Ploidy of somatic embryos and the ability to regenerate plantlets in melon (Cucumis melo L.)

Summary The number of chromosomes in cells of callus, somatic embryos and regenerated plantlets during somatic embryogenesis were examined in two cultivars of melon (Cucumis melo L.). Somatic embryos were diploid (50.0%/32.1%), tetraploid (38.5%/57.5%) and octoploid (11.5%/10.4%) whereas in callus cells diploidy (41.9%/43.3%), tetraploidy (27.9%/25.8%), octoploidy (11.6%/15.5%) and a low frequency of other types of ploidy and aneuploidy were observed. Mixoploid somatic embryos were not observed. These results suggest that the somatic embryos were selectively differentiated from diploid, tetraploid and octoploid cells, and that endopolyploidization of cultured cells occurred before the start of cell division leading to somatic embryogenesis. The ratio of diploid to tetraploid (1.30/0.55) in somatic embryos was less than that in callus cells (1.50/1.68) while ratios of diploid to octoploid (4.35/3.09) and tetraploid to octoploid (3.35/5.52) in somatic embryos were greater than those in callus cells (3.61/2.80 and 2.40/1.67). Therefore, it appears that the ability of callus cell to differentiate into somatic embryos increases in the following order: octoploid < diploid < tetraploid. Regenerated plantlets were diploid (65.5%/55.1%) and tetraploid (34.5%/44.9%). No octoploid plantlets were observed. The ratio of diploid to tetraploid in regenerated plantlets (1.72/1.23) was greater than that in somatic embryos. Therefore, it appears that the ability of somatic embryos to develop into plantlets increases in the following order: octoploid < tetraploid < diploid.     

Molecular,cytological and morpho-agronomical characterization of hexaploid somatic hybrids in Medicago

Somatic hybrid plants produced by protoplast fusion between tetraploid Medicago sativa (2n= 4x=32) and the diploid species Medicago coerulea (2n= 2x=16) have been RFLP fingerprinted to establish their nuclear composition. Although all of the chromosomes were present, molecular analysis revealed an incomplete incorporation of the alleles of the diploid parent in the fusion products. In the polycross progeny the alleles of both parents segregated in a Mendelian mode. Cytological observations indicated that in the somatic hybrid population minor abnormalities are present; these are restricted mainly to the formation of univalents and lagging chromosomes. Meiosis appeared to be more stable than has been previously reported in the hexaploids of alfalfa. The somatic hybrids grown in the field had a rather vigorous aspect, particularly with respect to the vegetative organs. Forage yield was comparable to that of thmore productive parent. The results are discussed with a view to utilizing the somatic hybrids as starting material for breeding alfalfa at the hexaploid level.This paper was supported by the National Research Council of Italy, Special Project RAISA, Sub-project No.2 paper No. 1911     

Improved isolation of dihaploidsolanum tubersoum protoplasts and the production of somatic hybrids between dihaploidS. tuberosum andS. brevidens

Summary A modified protoplast isolation technique, applicable to a range of dihaploidSolanum tuberosum genotypes, has been developed. A combination of high calcium and high pH was used to fuse mesophyl protoplasts of dihaploidS. tuberosum (PDH40) and the diploid wild speciesS. brevidens. Large numbers of colonies were obtained after fusion and putative hybrids selected on the basis of phenotype from regenerated shoots. From these, 11 somatic hybrid plants have been identified by their isoenzyme patterns and morphologic characteristics. Four of these hybrids had the expected chromosome number of 48. The approach of mass culture after fusion followed by selection of hybrids from regenerated shoots and the application of somatic hybridization to potato breeding are discussed.     

Production of somatic hybrids by electrofusion in Solanum

Summary Conditions are described for large scale electrofusion of mesophyll protoplasts of dihaploid S. tuberosum with those of diploid S. brevidens. Overall fusion frequencies of 20%–30% were achieved, and following fusion, large numbers of protoplast-derived calli were obtained. Putative somatic hybrid plants were selected from the regenerated shoots by examining their morphological characteristics. Twenty-one somatic hybrids were confirmed by isoenzyme analysis and six somatic hybrids were further confirmed by Southern hybridization. Tetraploid hybrids were obtained, but cytogenetic studies indicated that more of the regenerated hybrids were hexaploid than had previously been found following chemical fusion of the same partners. Some advantages of electrofusion over chemical fusion are discussed.     

