Reproduction pathway analysis of several Hypericum perforatum L. somaclonal families

Flow cytometry seed screen of mature seeds originating from several in vitro regenerated Hypericum perforatum L. somaclones and their seed progenies were used to screen the ways of reproduction of 4 subsequent generations of several somaclonal families and to search for the relation between the ploidy and prevalent mode of reproduction. The prevalent reproduction pathway of diploid plants was sexual reproduction. Seed samples of plants with higher ploidy levels showed an extensive variation in the mode of reproduction: BII and BIII hybrid formation and/or aposporous pseudogamy including parthenogenetic development of a reduced embryo sac.     

Detection of somaclonal variants in somatic embryogenesis-regenerated plants of <Emphasis Type="Italic">Vitis vinifera</Emphasis> by flow cytometry and microsatellite markers

Flow cytometry and microsatellite analyses were used to evaluate the trueness-to-type of somatic embryogenesis-regenerated plants from six important Spanish grapevine (Vitis vinifera L.) cultivars. Tetraploid plants were regenerated through somatic embryogenesis from all of the cultivars tested with the exception of ‘Merenzao’. In addition, an octoploid plant was obtained in the cv. ‘Albariño’, and two mixoploids in ‘Torrontés’. The most probable origin of these ploidy variations is somaclonal variation. The cv. ‘Brancellao’ presented significantly more polyploids (28.57%) than any other cultivar, but it must be noted that 50% of the adult field-grown ‘Brancellao’ mother plants analysed were mixoploid. Hence, it is probable that these polyploids originated either from somaclonal variation or by separation of genotypically different cell layers through somatic embryogenesis. Microsatellite analysis of somatic embryogenesis-regenerated plants showed true-to-type varietal genotypes for all plants except six ‘Torrontés’ plants, which showed a mutant allele (231) instead of the normal one (237) at the locus VVMD5. There was not a clear relationship between the occurrence of the observed mutant regenerated plants and the callus induction media composition, the developmental stage of the inflorescences, the type of explant used for starting the cultures or the type of germination (precocious in differentiation medium or normal in germination medium) in any of the cultivars tested, except ‘Torrontés’. The mutant plants described herein have been transplanted to soil for future evaluation of putative phenotypic traits of interest. These mutants can be useful both for breeding programs and for functional genomic approaches aimed at increasing knowledge of the biology of grapevine.     

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 regeneration ability of diploid and autotetraploid plants of Cichorium intybus L.

Polyploidy has played a significant role in the evolutionary history of plants and is a valuable tool for obtaining useful characteristics. Because of the novelty of polyploids, comparison of their in vitro culture responses with diploids would be notable. In this study, leaf explants from diploid, autotetraploid and mixoploid plants of Cichorium intybus L. were cultured in vitro on the similar media and under same conditions. The ploidy level of the obtained calluses and regenerants were determined by flow cytometry analysis. The callogenic response of leaf explants cultured on the callus induction medium did not depend on the ploidy level of their parental plants. According to the flow cytometry analysis, the increased ploidy levels (4x) and (8x) were observed in the callus cultures with diploid and tetraploid origin, respectively. A considerable difference was observed between the ploidy level of mixoploid plants and their calluses, indicating the dominance of diploid cells in the callus tissue. The results showed that polyploidy led to the loss of organogenic potential as the tetraploid origin calluses failed to regenerate, while the diploid origin calluses successfully regenerated to whole plants.     

The regeneration and screening of watercress somaclones for resistance to Spongospora subterranea f. sp. nasturtii and measurement of somaclonal variation

A range of watercress (Rorippa nasturtium-aquaticum) explants (stems, hypocotyls, true-leaves, cotyledons and petioles) were tested for their capacity to regenerate adventitious shoots from callus formed using Murashige and Skoog medium containing different concentrations of thidiazuron and 2,4-dichlorophenoxyacetic acid. The highest shoot regeneration rate was a mean of 18 shoots per responding explant from stem callus formed on medium containing 5 μM thidiazuron and 0.05 μM 2,4-dichlorophenoxyacetic acid. A histological study confirmed that shoots originated directly from callus tissue. Twenty five percent of somaclones exhibited somaclonal variation in leaf shape, plant height, axillary branching or ploidy. The variation in 6% of somaclones was heritable to the first selfed generation. A screening protocol was developed to permit the identification of somaclones with increased resistance to the economically damaging watercress root pathogen, Spongospora subterranea f. sp. nasturtii. Although 883 somaclones were screened using this protocol, no significant increase in disease resistance was detected. This revised version was published online in June 2006 with corrections to the Cover Date.     

