Production and molecular characterization of potential seedless cybrid plants between pollen sterile Satsuma mandarin and two seedy <Emphasis Type="Italic">Citrus</Emphasis> cultivars

Cytoplasmic male sterility (CMS) is known to be controlled by mitochondrial genome in higher plants including Satsuma mandarin (Citrus unshiu Marc.). Citrus symmetric fusion experiments often produce diploid cybrids possessing nuclear DNA from the mesophyll parent and mitochondrial DNA (mtDNA) from the embryogenic callus parent. Therefore, it is possible to transfer CMS from Satsuma mandarin as callus parent to seedy citrus cultivars as leaf one by somatic cybridization. Herein, symmetric fusion technique was adopted to create cybrids for potential seedlessness by transferring CMS from Citrus unshiu Marc. cv. Guoqing No. 1 (G1) to two traditional Chinese seedy citrus cultivars, ‘Shatian’ pummelo (C. grandis (L) Osbeck) and ‘Bingtang’ orange (C. sinensis (L) Osbeck). Flow cytometry analysis showed that 19 plants recovered from G1 + ‘Bingtang’ orange and 17 of 35 plants regenerated from G1 + ‘Shatian’ pummelo were diploid. The remaining plants from G1 + ‘Shatian’ pummelo were tetraploid. The diploid plants from the two combinations were confirmed as true cybrids by simple sequence repeat (SSR) and cleaved amplified polymorphic sequence (CAPS) analysis, with nuclear DNA from their corresponding leaf parent and mtDNA from their common suspension parent, G1 Satsuma mandarin. The remaining plants from G1 + ‘Shatian’ pummelo were identified as somatic hybrids with mtDNA from G1. The chloroplast simple sequence repeat (cp-SSR) analysis revealed somatic hybrid/cybrid plants from the two combinations in most cases possessed either of their parental chloroplast type, and two plants from G1 +‘Shatian’ pummelo and all embryoids analyzed from G1 + ‘Bingtang’ orange possessed chloroplast DNA (cpDNA) from both parents. These results demonstrated that we succeeded in introducing mtDNA from G1 Satsuma mandarin into the two target seedy citrus cultivars for potential seedlessness through symmetric fusion.     

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.     

New universal mitochondrial PCR markers reveal new information on maternal citrus phylogeny

The aim of this work was to provide a set of mitochondrial markers to reveal polymorphism and to study the maternal phylogeny in citrus. We first used 44 universal markers previously described in the literature: nine of these markers produced amplification products but only one revealed polymorphism in citrus. We then designed six conserved pairs of primers using the complete mitochondrial DNA sequences of Arabidopsis thaliana and Beta vulgaris to amplify polymorphic intergenic and intronic regions. From these six pairs of primers, three from introns of genes coding for NADH dehydrogenase subunits 2, 5, and 7, revealed polymorphism in citrus. First, we confirmed that citrus have a maternal mitochondrial inheritance in two populations of 250 and 120 individuals. We then conducted a phylogenic study using four polymorphic primers on 77 genotypes representing the diversity of Citrus and two related genera. Seven mitotypes were identified. Six mitotypes (Poncirus, Fortunella, Citrus medica, Citrus micrantha, Citrus reticulata, and Citrus maxima) were congruent with previous taxonomic investigations. The seventh mitotype enabled us to distinguish an acidic mandarin group (‘Cleopatra’, ‘Sunki’ and ‘Shekwasha’) from other mandarins and revealed a maternal relationship with Citrus limonia (‘Rangpur’ lime, ‘Volkamer’ lemon) and Citrus jambhiri (‘Rough’ lemon). This mitotype contained only cultivated species used as rootstocks due to their good tolerances to abiotic stress. Our results also suggest that two species classified by Swingle and Reece, Citrus limon, and Citrus aurantifolia, have multiple maternal cytoplasmic origins.     

GFP expression as an indicator of somatic hybrids between transgenic Satsuma mandarin and calamondin at embryoid stage

Somatic hybridization was performed via electrofusion between embryogenic suspension-derived protoplasts of transgenic green fluorescent protein (GFP) Satsuma mandarin (Citrus unshiu Marc. cv. Guoqing No. 1) (G1) callus and mesophyll protoplasts of calamondin (Citrus microcarpa Bunge), and three embryoids expressing GFP under UV light were obtained after 60 days of culture. The three embryoids were considered not as diploid cybrids but true allotetraploid somatic hybrids, as it was based on: (1) citrus heterokaryons are generally more vigorous and have higher capacity for embryogenesis as compared with unfused and homo-fused embryogenic callus protoplasts; (2) the callus line of G1 Satsuma mandarin has lost the embryogenesis capacity; and (3) citrus diploid cybrids produced by symmetric fusion always possess nuclear genome of mesophyll parent, and calamondin without GFP gene was used as leaf parent in this study. Subsequent flow cytometry, simple sequence repeat and cleaved amplified polymorphic sequence analysis of one regenerated callus mass and three resulting plants validated this supposition, i.e., the callus was derived from transgenic G1 callus protoplasts, and the three plants were true allotetraploid somatic hybrids possessing nuclear genomic DNA of both parents and cytoplasmic DNA from callus parent. The potential of transgenic GFP citrus callus as suspension parent in citrus somatic fusion to study the mechanism of cybrid formation, create new citrus cybrids, and transfer organelle-encoded agronomic traits was also discussed.     