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.     

Ploidy of somatic nuclei during life cycle of Myxosporean (Myxozoa, Grasse, 1970)

Results of the author's investigation on the ploidy of somatic nuclei in various myxosporean species, throughout different stages of their complicated life cycles, have been summarized. A comparative analysis of data on the ploidy in somatic and generative nuclei of Kudoa quadratum (Multivalvulida) has been given for the first time. Representatives of the Multivalvulida order differ from those of the earlier studied Bivalvulida order in the structure of their myxospore. It has been found that during the myxosporean life cycle alteration of haploid, diploid and polyploid somatic nuclei occurs, and that differentiation of somatic cells and nuclei takes place in both haploid and diploid phases of the life cycle.     

Somatic hybridization in citrus: An effective tool to facilitate variety improvement

Summary Citrus somatic hybridization and cybridization via protoplast fusion has become an integral part of citrus variety improvement programs worldwide. Citrus somatic hybrid plants have been regenerated from more than 200 parental combinations, and several cybrid combinations have also been produced. Applications of somatic hybridization to citrus scion improvement include the production of quality tetraploid breeding parents that can be used in interploid crosses to generate seedless triploids, and the direct production of triploids by haploid + diploid fusion. Applications of somatic hybridization to citrus rootstock improvement include the production of allotetraploid hybrids that combine complementary diploid rootstocks, and to combine citrus with sexually incompatible or difficult to hybridize genera that possess traits of interest for germplasm expansion. A few somatic hybrid tetraploid breeding parents have flowered, are fertile, and are being used as pollen parents to generate triploids. Several allotetraploid somatic hybrid rootstocks are performing well in commercial field trials, and show great promise for tree size control. Seed trees of most of these somatic hybrid rootstocks are producing adequate nucellar seed for standard propagation. Somatic hybridization is expected to have a positive impact on citrus cultivar improvement efforts.     

Factors influencing <Emphasis Type="Italic">in vitro</Emphasis> regeneration from protoplasts of wild cotton (<Emphasis Type="Italic">G. klotzschianum</Emphasis> A) and RAPD analysis of regenerated plantlets

Plants of a diploid wild cotton species (G. klotzschianum A.) were efficiently regenerated from protoplasts isolated from immature somatic embryos and suspension cultures by studying various factors affecting regeneration. Purified protoplasts were cultured with the density of 2–10×10⁵ ml⁻¹, and the medium was k₃ inorganic salts with modified KM₈P organic compositions, supplemented with several combinations of PGRs. Calluses were formed from protoplasts of suspension cultures and immature somatic embryos. The influences of carbon sources and GA₃ on callus differentiation and somatic embryo germination were analyzed. Somatic embryos germinated normally and formed regenerated plantlets. Regenerated plantlets were transferred to the soil and seeds were obtained. Random amplified polymorphic DNA (RAPD) analysis using 80 arbitrary oligonucleotide 10-mers showed 23 primers that gave 74 clear reproducible bands, with amplification products being monomorphic for 14 tested plantlets. A total of 1036 bands obtained exhibited no aberration in RAPD banding patterns in the 14 plants. Plants regenerated via somatic embryogenesis from the diploid cotton protoplasts have genetic homogeneity.     

Distinguishing allozymes and isozymes of phosphoglucoisomerases by electrophoretic comparisons of pollen and somatic tissues

The different electrophoretic patterns of dimeric phosphoglucoisomerases extracted from haploid pollen and diploid somatic tissues of plants may be used to distinguish allozymes and isozymes. The analysis depends on the presence of two alleles at each locus in somatic tissues but only one or the other allele in pollen grains. Consequently, in heterozygotes, heterodimeric allozymes can be identified because they are formed in stems and leaves but not in pollen. The procedure is described in enzymes extracted from the diploid annual plant Clarkia dudleyana, which possesses three gene loci for PGI subunits. Comparison of the electrophoretic patterns of stem and pollen extracts makes it possible in many cases to identify allelic state without breeding tests. The technique also is likely to be useful in the interpretation of zymograms of other multimeric enzymes coded by more than one gene locus.     