Ploidy stability of maize anther culture-derived callus lines

Summary Ploidy levels of 26Zea mays L. anther culture-derived callus lines of the F1 hybrids (H99 × Pa91, Pa91 × FR16, and H99 × FR16) were determined at various times after culture initiation using flow cytometry (for 21 lines) or chromosome counting of callus cells or regenerated plants (for the remaining 5 lines). Twenty of the lines remained haploid, whereas 6 were diploid. The results from flow cytometry, after examining the DNA content of 5000 nuclei of each callus line, show that each callus line consisted of homogenous haploid or diploid cells. Thus for diploid callus lines, spontaneous chromosome doubling must have occurred before or in the early stages of androgenesis, before the initiation of callus cultures. These long-term callus cultures (growing for up to 38 mo.) have stably maintained their ploidy levels so it is unlikely that the culture conditions have caused chromosome doubling. The restriction fragment length polymorphism pattern obtained with 52 to 58 markers for each diploid callus line shows that all the diploid lines are homozygous diploid so each originated from a microspore and not from diploid maternal F1 hybrid tissue.     

Induction conditions for somatic and microspore-derived structures and detection of haploid status by isozyme analysis in anther culture of caraway (Carum carvi L.)

Plant regeneration was obtained from cultured anthers and hypocotyl segments of caraway (Carum carvi L.). Microspore- and somatic tissue-derived embryos were compared by observation of the regeneration process under identical induction conditions. Fluorescent microscopy with DAPI staining showed initiation of cell divisions and formation of embryogenic callus and somatic embryos from anther sacs, with production of embryos of both microspore and somatic origin. Induction of somatic embryos from hypocotyl-derived callus was also demonstrated. Isozyme native polyacrylamide gel electrophoresis was used to identify haploids and doubled haploids, and to determine the frequency of spontaneous diploidization of regenerated plants of microspore origin. Donor plants (2n = 20) and their anther-derived derivative plants (n = 10, 2n = 20, 4n = 40) in callus stage or leafy rosette stage were compared. The esterase (EST) band patterns of regenerated plants differed from the heterozygous parental material, suggesting that the regenerated plants were microspore-derived haploid/doubled haploid plants. The similar profile of EST bands between the diploid anther-derived plants and a sample of the donor plants corresponded to a somatic regeneration pathway. Although the selected induction conditions revealed no preference for induction of microspore embryogenesis, the anther culture protocol established for caraway utilizing isozyme segregating EST loci markers is suitable for DH production.     

Occurrence of chromosomal variations and plant regeneration from long-term-cultured citrus callus

Summary Embryogenic callus of Anliucheng sweet orange (Citrus sinensis Osbeck) is theoretically diploid. However, significant chromosomal variations occurred when the calluses were subcultured and preserved for a long time. Cytological observation revealed a variety of mitotic irregularities underlying the occurrence of chromosomal variations. Despite the ubiquitous existence of chromosomal variations, long-term-cultured calluses were still capable of producing somatic embryos and plants. Interestingly, chromosomal variants were selected against when somatic embryos and plants regenerated from the embryogenic callus. Randomly amplified polymorphic DNA (RAPD) analysis was also carried out to detect DNA sequence variation in regenerated plants derived from the embryogenic callus. No difference in banding patterns was detected. It was clear that the plant regeneration from long-term-cultured callus was inclined to select against somaclonal variations.     

Recovering polyploid papaya in vitro regenerants as screened by flow cytometry

Several protocols have been proposed for in vitro propagation of papaya, either based on somatic embryogenesis or shoot organogenesis. It is well-known that tissue culture-based approaches are frequently associated with somaclonal variation. Whether on the one hand this phenomenon can preclude further stages of in vitro culture, on the other hand it can generate useful genetic variability for crop improvement. However, somaclonal variation analyses are limited in papaya tissue culture. The DNA ploidy level of 250 papaya somatic embryogenesis-derived plantlets from immature zygotic embryos was analyzed by flow cytometry. In vitro-grown and greenhouse seed-derived plantlets were used as diploid standards. Flow cytometry unambiguously evidenced euploid (diploid, mixoploid, triploid and tetraploid) and aneuploid papaya plantlets, indicating that in vitro culture conditions can lead the occurrence of somaclonal variation. Additionally, the two subsequent flow cytometry analyses showed that the DNA ploidy level remained stable in all cloned papaya plantlets during the successive subcultures in the multiplication medium.     

