Somatic hybridization between Lycopersicon esculentum and Lycopersicon pennellii

Summary Selection and screening methods were devised which resulted in the identification of a number of somatic hybrid callus clones following fusion of Lycopersicon esculentum protoplasts and L. pennellii suspension culture protoplasts. Visual selection for callus morphology combined with a high fusion frequency and irradiation of one parental protoplast type (¹³⁷Cs source, 1.5 Krads) resulted in selection of a callus clone population containing a high proportion of somatic hybrids. Analysis of a dimeric isozyme for the presence of a heterodimeric form was found to be satisfactory for distinguishing parental-type calli, somatic hybrid calli, and mixed calli derived from both types of unfused parental cells. No somatic hybrid calli produced shoots, although the sexual hybrid between L. esculentum and L. pennellii regenerated well under the culture conditions employed. This result suggests that the non-regenerable growth habit of the L. pennellii suspension culture was dominant in the somatic hybrid. The culture conditions described here are suitable for obtaining regenerated plants from L. esculentum mesophyll protoplasts. L. esculentum protoplast calli from fusion cultures gave rise to shoots with L. esculentum phenotype at higher frequency than calli from control unfused L. esculentum mesophyll protoplast cultures. The use of probes for species-specific organelle DNA fragments allowed identification of organelle DNA restriction fragments in digests of total DNA from small samples of individual callus clones. The callus clones analyzed either carried predominantly one parental plastid DNA type or mixtures of both types. Use of a mitochondrial DNA (mtDNA) probe which distinguishes two parental mtDNA fragments revealed that the L. pennellii-specific fragment was present in all clones examined, but the L. esculentum fragment was absent or in low proportion.     

Somatic hybrid plants between Lycopersicon esculentum and Solanum lycopersicoides

Summary Leaf mesophyll protoplasts of Lycopersicon esculentum (2n=2x=24) were fused with suspension culture-derived protoplasts of Solanum lycopersicoides (2n=2x=24) and intergeneric somatic hybrid plants were regenerated following selective conditions. A two phase selection system was based on the inability of S. lycopersicoides protoplasts to divide in culture in modified medium 8E and the partial inhibition of L. esculentum protoplasts by the PEG/DMSO fusion solution. At the p-calli stage, putative hybrids were visually selected based on their hybrid vigor and lime-green coloration in contrast to slower growing parental calli characterized by a watery, whitish-brown coloration. Early identification of the eight hybrid plants studied was facilitated by isozyme analysis of leaf tissue samples taken from plants in vitro at the rooting stage. Regenerated plants growing in planting medium were further verified for hybridity by 5 isozymes marking 7 loci on 5 chromosomes in tomato. These included Skdh-1 mapped to chromosome 1 of tomato, Pgm-2 on chromosome 4, Got-2 and Got-3 on chromosome 7, Got-4 on chromosome 8, and Pgi-1 and Pgdh-2 both on chromosome 12. Fraction I protein small subunits further confirmed the hybrid nature of the plants with bands of both parents expressed in all hybrids. The parental chloroplasts could not be differentiated by the isoelectric points of the large subunit. Seven of the eight somatic hybrids had a chromosome number ranging from the expected 2n=4x=48 to 2n=68. Mixoploid root-tip cells containing 48, 53, 54 or 55 chromosomes for two of the hybrids were also observed.Michigan Agricultural Experiment Station Journal Article No. 11736. Supported by Grant No. I-751-84R from BARD — The United States — Israel Binational Agricultural Research and Development Fund     