Contrasting power of the factors for fission and sexuality in a polyploid planarian

One of the biotypes of the planarian Dugesia benazzii is triploid in the somatic line, hexaploid in the female line owing to a chromosome set doubling, and diploid in the male line due to a haploid set elimination. In a population of this biotype only 50% of the oocytes are hexaploid, the others being triploid as a results of the lack of set doubling; the male line is always diploid. After a long period of laboratory culture most of the individuals became asexual and fissiparous. Almost all the oocytes of the few specimens which have remained sexual showed triploid complement; B-chromosomes also appeared. These events represent the manifestation of a new genetic background which act upon the two germ lines in different ways and moments. These topics are discussed.     

Evidence for non-disomic inheritance in a Citrus interspecific tetraploid somatic hybrid between C. reticulata and C. limon using SSR markers and cytogenetic analysis

Artificial tetraploid somatic hybrids have been developed for sterile triploid citrus breeding by sexual hybridization between diploid and tetraploid somatic hybrids. The genetic structure of diploid gametes produced by tetraploid genotypes depends on the mode of chromosome association at meiosis. In order to evaluate tetraploid inheritance in a tetraploid interspecific somatic hybrid between mandarin and lemon, we performed segregation studies using cytogenetic and single sequence repeat molecular markers. Cytogenetic analysis of meiosis in the somatic hybrid revealed 11% tetravalents and 76% bivalents. Inheritance of the tetraploid hybrid was analyzed by genotyping the triploid progeny derived from a cross between a diploid pummelo and the tetraploid somatic hybrid, in order to derive genotypes of the meiospores produced by the tetraploid. A likelihood-based approach was used to distinguish between disomic, tetrasomic, and intermediate inheritance models and to estimate the double reduction rate. In agreement with expectations based the cytogenetic data, marker segregation was largely compatible with tetrasomic and inheritance intermediate between disomic and tetrasomic, with some evidence for preferential pairing of homoeologous chromosomes. This has important implications for the design of breeding programs that involve tetraploid hybrids, and underscores the need to consider inheritance models that are intermediate between disomic and tetrasomic.     

Allotriploid somatic hybrids of diploid tomato (Lycopersicon esculentum Mill.) and monoploid potato (Solanum tuberosum L.)

Allotriploid somatic hybrids were obtained from fusions between protoplasts of diploid tomato and monohaploid potato. The selection of fusion products was carried out in two different ways: (1) The fusion of nitrate reductase-deficient tomato with potato gave rise only to hybrid calli if selection was performed on media lacking ammonium. Parental microcalli were rarely obtained and did not regenerate. (2) The fusion of cytoplasmic albino tomato with potato gave rise to albino and green hybrid calli and plants. Allotriploids were identified from the two somatic hybrid populations by counting chloroplast numbers in leaf guard cells and by flow cytometry of leaf tissue. Although some pollen fertility of allotriploids and pollen-tube growth of tomato, potato andLycopersicon pennellii into the allotriploid style were observed, no progeny could be obtained. The relevance of allotriploid somatic hybrids in facilitating limited gene transfer from potato to tomato is discussed.     

Origin of plantlets and callus obtained from chile pepper anther cultures

Summary Androgenesis occurred from chile pepper (Capsicum annuum L.) anthers incubated in a continuous warm environment (29° C) with continuous light. Forty plantes and embryoids were retrieved from anther cultures and anllyzed for isozyme markers. Of these, 35 exhibited a single allele for markers suggesting microspore origin, while 5 were heterozygous indicating somatic tissue origin. Chromosome numbers were confirmed for 21 plantlets, of which 16 were haploid and 5 were diploid. However, two plants exhibited a single allele for an isozyme marker but possessed the diploid chromosome number, suggesting spontaneous doubling. Anther cultures also produced callus. Nearly 92% of the slow-growing calli sampled were heterozygous for the isozyme marker, suggesting somatic tissue origin. More than 46% of the fast-growing calli exhibited only one allele for the marker, indicating microspore origin. Callus did not regenerate plantlets. The occurrence of both heterozygous and homozygous diploid plantlets from pepper anther cultures has important implications for applied breeding programs.     

