Ploidy levels of plants regenerated from mixed ploidy maize callus cultures

Summary Haploid and diploid anther-derivedZea mays callus lines were treated with the antimicrotubule herbicide pronamide to produce mixed ploidy callus as determined by flow cytometry. The ploidy levels of the plants regenerated from the callus were determined by counting the leaf epidermal guard cell chloroplast numbers. The proportion of diploid regenerated plants was somewhat lower than the proportion of diploid cells of the callus. The diploid plants regenerated somewhat faster than the haploids. The proportion of tetraploids regenerated from the pronamide treated diploid callus, which originated by spontaneous chromosome doubling, was much lower than the proportion of cells indicating that tetraploid cells survive or regenerate plants at a lower frequency than diploid cells.     

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 regeneration and cytological characterization of shoots from leaf explants of three accessions of Solanum commersonii

In vitro culture of explants were used to apply genetic or cell engineering techniques to the sexually incompatible potato relative Solanum commersonii (2n=2x=24) Three accessions of S. commersonii were tested for regeneration from leaf explants using six different protocols. A two step-regeneration procedure gave the best results. Genetic variability for regeneration ability was found between accessions, and between clones within accessions. The accession PI 472834 regenerated at highest frequency. Clones with high regeneration ability were selected. Approximately 60% of regenerated plants were diploids and 40% were tetraploids. A very low frequency of chimeras was found. Leaf shape and chloroplast counts in guard cells were shown to be quick and reliable methods for estimating ploidy levels. Use of the diploid and tetraploid regenerants obtained for potato breeding is discussed.Abbreviations BAP 6-benzylaminopurine - EBN Endosperm Balance Number - GA₃ gibberellic acid - IAA indole-3-acetic acid - MS Murashige and Skoog - NAA 1-naphthalene-acetic acid - ZEA zeatin     

Chromosome doubling of 2x Solanum species by oryzalin: method development and comparison with spontaneous chromosome doubling in vitro

A potato breeding scheme implies the possibility of ploidy level manipulation either by reducing the chromosome number of cultivars from 48 to 24 to be able to cross them with diploid related species or by doubling diploid material to reach the generally optimal tetraploid level. In vitro spontaneous chromosome doubling is widely used but can lead to somaclonal variation. Since oryzalin has proven to be efficient as a chromosome doubling agent on potato cell suspension cultures, we tried this herbicide on various Solanum species and interspecific diploid hybrids. A 24 h dip in a 28.8 M aqueous oryzalin solution applied on apical buds was the most efficient treatment in terms of tetraploid plant production (mean = 4.1 tetraploid plants for 10 treated buds over 4 genotypes). However 50–100% of the regenerated tetraploid plants acclimatized after in vitro treatment proved to be chimaeric. Consequently, a selection procedure in the progeny was necessary to obtain real and stable doubled clones and final yields were low. This technique is easy to apply and could be a good alternative to chromosome doubling by spontaneous in vitro regeneration in the case of refractory genotypes especially where somaclonal variation is problematic. Percentage of tetraploids among the regenerated plants varied from 6 to 29% with the oryzalin doubling technique while it varied from 20 to 78% by in vitro spontaneous doubling for five diploid genotypes. An observation of the progeny indicated that chimaeras were more frequent using oryzalin (50–100% of the initially supposed tetraploid plants) than when chromosomes doubled spontaneously (4–67% of the initially supposed tetraploid plants).     

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.     

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.     

Regenerative callus of <Emphasis Type="Italic">Dianthus</Emphasis> ‘Telstar Scarlet’ showing mixoploidy produce diploid plants

Highly regenerative callus was isolated from the base of adventitious shoots on cotyledon explants of Dianthus hybrida Telstar Scarlet cultured on MS medium supplemented with 1 mg l⁻¹ TDZ and 0.1 mg l⁻¹ NAA. Flow cytometric analysis showed that cotyledon tissue is a mixture of diploid and tetraploid cells. Whereas the regenerative callus consisted of cells showing various ploidy levels of 2C to 16C, their regeneration ability was maintained as long as they were sub-cultured onto fresh media. More than 93% of regenerated shoots from the calluses were diploid. Only a few shoots were revealed as tetraploids and octoploids, suggesting that diploid cells had higher regeneration ability.     

Influence of ploidy level on morphology,growth and drought susceptibility in <Emphasis Type="Italic">Spathiphyllum wallisii</Emphasis>

In this study, we analysed morphological, anatomical and physiological effects of polyploidisation in Spathiphyllum wallisii in order to evaluate possible interesting advantages of polyploids for ornamental breeding. Stomatal density was negatively correlated with increased ploidy level. Stomatal size increased in polyploids. Tetraploid Spathiphyllum plants had more ovate and thicker leaves. The inflorescence of tetraploids had a more ovate and thicker spathum, a more cylindrical spadix and a thicker but shorter flower stalk. Biomass production of the tetraploids was reduced, as expressed by lower total dry weights, and tetraploids produced fewer shoots and leaves compared with their diploid progenitors. Furthermore, tetraploid Spathiphyllum plants were more resistant to drought stress compared with diploid plants. After 15 days of drought stress, diploids showed symptoms of wilting, while the tetraploids showed almost no symptoms. Further, measurements of stomatal resistance, leaf water potential, relative water content and proline content indicated that the tetraploid genotypes were more resistant to drought stress compared with the diploids.     