Somatic hybridization between selected Lycopersicon and Solanum species

Summary Mesophyll protoplasts of an interspecific Lycopersicon esculentum Mill, (tomato) x Lycopersicon pennellii hybrid plant (EP) were fused with callus-derived protoplasts of Solanum lycopersicoides Dun. using a modified PEG/DMSO procedure. The EP plant was previously transformed by Agrobacterium tumefaciens which carried the NPTII and nopaline synthase genes. Protoplasts were plated at 10⁵/ml in modified KM medium and 16 days post-fusion 25 ug/ml kanamycin was added to the culture medium. During shoot regeneration, 212 morphologically similar putative somatic hybrids were delineated visually from kanamycin resistant EP's. Forty-eight shoots, randomly selected among the 212, were further verified as somatic hybrids by their leaf phosphoglucoisomerase heterodimer isozyme pattern. However, the resulting plants were virtually pollen sterile. In a second fusion, mesophyll protoplasts of Solanum melongena (eggplant) were fused with EP callus-derived protoplasts. Using the same fusion and culture procedure, only two dark green calli were visually selected among the pale green parental EP and verified as somatic cell hybrids by several isozyme patterns. These two calli have produced only leaf primordia in one and half years on regeneration medium.Abbreviations ABA abscisic acid - BAP 6 benzylaminopurine - 2,4-D 2,4 dichlorophenoxy acetic acid - DMSO dimethyl sulfoxide - GA₃ gibberellic acid - GOT glutamate oxaloacetate - IAA indoleacetic acid - IBA indolebutyric acid - IDH isocitrate dehydrogenase - MDH malate dehydrogenase - MES morpholinoethane-sulfonic acid - PEG polyethylene glycol - 6-PGDH 6 phosphogluconate dehydrogenase - PGI phosphoglucoisomerase     

Somatic hybridization in higher plants

Summary Somatic hybridization in higher plants has come into focus since methods have been established for protoplast fusion and uptake of foreign DNA and organelles by protoplasts. Polyethylene glycol (PEG) was an effective agent for inducing fusion. Treatment of protoplasts with PEG resulted in 5 to 30% heterospecific fusion products. Protoplasts of different species, genera and even families were compatible when fused. A number of protoplast combinations (soybean + corn, soybean + pea, soybean + tobacco, carrot + barley, etc.) provided fusion products which underwent cell division and callus formation. Fusion products initially were heterokaryocytes. In dividing heterokaryocytes, random distribution of mitotic nuclei was observed to be accompanied by multiple wall formation and to result in chimeral callus. Juxtaposition of mitotic nuclei suggested nuclear fusion and hybrid formation. Fusion of heterospecific interphase nuclei was demonstrated in soybean + pea and carrot + barley heterokaryons. Provided parental protoplasts carry suitable markers, the fusion products can be recognized. For the isolation and cloning of hybrid cells, fusion experiments must be supplemented with a selective system. Complementation of two nonallelic genes that prevent or inhibit growth under special culture conditions appears as the principle on which to base the selection of somatic hybrids. As protoplasts of some species have been induced to regenerate entire plants, the development of hybrid plants from protoplast fusion products is feasible and has already been demonstrated for tobacco. Presented in the formal symposium on Somatic Cell Genetics at the 27th Annual Meeting of the Tissue Culture Association, Philadelphia, Pennsylvania, June 7–10, 1976.     

Regeneration of intergeneric somatic hybrid plants between Lycopersicon esculentum and Solanum muricatum

Summary Mesophyll protoplasts of tomato (Lycopersicon esculentum) and pepino (Solanum muricatum) were fused by using an electrofusion method and cultured in modified MS medium supplemented with naphthaleneacetic acid and kinetin, in which only pepino and somatic hybrid protoplasts could divide. Somatic hybrid plants showing intermediate characteristics in morphology were regenerated from the calli exhibiting vigorous growth in contrast with those of pepino. The hybrid nature of these plants was confirmed by cytological observation and biochemical analyses of phosphoglucomutase isozymes and the fraction-1-protein. The regenerated somatic hybrids grew to flowering stage and set fruits.     