Somatic embryogenesis and plant regeneration in Cyphomandra betacea (Cav.) Sendt

Callus cultures with globular proembryogenic structures were induced from zygotic embryos and hypocotyl segments of Cyphomandra betacea on MS medium supplemented with 2,4-D. Proembryogenic structures produced somatic embryos and plantlets on regulator-free basal medium. Pieces of embryogenic callus subcultured on medium with the same original composition gave rise to new globular structures and the potential for plantlet regeneration has been maintained for over a year. The histological examination of these proembryogenic structures suggested that somatic embryos arise from single cells. Regenerated plants are phenotypically normal, having diploid chromosome numbers (2n = 24).     

Extracellular proteins in plant embryogenesis.

In many plant species nonzygotic embryos can develop from diploid somatic cells grown in tissue culture. Extracellular glycoproteins have been identified that can rescue arrested somatic embryos. One of these glycoproteins may be part of a mechanism that controls the expansion of plant cells.     

Comparison of triploid and diploid cucumber in long-term liquid cultures

Triploid suspensions generally grew more vigorously in modified MS medium with 2,4-D than those of diploids. The embryogenic potential of 26-month-old auxin-dependent suspension cultures depended on the line. Neither triploid nor diploid BOR (Borszczagowski line) were able to produce somatic embryos. Similarly, 12–20-month-old cytokinin-dependent suspensions from the same triploid line were not capable of regeneration. Only aggregates from 26-month-old auxin-dependent suspension of triploid line 603 differentiated into somatic embryos. In contrast, 18-month-old diploid and triploid liquid cultures of meristematic clumps (LMC) of BOR retained their regeneration potential. The ploidy level of triploid and diploid auxin-dependent suspension cultures was stable during the first 8 months. However, the ploidy level of triploids remained stable over 26 months of culture, whereas 66.7% of diploid cultures underwent chromosome doubling. No ploidy changes were observed among plants regenerated from 18-month-old LMC. Our data suggest that loss of embryogenic potential in suspension culture was independent of ploidy level.     

Current status in production and utilization of dihaploids from somatic hybrids between eggplant (Solanum melongena L.) and its wild relatives

The major constrains for practical exploitation of the somatic hybrids between eggplant and its wild relatives have been their sterility and tetraploidy which prevented their incorporation into breeding programs. Here we demonstrate that anther culture was successfully utilized to bring back the ploidy level to the diploid status in tetraploid interspecific hybrids between eggplant and the allied species S. integrifolium and S. aethiopicum gr. gilo. Both the relative species are resistant to Fusarium oxysporum f. sp. melongenae and to some strains of bacterial wilt (Ralstonia solanacearum) which are very destructive diseases of eggplant. Dihaploid androgenetic plants were obtained from the somatic hybrids, from the “double somatic hybrid” obtained by sexual cross of the two somatic hybrids [(eggplant + S. aethiopicum) × (eggplant + S. integrifolium)], and from tetraploid backcrossed plants between the somatic hybrid with S. aethiopicum and eggplant. Phenotypical, molecular, biological and biochemical characterization, and also artificial inoculation with Fusarium oxysporum are consistent with a recombination between the genomes of the species involved in the hybridizations. Dihaploids resistant to Fusarium were successfully backcrossed with eggplant. Besides their utility as potential valuable breeding materials, the introgressed lines obtained may be utilized in genetic and molecular studies about the resistance to Fusarium from S. integrifolium and S. aethiopicum gr. gilo.     