Cytoplasmic hybridization in Nicotiana: mitochondrial DNA analysis in progenies resulting from fusion between protoplasts having different organelle constitutions

Summary Our previous studies indicated that fusion products with one functional nucleus but organelles of the two fusion partners (i.e. heteroplastomic cybrids) could be obtained by fusing X-irradiated (cytoplasmic donor) with non-irradiated (recipient) Nicotiana protoplasts. The present report deals with the analysis of mitochondria in cybrid populations resulting from the fusion of donor Nicotiana tabacum protoplasts with recipient protoplasts having a N. Sylvestris nucleus but chloroplasts of an alien Nicotiana species, and exhibiting cytoplasmic male sterility. The two fusion parents showed significant differences in restriction patterns of their chloroplast and mitochondrial DNA. Four groups of cybrid plants were obtained by this fusion. All had N. sylvestris nuclei but contained either donor or recipient chloroplasts and had either sterile or fertile anthers. There was no correlation between anther fertility and chloroplasts type. The mitochondrial DNA restriction patterns of sterile cybrids were similar to the respective patterns of the sterile fusion partner while the mitochondrial DNA restriction patterns of the fertile cybrids were similar to the respective patterns of the fertile fusion partner. The results indicate an independent assortment of chloroplasts and mitochondria from the heteroplastomic fusion products.     

Transfer of Ogu cytoplasmic male sterility to Brassica juncea and improvement of the male sterile line through somatic cell fusion

Male sterility conferred by ogu cytoplasm of Raphanus sativus has been transferred to Brassica juncea cv RLM 198 from male-sterile B. napus through repeated backcrossing and selection. The male-sterile B. juncea is, however, highly chlorotic and late. It has low female (seed) fertility and small contorted pods. To rectify these defects, protoplasts of the male sterile were fused with normal RLM 198 (green, self fertile). Four dark green, completely male-sterile plants were obtained and identified as putative cybrids. All the plants were backcrossed three times with RLM 198. Mitochondrial and chloroplast DNA analysis of backcross progeny confirmed hybridity of the cytoplasm. The restriction pattern of the chloroplast DNA of progeny plants of three cybrids (Og 1, Og 2, Og 3) was similar to that of the green self-fertile RLM 198 and indicated that the correction of chlorosis resulted from chloroplast substitution. The chloroplast DNA of the lone progeny plant of the fourth cybrid (Og 10) could not be analyzed because the plant was stunted and had only a few leaves. When total cellular DNA was probed with mitochondrial probes coxI and atpA it was found that the cybrids had recombinant mitochondria. The chlorosis-corrected plants were early flowering and had vastly improved seed fertility.     

The transfer of ‘Polima’ cytoplasmic male sterility from oilseed rape (Brassica napus) to broccoli (B. oleracea) by protoplast fusion

Protoplast fusion was utilised to transfer Polima type cytoplasmic male sterility (CMS) from Brassica napus, canola cv. Polima Karat (Pol-Karat) to B. oleracea, broccoli, var. Green Comet. Southern and RFLP analysis confirmed that four cybrids possessed nuclear genomes of broccoli with Polima mitochondria and chloroplasts. A fifth cybrid was a nuclear hybrid between broccoli and Pol-Karat, with Polima mitochondria and chloroplasts of broccoli. The broccoli type cybrids were morphologically similar to Green Comet, while the hybrid type was an intermediate of the two fusion parents. Flowers on the cybrids were distinctive in that although they possessed a morphology typical of Polima, they had very reduced petals. The broccoli type cybrids exhibited some female fertility, albeit low, establishing potential for F₁ hybrid production.     