Chloroplast and mitochondrial DNA composition of triploid and tetraploid somatic hybrids between Lycopersicon esculentum and Solanum tuberosum

The chloroplast (cp) DNA type and mitochondrial (mt) DNA composition of 17 somatic hybrids between a cytoplasmic albino tomato and monoploid potato (A7-hybrids) and 18 somatic hybrids between a nitrate reductase-deficient tomato and monoploid potato (C7-hybrids) were analyzed. Thirteen A7-hybrids and 9 C7-hybrids were triploids (with one potato genome); the other hybrids were tetraploid. As expected, all A7-hybrids contained potato cpDNA. Of the C7-hybrids 7 had tomato cpDNA, 10 had potato cpDNA and 1 hybrid contained both tomato and potato cpDNA. The mtDNA composition of the hybrids was analyzed by hybridization of Southern blots with four mtDNA-specific probes. The mtDNAs in the hybrids had segregated independently from the cpDNAs. Nuclear DNA composition (i.e. one or two potato genomes) did not influence the chloroplast type in the C7-hybrids, nor the mtDNA composition of A7- or C7-hybrids. From the cosegregation of specific mtDNA fragments we inferred that both tomato and potato mtDNAs probably have a coxII gene closely linked to 18S+5S rRNA genes. In tomato, atpA, and in potato, atp6 seems to be linked to these mtDNA genes.     

Species-specific DNA sequences for identification of somatic hybrids between Lycopersicon esculentum and Solanum acaule

Summary Species-specific highly repeated DNA sequences can be used to screen the progeny of protoplast fusions combining different species. Such probes are easy to clone and can be detected by fast methods, e.g., hybridization to total genomic DNA. Furthermore, due to their high copy number, hybridization signals are strong and represent more than one locus, unlike isozymes or resistance markers. After cloning and screening for species-specific DNA sequences we characterized the highly repeated DNA sequences of the solanaceous species Solanum acaule and Lycopersicon esculentum var. gilva. DNA sequencing and hy ridization revealed a prominent, tandemly arranged satellite DNA repeat of 162 bp in Lycopersicon esculentum and a different satellite repeat of 183 bp, also tandemly organized, in Solanum acaule. Each repeat is absent in the respective other species. Therefore, we have used these DNA repeats as markers to distinguish regenerated interspecific somatic hybrids from the respective fusion partners. These hybrids were clearly identified by Southern hybridization and dot-blot assays to the respective ³²P-labelled satellite DNA.     

Asymmetric somatic hybrids between Lycopersicon esculentum and irradiated Lycopersicon peruvianum

Summary Asymmetric somatic hybrids of Lycopersicon esculentum and Lycopersicon peruvianum were obtained by fusion of leaf protoplasts from both species after irradiation of protoplasts or leaf tissue of L. peruvianum with 50, 300, or 1,000 Gy of gamma-rays. These radiation doses were sufficient to abolish the growth of the L. peruvianum protoplasts. The hybrids were selected for their ability to regenerate plants; this regeneration capacity derived from L. peruvianum. All asymmetric hybrid plants were aneuploid. The ploidy level, the morphology, and the regeneration rate were analyzed in relation to the radiation dose applied to L. peruvianum. After a low dose (50 Gy), most hybrids had near-triploid chromosome numbers, whereas after a high dose (300 or 1,000 Gy), most hybrids had near-pentaploid numbers. The morphology of the asymmetric hybrids was intermediate between that of L. esculentum and symmetric somatic hybrids of both species (obtained without irradiation treatment), and approached the morphology of L. esculentum to a greater extent after a high dose of irradiation. The asymmetric hybrids regenerated more slowly than the symmetric hybrids and regeneration proceeded more slowly after a high dose than after a low dose of irradiation. The high-dose hybrids also grew more slowly, flowered less, and set fruits less than the low-dose hybrids. No seeds could be obtained from any asymmetric hybrid.     

Solanum lycopersicoides gene introgression to tomato,Lycopersicon esculentum,through the systematic avoidance and suppression of breeding barriers