Molecular characterization of UV-treated sugar beet somaclones using RFLP markers

Sugar beet plants regenerated from UV-treated calluses were examined by restriction fragment length polymorphism (RFLP) analysis to determine the extent of somaclonal variation occurring at the DNA level. In total, 50 random sugar beet DNA sequences were used to screen 42 somaclones for genetic alterations. Three polymorphisms were detected among the 7 644 alleles analysed. From these data a mutation frequency of 0.03 ± 0.02% per allele was estimated. This frequency is in agreement with similar studies of somaclonal DNA variation using molecular markers and lies in the upper range of the spontaneous gene mutation frequencies found in plants. The two probegenotype combinations showing independent polymorphisms, were further analysed using the restriction enzymes Bam HI, Eco RI, Eco RV and Hind III. Both polymorphisms are likely to result from structural rearrangements rather than from point mutations. Differences in methylation among 10 of the investigated somaclones were tested for by comparing Hpa II and Msp I generated RFLP patterns. The somaclones showed extensive methylation, but no differences in their degree of methylation. Cytological analysis revealed 34 diploid, 8 tetraploid, but no aneuploid plants.     

Comparative assessment of variation in the USA Arachis pintoi (Krap. and Greg.) germplasm collection using RAPD profiling and tissue culture regeneration ability

Arachis pintoi accessions were used to study genetic diversity using RAPD markers. Concurrently, two tissue culture protocols were evaluated for organogenesis and the capacity to generate somaclonal variation. Data were collected on callus growth, callus weight gain, and number of regenerated plants. Robust RAPD profiles were obtained and eight primers amplified 100 different bands with 98% polymorphisms. The proportion of polymorphic RAPD loci was 89%. Average genetic distance was 0.36 and indicated that a large amount of genetic diversity exists within the germplasm evaluated. Genetic distances were used to prepare a dendogram for the A. pintoi accessions that separated them into four groups. A large degree of variability for callus induction and callus weight gain was observed among the accessions. Shoot regeneration was achieved for several accessions on both media with no structures indicative of somatic embryogenesis detected. Root induction was difficult to obtain, and many shoots died during this process. RAPD band profiles of regenerated tissue culture plants were similar to their parent plants, and therefore no somaclonal variation was evident using these methods.     

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

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

Selection for virus resistance in tomato exposed to tissue culture procedures

Protocols elaborated with the objective of achieving valuable material for selection procedure of variants with virusresistance traits in tomato genotypes are presented. Preliminary results are demonstrated in the domain of testing for variability in somaclones obtained through indirect adventitous organogenesis initiated on leaf explants of cultivated tomato (Lycopersicon esculentum Mill.). Somaclones were grown in greenhouse conditions and variation of their symptoms upon infection with tomato mosaic (ToMV) or cucumber mosaic (CMV) respectively was observed. Tests for resistance to the local isolates of the above cited viruses were performed using enzyme linked immunosorbent assay and back inoculation onto diagnostic plants. Screening data are presented. Desirable variants were selected from cultivars ‘Moneymaker’, ‘Potentat’ and ‘Rutgers’. Some of the ‘Moneymaker’ somaclones exhibited increased tolerance to cucumber mosaic virus, a few seemed to be even fully resistant though most were susceptible as donor plants. The most favourable somaclonal lines are actually further tested and monitored for changes in horticultural characteristics. The described procedure of searching for resistance trait in specific pathogen-free (SPF) plants regenerated from infected tissue looks promising and thus can serve as aid in attaining appropriate objectives of breeding programme. Additionaly experiments were initiated to obtain somaclones from cultivars ‘Beta’, ‘Krakus’ and Stevens Rodade hybrid via regeneration of isolated protoplasts. To this end the callus stage was obtained from all donors.     

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.     

Haploid callus and regeneration of plants from anthers of Digitalis purpurea L.

