Heterozygous diploid plants regenerated from anther culture of F1 rice plants

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

Breeding for nematode and virus resistance in potato via anther culture

Summary In Solanum tuberosum the production by parthenogenesis of 2x plants with 24 chromosomes, and the regeneration of microspores of such dihaploids to yield monohaploid (1x) plants is reproducibly possible, at least for some specific genotypes. Experiments are described using tissue culture techniques in an applied breeding program with the main aim of increasing the level of resistance to the potato cyst nematode Globodera pallida (Stone) and to the potato viruses X, Y and leaf roll. These resistances follow quantitative as well as qualitative modes of inheritance. Using anther culture it is demonstrated that doubled monohaploid clones can be produced which possess the resistance in the homozygous condition. In both ways of inheritance the ratio of resistant clones is rather high. The genotype of the anther donor plant has, however, a strong influence on the total number of androgenetic plants which can be regenerated. Therefore, experiments were initiated with the aim of integrating this capacity for regeneration (tissue culture ability) into valuable genotypes. The results show that the potentiality for regeneration is under genetic control and can be utilized by combination breeding. Its inheritance and physiological basis, as well as the behaviour of complete homozygous clones, is discussed.Dedicated to Prof. Dr. Joseph Straub on the occasion of his 70. birthday     

Characterization of root clones obtained after transformation of monohaploid and diploid potato genotypes with hairy root inducing strains of Agrobacterium

A procedure for transformation of monohaploid and diploid potato genotypes through infection of stem internodes with hairy root inducing strains of Agrobacterium is described. Hairy roots induced by A. rhizogenes strain LBA9402 and A. tumefaciens strain LBA1020, both containing the Ri1855 plasmid, were analysed for phenotype, growth and development, and opine expression. The ploidy level of the hairy roots was determined by measurements of the nuclear DNA content and the chromosome number. The genotypes of potato (8 monohaploids, 2 diploids) greatly differed in their response to transformation, i.e. the frequency of stem internodes with primary hairy roots, the number of roots per internode and their phenotype. Transformation efficiency was lower in most of the monohaploid genotypes as compared to that in diploid genotypes. Hairy root clones could be established in 4 of the 8 monohaploid genotypes and in both diploid genotypes after subculturing of primary hairy roots. Hormone autotrophy was observed in all the root clones. The root clones varied in their phenotype and opine expression; opine expression was found in only 50% of the clones. Twenty-five of the 26 hairy root clones of the diploid genotypes showed only parental (diploid) chromosome number, even after 6 months of culture, suggesting genetic stability during the transformation and in the resulting hairy roots. However, in monohaploid genotypes the hairy root clones were either diploid or tetraploid. The transformation of monohaploid and diploid potato genotypes can be an efficient system for the establishment of a series of genetic marker lines for gene mapping.     

Fate of introduced genetic markers in transformed root clones and regenerated plants of monohaploid and diploid potato genotypes

Summary Agrobacterium transformation of stem internodes of four monohaploid (839-79, 849-7, 851-23, 855-1) and two diploid (M9 and HH260) potato genotypes using hairy root-inducing single (LBA 1020, LBA 9365, LBA 9402) and binary (LBA 1060KG) vectors is reported. Various media and successive culture steps were tested for plant regeneration from different transformed root clones. The fate of introduced genetic markers in root clones and regenerated plants (hairy root phenotype, hormone autotrophy, opine production, kanamycin resistance, -glucuronidase activity), the ploidy stability and protoplast yield were analysed. The transformation efficiency of stem internodes (hairy root production) and the regeneration capacity of the transformed root clones greatly differed within and between the various potato genotypes. The regenerated plants obtained after transformation with both types of vectors often showed the absence of one or more genetic markers. However, transformation with the binary Agrobacterium vector generally resulted in the stable presence of the opines in all transformed root clones and most regenerated plants. In HH260, transformation efficiency, plant regeneration of transformed root clones, protoplast yield and ploidy stability were the highest as compared to the other genotypes. The application of these transformed plants as marker lines in gene mapping and gene expression studies is indicated.     

Genetic selection and liquid medium conditions improve the yield of androgenetic plants from diploid potatoes

Summary Solatium tuberosum L. diploid strains with superior androgenetic capacity have been selected for from androgenetic progenies of unselected diploid material. The paper also demonstrates that the use of a liquid medium for culturing potato anthers, instead of the conventional solid agar plates, improves the yield of androgenetic embryoids. The new method, associated with two successive cycles of selection for superior androgenetic response, allows the induction and regeneration of microspore derived plants on a large scale. The best genotype (clone 21 in this paper) regenerates androgenetic plants with a frequency around 30 per each anther plated. Over 80% of the regenerated plants are diploid. It is suggested that the androgenetic embryoids mainly originate from unreduced microspores by a mechanism which maintains a heterozygous or a partly heterozygous genetic situation.     