Summary While Lycopersicon esculentum and Solanum lycopersicoides have been successfully hybridized, attempts at further direct gene introgression have been unsuccessful due to the presence of incompatibility barriers. A systematic study of the initial hybridization and subsequent backcrosses has identified multiple barriers to introgression. These barriers are expressed as pollen tube inhibition in the upper style and lower pistil, and failures in syngamy, zygote development, and sporogenesis. Upper style cross-incompatibility barriers were successfully avoided by bud pollinations using a stigma complementation procedure to allow pollen germination on otherwise unreceptive stigmas. The inhibition of pollen tube growth was observed in the lower pistil. A combination of environmental, plant, and genetic manipulations facilitated consistent pollen tube growth to the ovule micropyles in all crosses attempted. Failures at syngamy and early zygote formation proved to be the most difficult barriers to overcome — these were particularly severe in crosses to F₁ hybrid plants. Progeny were obtained in all crossing combinations attempted except in the initial hybridization with S. lycopersicoides as the pistillate parent. Although the strong pre-zygotic barriers were overcome in this cross, further progress was restricted by post-zygotic failures. The capability to overcome pre-zygotic barriers and to excise and culture very young embryos has allowed plantlet recovery from male sterile F₁ plants. Partially pollen-fertile F₁ plants were recovered when relatively large F₁ populations were generated from different _{S. lycopersicoides accessions}. In general, barriers to introgression diminished with increased backcrossing, though exceptions were noted. Progeny from the second backcross to L. esculentum possessed adequate fertility to set self-seed under field conditions. Although all backcross progeny were developed from only a few F₁ individuals, considerable genetic variability was recovered for fruit and vegetative characteristics. Potentially useful levels of disease resistance, particularly to Botrytis cinerea, were also recovered.     

Organelle analysis of symmetric and asymmetric hybrids between Lycopersicon peruvianum and Lycopersicon esculentum

Summary The organelles of somatic hybrids obtained from symmetric and asymmetric fusions between the Lycopersicon species L. peruvianum and L. esculentum were analyzed by DNA hybridization methods. In the asymmetric fusions the L. peruvianum protoplasts were gamma-irradiated at a dose of 50, 300 and 1,000 Gy. The organelles were characterized using the Petunia chloroplast probe pPCY64 and the mitochondrial EcoRI-SalI fragment of the Pcf gene. In all symmetric and asymmetric hybrid plants, a total of 73 being analyzed, only one of the parental chloroplast genomes was present, except for one hybrid plant which harbored both parental chloroplast genomes. No recombination and/or rearrangement in the chloroplast genome could be identified with the pPCY64 probe. Irradiation of the L. peruvianum protoplasts did not significantly reduce the fraction of asymmetric hybrids with L. peruvianum chloroplasts. A novel mitochondrial restriction pattern was present in 5 out of 24 hybrids tested. In 9 hybrids novel combinations of chloroplasts and mitochondria were found, indicating that both organelle types sorted out independently.     

Asymmetric somatic hybrids between Lycopersicon esculentum and irradiated Lycopersicon peruvianum

Summary Asymmetric somatic hybrids of Lycopersicon esculentum and Lycopersicon peruvianum were analysed for the retention of genes and alleles specific for L. peruvianum. The hybrids were obtained by fusion of protoplasts from L. esculentum with those of L. peruvianum (the donor), the latter having been irradiated before fusion with 50, 300 or 1,000 Gy of gamma-rays. The retention of three different types of genes or alleles was analysed. (1) The gene coding for kanamycin resistance, which is dominant and had been introduced in most of the L. peruvianum donor plants by transformation. It was present at one locus in 16 L. peruvianum donor plants and at two loci in one donor plant. (2) The genes coding for acid phosphatase, locus Aps-1, and glutamate oxaloacetate transaminase (GOT); different alleles of these genes are co-dominant and were detected by isozyme analysis. (3) Eighteen single gene morphological markers for which most of the L. esculentum genotypes used were homozygous recessive. Kanamycin resistance from donor plants with one locus was retained in about 50% of the asymmetric 30H-hybrids (the donor was irradiated with 300 Gy). L. peruvianum specific alleles of Aps-1 and GOT were present in at least 70% of the hybrids; the retention of donor alleles was lower in 30H- than in 5H-hybrids (donor irradiated with 50 Gy). On average, 73% of the L. peruvianum-specific alleles (one or both) of the morphological markers were detected in the 30H-hybrids. Several of the L. esculentum genotypes used were homozygous recessive for two morphological markers on the same chromosome; in 43% of the 30H-hybrids derived from them, only one of these markers was complemented by the L. peruvianum allele. This is an indication of frequent breakage of the L. peruvianum chromosomes. Several hybrid calli regenerated genotypically different shoots. On the whole, this analyses confirms the conclusion drawn from the cytogenetic and morphological analysis of these asymmetric hybrids, namely that irradiation prior to fusion eliminates the L. peruvianum genome to only a limited extent.     