Summary Production of callus from anthers of D. purpurea was obtained on several basal media supplemented with various amounts of auxins. Chromosome counts showed that the callus produced was haploid when the anthers 1) were of a dark-brown to black color, and 2) were cultured in the late tetrad stage of microspore development. Subsequent differentiation to plants at high frequencies was possible only 1) when the anthers had been cultured on the medium of Nitsch and Nitsch (Science 163, 85–87; 1969) supplemented with 5 mg/l 2,4-dichlorophenoxyacetic acid (2,4-D), 2) when the callus was transferred to the same medium but without 2,4-D, and 3) when it was cultured under continuous light from fluorescent lamps. Proliferation of the callus and regeneration of plants did not diminish through as many as 20 subcultures. The high frequency of regenerates permits the propagation of a distinct geno-type to a virtually unlimited number of plants. Diploid plants were obtained when the anthers had been cultured in the dark. Tetraploid plants were regenerated by callus from anthers which had been cultured in light. When the time of 2,4-D treatment was shortened a few haploid plants were produced which however did not survive transfer to soil. Cytological observations demonstrated that regeneration started from haploid callus, leading to intermediate degrees of ploidy and finally to diploid plants. Most of the regenerated plants were euploid and flowered and fruited normally under greenhouse and field conditions. If the anther-derived callus was cultured on the medium of Nitsch and Nitsch supplemented with 2.2 mg/l kinetin, plants regenerated only under photoperiodic conditions of 16 h light at 28° and 8 h dark at 20° but the survival was lowered to one third. These plants had a different leaf and flower morphology as compared to the control without kinetin and to the starting material, but their progeny was again essentially normal.     

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.     

Detection of somaclonal variation of cotton (Gossypium hirsutum) using cytogenetics, flow cytometry and molecular markers

Two protocols of plant regeneration for cotton were adopted in this study, namely, 2, 4-D and kinetin hormone combination and IBA and kinetin hormone combination. Twenty-eight embryogenic cell lines via somatic embryogenesis and 67 regenerated plants from these embryogenic calli were selected and used for random amplified polymorphic DNA (RAPD), simple sequence repeat (SSR), chromosomal number counting, and flow cytometric analysis. The roles of RAPD and SSR markers in detecting somaclonal variation of cotton (Gossypium hirsutum L.) were evaluated. Two cluster analyses were performed to express, in the form of dendrograms, the relationships among the hormone combinations and the genetic variability. Both DNA-based techniques were able to amplify all of the cell clones and regenerated plantlets genomes and relative higher genetic variation could be detected in the culture type with 2, 4-D and kinetin hormone combination. The result suggested that 2, 4-D and kinetin hormone combination could induce relative high somaclonal variation and RAPD and SSR markers are useful in detecting somaclonal variation of regenerated cotton plants via somatic embryogenesis. Chromosome number counting and flow cytometry analysis revealed that the number of chromosomes and ploidy levels were nearly stable in all regenerated plants except two regenerated plantlets (lost 4 and 5 chromosomes, respectively) which meant that cytological changes were not correlated with the frequency of RAPD and SSR polymorphisms. This result also might mean that the cell lines with variation of chromosome numbers were difficult to regenerate plants.     

芍药花药愈伤组织诱导及体细胞胚发生

以芍药(Paeonia lactiflora)品种粉玉奴花药为外植体,研究不同浓度2,4-D对愈伤组织诱导、体胚发生及植株再生的影响,采用组织细胞学方法观察愈伤组织以及体细胞胚发育过程,采用根尖染色体法鉴定再生植株倍性。结果表明,芍药花药愈伤组织诱导的最适培养基为MS+1 mg·L–1 2,4-D+1 mg·L–1 N...     

药物诱导玉米孤雌生殖植株的倍性变异

实验结果表明,孤雌生殖植株根尖体细胞以二倍体细胞最多,占６８．９％,其次为非整倍体细胞,占２８．７％,其他异倍体和单倍体细胞极少（２．４％）。Ｐａ１植株可分为二倍体和混倍体两类,以二倍体细胞占绝对多数的混倍体植株最多,为８３．５％,这些植株生长发育和结实均正常。在花粉母细胞中正常二倍体频率比根尖体细胞明显提高,提高频率为３５．３一５９．６％,不同材料之间趋势一致。讨论了体细胞染色体变异的来源及其能否延续到生殖细胞。     

Somaclonal variation — a novel source of variability from cell cultures for plant improvement

Summary It is concluded from a review of the literature that plant cell culture itself generates genetic variability (somaclonal variation). Extensive examples are discussed of such variation in culture subclones and in regenerated plants (somaclones). A number of possible mechanisms for the origin of this phenomenon are considered. It is argued that this variation already is proving to be of significance for plant improvement. In particular the phenomenon may be employed to enhance the exchange required in sexual hybrids for the introgression of desirable alien genes into a crop species. It may also be used to generate variants of a commercial cultivar in high frequency without hybridizing to other genotypes.