Relationships among genetic distance,forage yield and heterozygosity in isogenic diploid and tetraploid alfalfa populations

Isogenic diploid and tetraploid alfalfa (Medicago sativa L.) was studied with molecular markers to help understand why diploid performance and breeding behavior does not always predict that of tetraploids. In a previous study of partially heterozygous alfalfa genotypes, we detected a low correlation between yields of isogenic diploid (2x) and tetraploid (4x) single-cross progenies, and genetic distances were more highly correlated with yields of tetraploids than diploids. These differences may be related to the level of RFLP heterozygosity expected among progenies derived from heterozygous parents at the two ploidy levels. The objectives of this study were to determine the relationships among genetic distance, forage yield and heterozygosity in isogenic 2 x and 4 x alfalfa populations. Four diploid genotypes were chromosome doubled to produce corresponding isogenic autotetraploids, and these genotypes were mated in 4 × 4 diallels to produce 6 single-cross families at each ploidy level for field evaluation. Allele compositions of parents were determined at 33 RFLP loci by monitoring segregation of homologous restriction fragments among individuals within progenies, and these were used to estimate RFLP heterozygosity levels for all single-cross progenies at both ploidy levels. RFLP heterozygosity rankings were identical between progenies of isogenic diploid and tetraploid parents; but significant associations (P < 0.05) between estimated heterozygosity levels and forage yield were detected only at the tetraploid level. Since tetraploid families were nearly 25% more heterozygous than the corresponding diploid families, inconsistencies in the association between molecular marker diversity and forage yields of isogenic 2 x and 4 x single crosses may be due to recessive alleles that are expressed in diploids but masked in tetraploids. The gene action involved in heterosis may be the same at both ploidy levels; however, tetraploids benefit from greater complementary gene interactions than are possible for equivalent diploids. Present address: AgResearch Grasslands, New Zealand Pastoral Agriculture Research Institute, Palmerston North, New Zealand     

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 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.     

Determination of the ploidy level in chamomile (Chamomilla recutita (L.) Rausch.) strains rich in alpha-bisabolol

The present study aimed to identify morphological traits whose performance depends on plant ploidy in Chamomilla recutita. Flowerhead diameter, 100-flowerhead weight, 1000-seed weight, pollen grain diameter, stoma length, and number of chloroplasts per guard cell, were examined in 5 tetraploid and 5 diploid strains. Out of these traits, stoma length, number of chloroplasts per guard cell, 100-flowerhead weight, and 1000-seed weight, proved to be significantly higher in tetraploid than in diploid strains, and can be used for indirect identification of tetraploid and diploid genotypes in various developmental stages of this species.     

<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.     

In vitro induction of tetraploids in cassava variety ‘Xinxuan 048’ using colchicine

Polyploids have great breeding value as they could have higher vegetative yields, higher qualities and greater tolerances against biotic and abiotic stresses. This research is focusing on in vitro colchicine-induced tetraploids in cassava. The survival rate of explants decreased with the increase of colchicine concentrations. Based on the survival rate, the treatment with 0.05 g l^?1 colchicine for 2 days was the best protocol for tetraploid induction in the cassava variety ‘Xinxuan 048’. The determination of ploidy levels showed that 28 autotetraploidy and 12 mixoploidy plantlets were obtained from 44 plantlets. Thus, 90.9% of the plants were variants. Significant differences in morphology and anatomy were found between the diploid and tetraploid plants. Tetraploid plants showed better photosynthetic capacities than the original diploid plants. The tetraploid cassava regenerated herein will enrich the germplasm spectrum and open a new arena for breeding novel triploids with elite cultivars by interploid crossing in the future.     

Polyploidization in leaf callus tissue and in regenerated plants of dihaploid potato

Cytological studies on leaf callus cells and regenerated potato plants suggest that it may be possible to utilize somatic chromosome doubling to obtain tetraploids from outstanding dihaploid breeding clones. The ploidy levels found in callus-derived plants were diploid, tetraploid, and octaploid, but the proportion of these was dependent on the donor genotype. L₁ and L₃ germ layers were studied in more than 300 plants; periclinal ploidy chimerism, an undesirable feature of colchicine doubling, was not found. Leaf callus was more efficiently induced using NAA than 2, 4-D as an auxin source in the Murashige and Skoog medium. A high proportion of dividing cells in young calli were polyploid. The frequency of doubled and octaploid plants regenerated was significantly dependent on donor genotype. The extent of polyploidization was marginally higher after callus growth on a medium containing 2, 4-D than in a medium containing NAA. In some genotypes the chromosome numbers of regenerated plants were variable, being less than tetraploid (mixohypotetraploid). After tuber propagation, the original ploidy level was maintained although mixohypotetraploidy persisted. In a few somatically doubled clones, male fertility was tested and found to be satisfactory with respect to seed-setting.     

