plants of melon

The chromosome number of cells in the shoot primordium aggregates and produced plants of melon [Cucumis melo L. 'Prince' (2n=2x=24)] was examined. Shoot primordium aggregates were induced from shoot-tips cultured in liquid medium and shaken at low speed (2 rpm). They were maintained by subculturing small pieces (5mm<) every 4 weeks. Shoot primordium aggregates just after induction contained about 97 diploid and 3 tetraploid cells, which was similar to those maintained in shoot primordium cultures for 6 years. This indicates that the ploidy level was maintained stably. On the other hand, plants produced from the shoot primordium aggregates just after induction were either diploid, tetraploid or mixoploid with both diploid and tetraploid cells. These ploidies were again observed among plants produced from shoot primordium cultures that were 2, 3 or 4 years old. A majority of produced plants were diploid while the total frequency of tetraploids and mixoploids was less than 8 of plants produced from all ages. Therefore, the frequency of somaclonal variation with respect to ploidy among plants produced from shoot primordium aggregates is likely to be stable at a low level over the long term.     

不同山茶种质组培条件下染色体倍性的维持与变化

植物染色体的倍性维持和变化受环境因素影响,组培再生过程由于培养条件等因素往往导致染色体的结构和倍性变化。为探索组培条件下山茶种质的倍性变化,该研究利用山茶种质的愈伤组织诱导体系,通过流式细胞仪分析倍性变化情况,并结合秋水仙素处理对组培再生条件下倍性的稳定性和变化进行分析。结果表明:(1)10个山茶种质中6个为二倍体,2个为四倍体,1个为六倍体和1个为十倍体,在组培诱导愈伤及再生过程中不同倍性的种质材料能够保持稳定的倍性。(2)获得了秋水仙素处理的最适诱导条件,即培养基配方为秋水仙素浓度20 mg·L^-1,愈伤增殖培养10 d。(3)对56个独立组织样品(含愈伤和芽)开展了倍性检测发现,有38个组织样品的倍性在1.5～2.5倍之间,11个组织样品产生了低于1.5倍性的特异现象。该研究结果进一步探索了不同山茶种质之间的倍性关系,为山茶属植物的倍性调控和多倍体诱导提供了理论基础。     

Genetic response of Paspalum plicatulum to genome duplication

Paspalum plicatulum is a perennial rhizomatous grass with natural diploid and polyploid cytotypes. In this study, we investigated the occurrence of sequence polymorphisms arising immediately after genome autoduplication in this species. Two mixoploid plants (4C and 7D) were previously obtained through colchicine treatment of seeds generated by open pollination of a diploid plant (H14-2x). Diploid and tetraploid sectors from both mixoploids were dissected to generate two ploidy series (4C-2x/4C-4x and 7D-2x/7D-4x). Molecular fingerprints were generated from the maternal plant H14-2x, both ploidy series (4C-2x/4C-4x and 7D-2x/7D-4x), and a tetraploid plant (C1) produced by selfing 7D-4x. Our results indicate that immediately after polyploidization P. plicatulum suffers genetic rearrangements affecting ~28–38 % of the genome. Band gain and loss were equally prevalent at a statistically significant level. At least 5.62 % of the genome experimented recurrent genetic variation in a non-random basis with a confidence of 94.88 %. A significant proportion of novel bands (36 out of 195; 18.4 %) was detected in the C1 tetraploid plant. Half of these bands were not amplified in either H14-2x or 7D-4x, while the remainders were present in H14-2x but absent in 7D-4x. Our results indicate the occurrence of a considerable number of genetic changes in P. plicatulum immediately after polyploidization, some of which were recurrently detected in different independent events. Moreover, we confirmed that after polyploidization, lost ancestral alleles were spontaneously recovered in further generations, a phenomenon previously reported by other research groups.     

Induction and identification of tetraploids using in vitro colchicine treatment of <Emphasis Type="Italic">Gerbera jamesonii</Emphasis> Bolus cv. Sciella

To induce variation through chromosome doubling in Gerbera jamesonii Bolus cv. Sciella, two-week-old in vitro grown shoots were treated with various concentrations of colchicine (0.01, 0.05, 0.10, 0.50 or 1% w/v) for 2, 4 or 8 h. Treated shoots were then cultured on Murashige and Skoog (MS) medium supplemented with 8.8 μM 6-benzyladenine (BA) and 155 μM adenine sulphate (ADS), and subsequently transferred to fresh MS medium containing 2.85 μM indole-3 acetic acid (IAA) for rooting. When shoots were treated with 0.1% colchicine for 8 h, 64% of recovered plantlets were tetraploid. Ploidy of plantlets was confirmed by flow cytometry, stomatal analysis, and morphological characters. Tetraploid plantlets displayed slower proliferation along with higher vigor and thickened broad leaves. Moreover, tetraploid plants developed larger flowers, longer stalks, and have improved vase-life, all contributing to higher ornamental value of gerbera.     

Production of tetraploid plants of non apomictic citrus genotypes

Ploidy manipulation in Citrus is a major issue of current breeding programs aiming to develop triploid seedless mandarins to address consumer demands for seedless fruits. The most effective method to obtain triploid hybrids is to pollinate tetraploid non apomictic cultivars with pollen of diploid varieties. Such non apomictic tetraploid lines are not found in the citrus germplasm and need to be created. In this work we describe a new methodology based on in vitro shoot-tip grafting combined with treatment of the micro-grafted shoot-tip with colchicine and oryzalin to achieve chromosome doubling and a dechimerization procedure assisted by flow cytometry. Stable tetraploid plants of Clemenules, Fina and Marisol clementines and Moncada mandarin have been obtained directly from shoot tip grafting combined with colchicine and oryzalin treatments or after dechimerization of mixoploids plants (2x–4x). These stable tetraploid plants have been used in 4x × 2x hybridizations, to recover over 3,250 triploid hybrids in 3 years.     

Nuclear instability and chromosomal mosaicism in the polyploids ofTrigonella foenum-graecum

It was observed that the polyploids ofTrigonella foenum-graecum produced by seed treatment with 0·2% colchicine died after two cotyledonary stage, while the ones produced by seedling treatment survived. The root and shoot of seed treated plants were found to be mixoploids. The root tips exhibited 2n to 12n chromosomes and with the passage of time there is a regular decrease in the frequency of cells with lower chromosomes. The frequency of dividing cells decreases considerably towards the end of the 6th day due to the highploidy of most of the ploid plants. In case of seedling treatment the first formed tissue was mixoploid of high level similar to that of seed treated ones but in some cases the growing tip reverted to low level of ploidy which lead to more or less normal growth. Since the difference in the constitution of seed and seedling treated plants lies in their root system, it has been suggested that probably highploidy of root system in the former may be responsible for the 100% mortality of plants.