Effect of ploidy increase on transgene expression: example from <Emphasis Type="Italic">Citrus</Emphasis> diploid cybrid and allotetraploid somatic hybrid expressing the EGFP gene

Polyploidization is an important speciation mechanism for all eukaryotes, and it has profound impacts on biodiversity dynamics and ecosystem functioning. Green fluorescent protein (GFP) has been used as an effective marker to visually screen somatic hybrids at an early stage in protoplast fusion. We have previously reported that the intensity of GFP fluorescence of regenerated embryoids was also an early indicator of ploidy level. However, little is known concerning the effects of ploidy increase on the GFP expression in citrus somatic hybrids at the plant level. Herein, allotetraploid and diploid cybrid plants with enhanced GFP (EGFP) expression were regenerated from the fusion of embryogenic callus protoplasts from ‘Murcott’ tangor (Citrus reticulata Blanco × Citrus sinensis (L.) Osbeck) and mesophyll protoplasts from transgenic ‘Valencia’ orange (C. sinensis (L.) Osbeck) expressing the EGFP gene, via electrofusion. Subsequent simple sequence repeat (SSR), chloroplast simple sequence repeat and cleaved amplified polymorphic sequence analysis revealed that the two regenerated tetraploid plants were true allotetraploid somatic hybrids possessing nuclear genomic DNA of both parents and cytoplasmic DNA from the callus parent, while the five regenerated diploid plants were cybrids containing nuclear DNA of the leaf parent and with complex segregation of cytoplasmic DNA. Furthermore, EGFP expression was compared in cells and protoplasts from mature leaves of these diploid cybrids and allotetraploid somatic hybrids. Results showed that the intensity of GFP fluorescence per cell or protoplast in diploid was generally brighter than in allotetraploid. Moreover, same hybridization signal was detected on allotetraploid and diploid plants by Southern blot analysis. By real-time RT-PCR and Western blot analysis, GFP expression level of the diploid cybrid was revealed significantly higher than that of the allotetraploid somatic hybrid. These results suggest that ploidy level conversion can affect transgene expression and citrus diploid cybrid and allotetraploid somatic hybrid represents another example of gene regulation coupled to ploidy.     

A novel method for somatic cell nuclear transfer to mouse embryonic stem cells

Nuclear reprogramming by somatic cell nuclear transfer (SCNT) provides a practical approach for generating autologous pluripotent cells from adult somatic cells. It has been shown that murine somatic cells can also be reprogrammed to a pluripotent-like state by fusion with embryonic stem (ES) cells. Typically, the first step in SCNT involves enucleation of the recipient cell. However, recent evidence suggests that enucleated diploid ES cells may lack reprogramming capabilities. Here we have developed methods whereby larger tetraploid ES cells are first generated by fusion of two mouse ES cell lines transfected with plasmids carrying different antibiotic-resistance cassettes, followed by double antibiotic selection. Tetraploid ES cells grown on tissue culture disks or wells can be efficiently enucleated (up to 99%) using a combination of cytochalasin B treatment and centrifugation, with cytoplasts generated from these cells larger than those obtained from normal diploid ES cells. Also, we show that the enucleation rate is dependent on centrifugation time and cell ploidy. Further, we demonstrate that normal diploid ES cells can be fused to tetraploid ES cells to form heterokaryons, and that selective differential centrifugation conditions can be applied where the tetraploid nucleus is removed while the diploid donor nucleus is retained. This technology opens new avenues for generating autologous, diploid pluripotent cells, and provides a dynamic model for studying nuclear reprogramming in ES cells.     

Tetraploid somatic hybrids of potato (<Emphasis Type="Italic">Solanum tuberosum</Emphasis> L.) obtained from diploid breeding lines

Intraspecific somatic hybrids between 16 different diploid breeding lines of Solanum tuberosum L. were produced by PEG-induced fusion. Manually selected heterokaryons were cultured in a Millicells-CM using a post-fusion protoplast mixture. Plants were regenerated from calli derived from heterokaryons obtained from 10 out of 38 combinations of diploid lines. Of the tested putative somatic hybrids, 14.2% were diploid, 72.8% were tetraploid and 13% pentaploid. The DNA amplification pattern obtained with RAPD or semi-random primers confirmed that 6 fusion combinations were hybrids. In most cases, the morphological traits were intermediate to those of the diploid fusion partners. About 23.0% of the tested somatic hybrids showed variation in their morphology. Of the tested somatic hybrids, 78.0% flowered and 86.0% tuberized. The cytoplasm of 9 diploid lines and 6 somatic hybrid combinations was analysed. Two of the diploid lines had W/S chloroplasts and α or ε mitochondria; the remainder contained T chloroplasts and β mitochondria. All the analysed somatic hybrids carried T chloroplasts and β mitochondria.