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

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

Callus Induction,Plant Regeneration and an Assessment of Cytological Variation in Regenerated Plants of Lolium multiflorum L.

Callus cultures were initiated from roots, apical meristem tips and leaf explants of several genotypes of Lolium multiflorum L. (Italian Ryegrass). Genotypes were selected which showed a high frequency of callus initiation and from which plants could be regenerated. Plants could be routinely produced from root-derived callus of only one of the genotypes tested. The selected genotypes were still amenable if the temperature and concentration of 2,4-D in the medium were altered. Increase in temperature caused callus from one genotype to give rise to more albino regenerants. Callus formation and plant regeneration occurred at a higher frequency from diploid than tetraploid explants. All regenerants from the diploid cultures had the 2n = 2x = 14 chromosome number whereas plants regenerated from callus derived from tetraploid cultures lost up to 3 chromosomes.     

Production of potato monohaploids (2n=x=12) through prickle pollination

Summary Data are presented on the potential of gynogenesis for the production of monohaploids and on factors affecting their frequency and relative vigour. Diploid Solanum tuberosum L. and S. tuberosumxS. phureja Juz et Buk hybrids were used as maternal parents and selected S. phureja clones as prickle pollinators with embryo-spot and nodal band as dominant seed and plant marker. About 2 million seeds were screened for absence of embryo-spot. After raising plants from phenotypically spotless seeds, further screening for absence of nodal bands and for ploidy level was carried out. Finally more than 500 monohaploid plants from three genetically different groups of maternal parents were obtained. Frequency and vigour of the monohaploids were clearly dependent on their maternal genotypes. The data also indicated an effect of the pollinator genotype, the physiological stage of the maternal plant and the environment on monohaploid frequency. On the basis of these results the possibility of breeding for a higher monohaploid production rate and for more stable and vigorous monohaploids is discussed. Furthermore, gynogenesis and androgenesis are compared. It is suggested that both should be used in order to obtain monohaploids from sufficiently various diploid breeding material.     

Chromosome doubling in monohaploid and dihaploid potatoes by regeneration from cultured leaf explants

Plants were regenerated from cultured excised leaf segments of monohaploid (2n=x=12) and diphaloid (2n=2x=24) potato (Solanum tuberosum L.) and a sample has been studied cytologically. In the case of monohaploids, a single leaf regeneration cycle resulted in almost total recovery of doubled monohaploid plants (2n=2x=24), whilst 50% of the plants regenerated from doubled monohaploid leaves had doubled again to the doubled double monohaploid (or homozygous tetraploid, 2n=4x=48) level. Regeneration from dihaploid leaf pieces also gave a good proportion (60%) of doubled genotypes. Very few mixoploids and very few aneuploids were found. These results, together with the general applicability of the method to a large number of potato cultivars, suggest that it can be used as a simple and reliable method of obtaining homozygous tetraploid potatoes.     

Plant regeneration from in vitro culture of anthers of Solanum chacoense Bitt. and interspecific diploid hybrids S. tuberosum L. x S. chacoense Bitt.

Summary Production of plants from cultured anthers of Solanum chacoense clone IP 33, of its interspecific diploid hybrids with S. tuberosum clones IP 354 and IP 372, and of a complex Solanum hybrid containing in its genome S. ajanhuiri is reported. Genotypic differences were found to influence both the induction phase and the regeneration process. Hybrids derived from clone IP 354 of S. tuberosum were much more responsive in culture than hybrids from clone IP 372. Altogether, 507 plants were regenerated and 309 were cytologically analyzed. Of these, 52% were haploid, 47% diploid and 1% mixoploid or tetraploid. A number of diploid plants probably originated from unreduced microspores and some genetic consequences of this event are discussed.     