Somatic hybridization between Brassica juncea and Moricandia arvensis by protoplast fusion

Intergeneric somatic hybrids have been produced between Brassica juncea (2n=36, AABB) cv. RLM-198 and Moricandia arvensis (2n=28, MM) by protoplast fusion. Hypocotyl protoplasts of B. juncea were fused with mesophyll protoplasts of M. arvensis using polyethylene glycol. Fusion frequency, estimated on the basis of differential morphological characterstics of parental protoplasts was about 5%. Of the 156 calli obtained, four calli produced shoots intermediate in morphology between the parents. Hybrid nature of the plants was confirmed using wheat nuclear rDNA probe. Hybridization of total DNA with a mitochondrial DNA probe carrying 5s–18s rRNA genes of maize showed that the mitochondria of the somatic hybrids were derived from the wild species M. arvensis. Meiosis in the only hybrid that produced normal flowers revealed the occurrence of 64 chromosomes, the sum of chromosomes of parental species. Inspite of complete pollen sterility, siliquas were produced in this hybrid by back-crossing with B. juncea. These siliquas on in vitro culture produced 12 seeds.     

Somatic hybrids between Brassica oleracea L. and Sinapis alba L. with resistance to Alternaria brassicae (Berk.) Sacc.

 Somatic Hybrids between Sinapis alba and rapid-cycling Brassica oleracea were generated for transferring of resistance to Alternaria brassicae to B. oleracea. A. brassicae causes the significant disease black spot in cruciferous crops. A total of 27 plants were regenerated from protoplast fusion using 0, 5, 10, 20 and 30 krad γ-irradiation of the resistance donor and iodoacetate treatment of B. oleracea. All plants showed intermediate morphology with partially divided leaves and some trichomes on stems and leaves. Flow cytometry and banding patterns of the enzymes leucine amino peptidase (LAP) and phosphoglucose isomerase (PGI) confirmed the hybrid status of the regenerated plants. Some of the plants obtained from cuttings from the somatic hybrids showed a resistance to A. brassicae that was similar to that found in S. alba. The flowers of the somatic hybrids had reduced anthers with little pollen production. Received : 9 May 1996 / Accepted : 15 November 1996     

Subcellular localization of steroidal glycoalkaloids in vegetative organs of Lycopersicon esculentum and Solanum tuberosum

Cell fractions from the major vegetative organs of tomato and potato plants were obtained by homogenization and differential centrifugation. In both species, steroidal glycoalkaloids were found to accumulate mainly in the soluble fraction, with smaller amounts in the microsomal fraction. Alkaloids appeared sporadically in the mitochondrial fractions but were only detected in lower fractions as an artefact.     

Limited DNA elimination from the irradiated potato parent in fusion products of albino Lycopersicon esculentum and Solanum tuberosum

Summary This paper describes the analysis of the elimination of potato DNA from potato-tomato somatic cell hybrids. The hybrids were obtained by fusion of protoplasts of a cytoplasmic albino tomato genotype with leaf mesophyll protoplasts of a potato genotype carrying the -glucuronidase (GUS) gene of Escherichia coli. The potato protoplasts were either isolated from unirradiated plants or from plants irradiated with 50 or 500 Gy of -rays. Green calli were selected as putative fusion products. The hybridity of these calli was confirmed by isoenzyme analysis. All of the green calli tested contained a potato-specific chloroplast DNA restriction fragment, and most of the calli analysed were positive for -glucuronidase activity. In 72 of the hybrid calli we determined the percentage of potato nuclear DNA using species-specific probes. All of the tested green calli contained a considerable amount of potato genomic DNA, irrespective of the dose of irradiation of the potato parent. The limited degree of potato DNA elimination and the absence of true cybrids are discussed.     