Why only tetraploid Solidago gigantea (Asteraceae) became invasive: a common garden comparison of ploidy levels

Many studies have compared the growth of plants from native and invasive populations, but few have considered the role of ploidy. In its native range in North America, Solidago gigantea Aiton (Asteraceae) occurs as a diploid, tetraploid and hexaploid, with considerable habitat differentiation and geographic separation amongst these ploidy levels. In the introduced range in Europe, however, only tetraploid populations are known. We investigated the growth performance and life history characteristics of plants from 12 European and 24 North American (12 diploid, 12 tetraploid) populations in a common garden experiment involving two nutrient and two calcium treatments. Twelve plants per population were grown in pots for two seasons. We measured 24 traits related to leaf nutrients, plant size, biomass production and phenology as well as sexual and vegetative reproduction. Native diploid plants had a higher specific leaf area and higher leaf nutrient concentrations than native tetraploids, but tetraploids produced many more shoots and rhizomes. Diploids grown with additional calcium produced less biomass, whereas tetraploids were not affected. European plants were less likely to flower and produced smaller capitulescences than North American tetraploids, but biomass production and shoot and rhizome number did not differ. We conclude that a knowledge of ploidy level is essential in comparative studies of invasive and native populations. While clonal growth is important for the invasion success of tetraploid S. gigantea, its potential was not acquired by adaptation after introduction but by evolutionary processes in the native range.     

Morphological, physiological, cytological and phytochemical studies in diploid and colchicine-induced tetraploid plants of Echinacea purpurea (L.)

Echinacea purpurea (L.) is one of the important medicinal plant species. To obtain the tetraploid plants of Echinacea purpurea with improved medicinal qualities, the root tips of two true leaves seedlings were imbibed in 0.25 % (w/v) colchicine solution for 24, 48, 72, 96 and 168 h. The ploidy level of plants was determined by chromosome counting of root tip cells, and confirmed by flow cytometric analysis. Tetraploid induction occurred in seedlings treated for 24, 48 and 72 h at colchicine solution. The morphological, physiological, cytological, and phytochemical characteristics of diploid and colchicine-induced tetraploid plants were compared. Results indicated that tetraploid plants had considerable larger stomata, pollen grain, seed and flower. Moreover, chloroplast number in guard cells, amount of chlorophyll (a, b, and a + b), carotenoids as well as width and thickness of leaves were increased in tetraploids. However, stomata frequency, leaf index, plant height, and quantum efficiency of photosystem II in tetraploid were lower than diploid plants. High-performance liquid chromatography analysis showed that leaves of the tetraploid plants had more cichoric acid (45 %) and chlorogenic acid (71 %) than diploid plants. It was concluded that morphological and physiological characteristics can be used as useful parameters for preliminary screening of putative tetraploids in this species.     

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.     

Ploidy doubling by in vitro culture of excised protocorms or protocorm-like bodies in <Emphasis Type="Italic">Phalaenopsis</Emphasis> species

Endopolyploidy was observed in the protocorms of diploid Phalaenopsis aphrodite subsp. formosana with ploidy doubling achieved by in vitro regeneration of excised protocorms, or protocorm-like bodies (PLBs). Thirty-four per cent of the PLBs regenerated from the first cycle of sectioned protocorms were found to be polyploids with ploidy doubled once or twice as determined by flow-cytometry. The frequency of ploidy doubling increased as the sectioning cycles increased and was highest in diploid followed by the triploid and tetraploid. Regeneration of the endopolyploid cells in the tissue of the protocorms or PLBs is proposed as the source of the development of ploidy doubled plantlets. The frequency of ploidy doubling was similar in seven other Phalaenopsis species, although the rate of increase within cycles was genotype specific. In two species, a comparison of five parameters between 5-month-old diploid and tetraploid potted plants showed only the stomata density differed significantly. The flowers of the tetraploid plant were larger and heavier than those of the diploids. This ploidy doubling method is a simple and effective means to produce large number of polyploid Phalaenopsis species plants as well as their hybrids. The method will be beneficial to orchid breeding programs especially for the interspecific hybridization between varieties having different chromosome sizes and ploidy levels.     

Regeneration of plants from protoplasts of rapid cycling Brassica oleracea L.

Rapid cycling Brassica species have great potential in plant genetic research because of their short life cycles and their minimal space requirements. Rapid cycling B. oleracea can be grown with up to six generations per year. Protoplast culture of this genotype can be applied for gene transfer by direct DNA uptake and by protoplast fusion. We here report on fast regeneration of flowering plants from protoplasts of rapid cycling B. oleracea. Regeneration frequencies of 27–65% were achieved with multiple shoots developing from individual calli. The regenerated plants were grown to maturity, and flowering and other morphological characteristics were monitored. The regenerants flowered within a similar time frame as plants grown from seeds. The ploidy level of regenerated and seed-grown plants was measured by flow cytometry. Many (20–45%) of the regenerants were tetraploid. Although only few seeds could be obtained from the tetraploids, large numbers of seeds with good germination were recovered from the diploid regenerants.Abbreviations MS-3,0 Murashige and Skoog medium containing 3% sucrose and no growth regulators - MES 1-morpholino-ethane sulfonate