Phenotypic and cytological variation among plants derived from anther cultures ofLilium longiflorum

Summary Anther culture of the Easter Lily (Lilium longiflorum; 2n=2x=24) was attempted in order to evaluate its potential in generating haploids for the production of hybrid cultivars. The effects of genotype, temperature (low temperature treatment of buds and high temperature treatment of cultures), sucrose concentration and growth regulators were tested. The most important factors for callus induction were the genotype and the presence of 2,4-dichlorophenoxyacetic acid. Pre-treatments at low or high temperature had no apparent effect, while high sucrose concentration was inhibitory. Callus was derived from 28 of the 108 genotypes tested and plants were regenerated. Phenotypic variations were observed among these regenerants. Somatic chromosome numbers were determined in 42 plants derived from 10 donor genotypes. Thirteen plants were diploid and 29 were mixoploid with chromosome numbers ranging from 11 to 26. Four of the mixoploid plants had a high proportion of cells with haploid chromosome numbers, particularly at early stages of development. Meiosis was examined in plants with flower buds. Most plants had 12 bivalents at Metaphase I, but also aneuploids were observed. Other irregularities included bridges and laggards at Anaphase I. The occurrence of high frequencies of haploid cells (up to 80%) in root tips suggests that some plants may be of gametic origin. Research was supported by the Easter Lily Research Foundation, the Ohio Floriculture Foundation, the Gloeckner Foundation and the Oregon Agricultural Experiment Station (technical paper no. 8398).     

Use of SSR markers to determine the anther-derived homozygous lines in coconut

Anther culture was used to obtain dihaploid (DH) coconut plants and their ploidy level was determined by flow cytometric analysis. Simple sequence repeat (SSR) marker analysis was conducted to identify the homozygous diploid individuals. Ploidy analysis showed that 50% of the tested plantlets were haploid and 50% were diploid. Polymorphic fragments of the mother palm and their segregation patterns in anther-derived plantlets were used to determine the origin of the diploid plantlets. Using a diagnostic SSR marker (CNZ43), all the diploid plantlets tested were identified as being derived from microspores (i.e. were homozygous) and were thus candidates for use in coconut breeding programs.     

Desynapsis in diploid and tetraploid clones of ryegrass

Desynapsis is described in diploid and tetraploid plants of perennial ryegrass. The plants were derived by repeated cloning of a single mixoploid (2n=14 and 28) detected among colchicine-treated seedlings. The diploid and tetraploid clones varied in degree of desynapsis, chiasma number, and fertility. The variation among the clones was probably environmental. The progeny of the mixoploid parent included dipoids, tetraploids, and an aneuploid. One diploid and the aneuploid were desynaptic and originated perhaps by selfing. Apparently a single recessive gene determined desynapsis. The role of synaptic genes in controlling the chemical structure and function of nucleoprotein macromolecules is discussed.     

Karyological characterization of sugar beet gynogenetic lines cultured in vitro

Flow cytometry was used to screen ploidy levels in 47 cultured in vitro sugar beet gynogenetic lines of various origin and age, obtained after plant regeneration from unfertilized ovules. When donor plants were diploid, the majority of regenerants were found to have cells with 1C, 2C and 4C relative DNA content (mainly haploid and diploid) and there were large differences in the rate of spontaneous in vitro chromosome doubling between individual homozygous lines. Six ovule-derived lines regenerated from fertile and sterile diploid donors of forty-five lines were solid diploids from the very early stages of their in vitro cultivation, and thus could not be classified as doubled haploids. In the case of tetraploid donor plants, the gynogenetic regenerants demonstrated 2x-ploidy level. The results obtained in chimeric plants with both haploid and diploid cells indicated the possibility to overcome mixoploidy by their re-cultivation through generative shoot tip culture. The flow cytometry method confirmed data obtained by conventional microscopic chromosome counting in dividing leaf cells and was found very useful for screening of a large number of regenerants and for characterizing the process of in vitro gynogenetic lines formation in sugar beet.     

High frequency of tetraploidy in Agrobacterium-mediated transformants regenerated from tuber discs of diploid potato lines

Summary Variations in the ploidy level of 69 transgenic potato (Solanum tuberosum L.) plants regenerated from the tuber discs of 17 diploid lines were studied: 24 plants (35%) were diploid, the other 45 plants (65%) were tetraploid. Seventy-eight control regenerants obtained without Agrobacterium inoculation showed a relatively low tendency to tetraploidization (35%). The results obtained suggested that chromosome doubling occurred frequently in diploid potato lines during the tissue culture process for regeneration. Putative somaclonal changes in in vitro-formed tuber proteins were detected in three out of six transformants by electrophoretic analysis.     