Wide hybridization experiments in cereals

Summary Wide hybridization is a useful tool in plant breeding, but little is known about its possible range. For the cereals, wheat, barley and rye, this was tested with 15 different species of the Poaceae and Panicoideae. Embryo formation could be obtained with Agropyron repens, Alopecurus agrestis, Dactylis glomerata, Festuca glauca, Hordeum bulbosum, Lolium perenne, Pennisetum americanum, and Zea mays. As well, haploid as diploid embryos occurred. New embryo culture techniques should enable these embryos to grow to plants.     

Cytogenetic analysis of Lycopersicon esculentum (+) Solanum etuberosum somatic hybrids and their androgenetic regenerants

The aim of the study was to characterize genomic relationships among cultivated tomato (Lycopersicon esculentum Mill.) (2n=2x=24) and diploid (2n=2x=24) non-tuberous wild Solanum species (S. etuberosum Lindl.). Using genomic in situ hybridization (GISH) of mitotic and meiotic chromosomes, we analyzed intergeneric somatic hybrids between tomato and S. etuberosum. Of the five somatic hybrids, two plants were amphidiploids (2n=4x=48) mostly forming intragenomic bivalents in their microsporocytes, with a very low frequency of multivalents involving the chromosomes of tomato and S. etuberosum (less than 0.2 per meiocyte). Tomato chromosomes showed preferential elimination during subsequent meiotic divisions of the amphidiploids. Transmission of the parental chromosomes into microspores was also evaluated by GISH analysis of androgenic plants produced by direct embryogenesis from the amphidiploid somatic hybrids. Of the four androgenic regenerants, three were diploids (2n=2x=24 or 2n=2x+1=25) derived from reduced male gametes of the somatic hybrids, and one plant was a hypertetraploid (2n=4x+4=52). GISH revealed that each anther-derived plant had a unique chromosome composition. The prospects for introgression of desirable traits from S. etuberosum into the gene pool of cultivated tomato are discussed. Received: 2 August 2000 / Accepted: 4 December 2000     

甘蓝型油菜与芝麻菜体的细胞杂交

为拓宽油菜育种的基因资源库, 改良油菜品种, 以甘蓝型油菜(Brassica napus)花油3号下胚轴和芝麻菜(Eruca sativa)下胚轴为材料分离制备原生质体; 然后采用PEG-高Ca2+-高pH法进行原生质体融合, 当PEG浓度为35%, 原生质体融合密度为5×105个/mL时, 融合25 min时, 融合率可达18.2%。融合后在培养密度为1×105个/mL时, 以附加1.0 mg/L 2,4-D +0.5 mg/L 6-BA+0.5 mg/L NAA+ 200 mg/L肌醇+300 mg/L水解酪蛋白的改良的KM8p为融合体培养基, 以0.1 mol/L 蔗糖+0.2 mol/L葡萄糖+0.2 mol/L甘露醇作渗透稳定剂进行液体浅层培养, 效果较好, 愈伤组织再生率最高为6.8%。将融合体再生的小愈伤组织转移至培养基(B5无机盐+0.087 mol/L蔗糖+0.2 mg/L 2, 4-D+0.5 mg/L NAA+0.2 mg/L 6-BA+ 0.5% Agar, pH 5.8)上增殖培养, 待愈伤组织长至直径为3~5 mm时, 及时将其转至分化培养基(MS无机盐+0.087 mol/L 蔗糖+0.1 mg/L IAA+0.8 mg/L 6-BA+0.8% Agar, pH 5.8)中诱导不定芽再生, 芽分化率为35.7%。当不定芽长为2~3 cm时, 将其切下转入附加0.5 mg/L IBA+0.2 mg/L 6-BA的1/2MS生根培养基中诱导生根, 14 d左右即可形成再生植株, 生根率可达88%。同时, 以紫外线(60 μW/cm2)照射芝麻菜原生质体, 进行不对称融合, 照射2 min的获得了愈伤组织和再生植株, 照射4 min的只获得愈伤组织, 而照射5 min以上的没有获得愈伤组织, 但其愈伤组织再生、增殖及植株再生均不如对称融合。从细胞学鉴定的21块杂种愈伤组织上再生出16株杂种植株。