Production of somatic hybrids between satsuma mandarin (Citrus unshiu) and navel orange (Citrus sinensis) by protoplast fusion

We have regenerated altotetraploid plants that are interspecific somatic hybrids between Citrus sinensis Osbeck cv. Yoshida navel orange and Citrus unshiu Marc cv. Okitsu satsuma mandarin. Protoplasts isolated from ‘Yoshida’ leaves were chemically fused with call us-derived protoplasts from ‘Okitsu’. After 6 months of culture, 102 plants were obtained. These hybrids were identified by differential leaf morphology, DNA fluorescence intensity, and DNA analysis. Ploidy analysis via the flow cytometry revealed that 15 of the 102 plants were tetraploids, with the rest being diploids that morphologically resembled their mesophyll parent. SRAP analysis confirmed that 9 of the tetraploid plants were allotetraploid somatic hybrids. These will be utilized as a possible pollen parents for improving seedy citrus cultivars, e.g., ponkan, mandarin, lemon and kumquat, in order to produce triploid seedless hybrids.     

Analyses of mitochondrial DNA structure and expression in three cytoplasmic male-sterile chicories originating from somatic hybridisation between fertile chicory and CMS sunflower protoplasts

Cytoplasmic male-sterile (CMS) chicories have been previously obtained by somatic hybridisation between fertile industrial chicory protoplasts and CMS sunflower protoplasts. In this study, we compared three different CMS chicory cybrids that originated from three different fusion events. The cybrids were backcrossed with different witloof chicories in order to transfer the three male-sterile cytoplasms from an industrial chicory nuclear environment to a witloof chicory nuclear context. Southern hybridisation, using different mitochondrial genes as probes, revealed that the three cybrid mitochondrial genomes were different and that they were stable throughout backcrossing generations regardless of the pollinator. However, pollinators were found to influence floral morphologies – with one being able to restore fertility – showing that nuclear context can affect the sterility of the cybrids. PCR and RFLP analyses revealed that the orf522 sequence, responsiblefor CMS in PET1 sunflower, was present in two out of the three cytoplasms studied, namely 411 and 523, but was absent from the other cytoplasm, 524. We thus concluded that orf522 is not responsible for CMS in the 524 cybrid. Although the orf522 gene is present in the 411 and 523 cytoplasms, it is probably not responsible for the sterile phenotype of these cybrids. Received: 3 June 1998 / Accepted: 30 April 1999     

Further evidence of a cybridization requirement for plant regeneration from citrus leaf protoplasts following somatic fusion

Summary Somatic hybridization experiments in Citrus that involve the fusion of protoplasts of one parent isolated from either nucellus-derived embryogenic callus or suspension cultures with leaf-derived protoplasts of a second parent, often result in the regeneration of diploid plants that phenotypically resemble the leaf parent. In this study, plants of this type regenerated following somatic fusions of the following three parental combinations were analyzed to determine their genetic origin (nuclear and organelle): (embryogenic parent listed first, leaf parent second) (1) calamondin (C. microcarpa Bunge) + Keen sour orange (C. aurantium L.), (2) Cleopatra mandarin (C. reticulata Blanco) + sour orange, and (3) Valencia sweet orange (C. sinensis (L.) Osbeck) + Femminello lemon (C. limon (L.) Burm. f.). Isozyme analyses of PGI, PGM, GOT, and IDH zymograms of putative cybrid plants, along with RFLP analyses using a nuclear genome-specific probe showed that these plants contained the nucleus of the leaf parent. RFLP analyses using mtDNA-specific probes showed that these plants contained the mitochondrial genome of the embryogenic callus donor, thereby confirming cybridization. RFLP analyses using cpDNA-specific probes revealed that the cybrid plants contained the chloroplast genome of either one or the other parent. These results support previous reports indicating that acquisition of the mitochondria of embryogenic protoplasts by leaf protoplasts is a prerequisite for recovering plants with the leaf parent phenotype via somatic embryogenesis following somatic fusion.Abbreviations cp chloroplast - GOT glutamateoxaloacetate transaminase - IDH isocitrate dehydrogenase - mt mitochondria - PEG polyethylene glycol - PGI phosphoglucose isomerase - PGM phosphoglucomutase - RFLP restriction fragment length polymorphism Florida Agricultural Experiment Station Journal Series No. R-04631.     

Protoplast-fusion-mediated transfer of organelles from Microcitrus into Citrus and regeneration of novel alloplasmic trees

Summary Iodoacetate-treated Citrus protoplasts from embryogenic nucellar calli of Sour orange (C. aurantium) or from Rough lemon (C. jambhiri) were fused with -irradiated protoplasts from a related genus, Microcitrus. The fused protoplasts were cultured to obtain colonies and micro-calli. Micro-calli derived from these two fusion combinations were isolated, propagated and differentiated into embryos, which subsequently regenerated trees having the morphology of Sour orange or Rough lemon. These intergeneric fusions resulted in mitochondria with novel DNA, indicating recombination between the chondriomes of Citrus and Microcitrus. Chloroplast DNA analyses of fusion-derived embryos indicated that they contained the chloroplasts of either fusion-partner or a mix of these chloroplasts. Later plastome analyses of leaves from fully differentiated plants showed that cybrids having Rough lemon morphology had either Rough lemon or Microcitrus chloroplast DNA, indicating complete sorting out of chloroplasts. Likewise, sorting out of Microcitrus chloroplasts was detected in a cybrid plant having Sour orange morphology.Contribution from the Agricultural Research Organization, The Volcani Center, Bet Dagan, 50250 Israel. No. 2663-E, 1989 series     