Gametic and somatic embryogenesis through in vitro anther culture of different Citrus genotypes

In vitro tissue culture represents a useful technique for advancing Citrus breeding and propagation. Among in vitro regeneration systems, anther culture is commonly used to produce haploids and doubled haploids for a fast-track producing homozygous lines, in comparison with the traditional self-pollination approach, which involves several generations of selfing. In addition, anthers culture can produce somatic embryos that can also be used for clonal propagation. In this study, two thermal shocks were applied to the anthers of six Citrus genotypes (two clementine and four sweet oranges), just after they were put in culture. The response obtained was different depending on the genotype: both clementines, namely Hernandina and Corsica, produced homozygous and triploid regenerants (microspore-derived embryos), whereas all of the analyzed regenerants from sweet oranges, three cultivars of Tarocco and Moro, produced heterozygous and diploid regenerants similar to the parental genotypes (somatic embryos).     

Comparison of single cell culture derived Solanum tuberosum L. plants and a model for their application in breeding programs

Summary The techniques of microspore and protoplast regeneration starting from dihaploid Solanum tuberosum plants has been improved to such an extent that the production of more than 2000 microspore derived A₁ plant lines and of several hundred protoplast derived plantlets has become possible. Further, from the dihaploid Solanum species S. phureja the regeneration of microspores to plants, and from the species S. infundibuliforme, S. sparsipilum and S. tarijense the regeneration of protoplasts to calluses, has been achieved. The plants descending from the two single cell culture systems are compared with reference to phenotypic markers and economic qualities. Some principles characteristic for either microspore or protoplast derived plants are examined and their significance is discussed. The results are compiled into an extended analytical synthetic breeding scheme based on a stepwise reduction of the autotetraploid to the monohaploid level and a subsequent controlled combination to a new synthetic completely heterozygous tetraploid potato.     

Colchicine, an efficient genome-doubling agent for maize (Zea mays L.) microspores cultured in anthero

The construction of maize genotypes with high haploid induction capacity made it possible to study the effect of colchicine on maize androgenesis in vitro. Anther cultures of three hybrids were treated with 0.02% and 0.03% colchicine for 3 days at the beginning of microspore induction. Colchicine added to the induction medium had no negative influence on the androgenic responses (anther induction, induction of structures of microspore origin and their regeneration ability) of the genotypes examined. However, significantly higher fertility was observed in plants originating from colchicine-treated microspores, especially at 0.03%. Cytological examinations showed that colchicine treatment before the first microspore division efficiently arrested mitosis and resulted in homozygous doubled-haploid microspores. Under the experimental conditions, the antimitotic drug had no later effect on the division symmetry of the microspore nucleus, and unequal divisions remained dominant. Callus formation from the induced microspores seemed to be more typical (ranging between 60–70%), but embryo frequency was increased by approximately 10%, especially at the higher colchicine concentration. These results suggest that the mechanism of colchicine action in premitotic maize microspores may differ from that previously observed in wheat. Received: 15 June 1998 / Revision received: 17 September 1998 / Accepted: 3 December 1998     

Isolation and characterization of diploid clones from adult and newborn rat liver cell lines.

A high frequency of diploid and near-diploid clones were developed from cell lines derived from adult and newborn rat liver using micropipettes. There were some differences in morphology, biochemical properties and growth rate between clones. Cloned cells had low levels of tyrosine transaminase activity, glucose-6-phosphatase activity and albumin content. A diploid clone and pseudodiploid clone derived from adult rat liver cell line were positive for alpha-fetoprotein.     

Production of transgenic diploid <Emphasis Type="Italic">Cucumis melo</Emphasis> plants

Melon (Cucumis melo L.) is considered to be a recalcitrant species for genetic transformation. Additionally, many studies have observed that regenerated transgenic plants are frequently polyploids. Here we have studied several aspects of melon transformation with the aim of improving transformation efficiency and producing diploid transformed plants. The protocol was based on using cotyledon explants from quiescent seeds that retain meristematic cells, which facilitated the regeneration of transformed diploid melon plants. In this study we evaluated the effect of using two different explant types from the proximal portion of melon seeds on the ploidy status (evaluated by flow cytometry) of regenerated plants. We also determined the transformation efficiencies obtained with these types of explants from four different genotypes. Regeneration was obtained from all explant types. Using quiescent seeds the percentage of diploid plants produced ranged from 85.2 to 94.1%, depending on the type of explant. On the other hand, only half of the plants regenerated from older-seed cotyledons (2- or 3-day-old) were diploids. Transgenic plants were produced with variable transformation efficiencies depending on the explant and which of the four melon genotypes was used. The explants with the best behavior produced transgenic plants with the highest efficiencies ever published both, in terms of plants expressing the visual marker transgenes (ranging from 4.5 to 15.4%) and the number of rooted plants in selective medium (ranging from 1.3 to 3.8%). Although the transformation efficiencies were still relatively low, they were consistent for the four very different melon genotypes tested. Furthermore, at least 85% of plants produced were diploid.