Production and molecular characterization of diploid and tetraploid somatic cybrid plants between male sterile Satsuma mandarin and seedy sweet orange cultivars

Seedlessness, an important economic trait for fresh fruit, is among the prior goal for all citrus breeding programs. Symmetric somatic hybridization provides a new strategy for citrus seedless breeding by creating cybrids transferring mitochondrial DNA (mtDNA) controlled cytoplasmic male sterility (CMS) from the callus parent Satsuma mandarin (C. unshiu Marc.) to seedy cultivars. In this study, protoplast fusion was adopted to transfer CMS from C. unshiu Marc. cv. Guoqing No. 1 (G1) to three seedy sweet oranges (C. sinensis L. Osb.), i.e. ‘Early gold’, ‘Taoye’ and ‘Hongjiang’. Flow cytometry analysis showed that 12 of 13 regenerated plants from G1 + ‘Early gold’, 9 of 12 from G1 + ‘Taoye’ and both two plants from G1 + ‘Hongjiang’ were diploids, while the remaining regenerated plants were tetraploids. Molecular analysis using 23 simple sequence repeat (SSR) markers previously proven to map to the citrus genome showed that the nuclear DNA from all recovered diploid and tetraploid plants derived from their corresponding leaf parent, while cleaved amplified polymorphic sequence analysis showed that the mtDNA of all regenerated plants derived from the callus parent, indicating that the regenerated 2X and 4X plants from all these three combinations are authentic cybrids. Furthermore, the Chloroplast SSR analysis revealed that somatic cybrid plants from the three combinations possessed either of their parental chloroplast type in most cases. These results demonstrated that mtDNA of G1 Satsuma mandarin was successfully introduced into the three seedy sweet orange cultivars for potential seedlessness via symmetric fusion.     

Targeted cybridization in citrus: transfer of Satsuma cytoplasm to seedy cultivars for potential seedlessness

CMS (cytoplasmic male sterility) can be controlled by the mitochondrion genome in higher plants, including Satsuma mandarin. Somatic fusion experiments in citrus combining embryogenic callus protoplasts of one parent with leaf protoplasts of a second parent often produce cybrid plants of the leaf parent, a phenomenon occurring most often with interspecific fusion combinations. In an attempt to practically exploit this cybridization phenomenon, we conducted somatic fusion experiments combining embryogenic suspension-derived protoplasts of Satsuma mandarin, Citrus unshiu Marc. cv. Guoqing No. 1 (G1), a male-sterile cultivar, with leaf protoplasts of other seedy types—Hirado Buntan Pink pummelo (HBP) [Citrus grandis (L.) Osbeck], Sunburst mandarin (C. reticulata Blanco), Orie Lee hybrid (C. reticulata cv. Clementine × Murcott tangor), and Murcott tangor [C. reticulata × C. sinensis (L.) Osbeck], respectively—in an attempt to generate seedless cybrids by the targeted transfer of CMS. The genetic identities of regenerated plants from all four parental combinations were determined by flow cytometry, SSR, CAPS (or PCR-RFLP), RFLP, and chloroplast-SSR analyses. Regenerated plants from the first three parental combinations were diploids, and the cybrid nature of G1 + HBP with the mitochondrion genome from G1 and the chloroplast genome from HBP was confirmed, whereas the cybrid nature of the remaining two combinations was difficult to confirm because of the close phylogenetic relatedness of both fusion parents, as expected. Plants from G1 + Murcott were confirmed as tetraploid somatic hybrids. This is the first report of targeted citrus cybrid production by symmetric fusion with male-sterile Satsuma as the callus parent and other seedy cultivars as the leaf parents.Abbreviations CAPS: Cleaved amplified polymorphic sequence - CMS: Cytoplasmic male sterility - cp-SSR: Chloroplast simple sequence repeat - PEG: Polyethylene glycol - SSR: Simple sequence repeat - RFLP: Restriction fragment length polymorphism Communicated by G.C. Phillips     

Molecular and ultrastructural analysis of a nonchromosomal variegated mutant. Tomato mitochondrial mutants that cause abnormal leaf development.

Mutants were recovered in a population of cybrids formed following protoplast fusion between tomato (Lycopersicon esculentum Mill.) cv UC82 and Lycopersicon pennellii Corr. The cybrids were identified as individuals with recombinant cytoplasmic genomes but only tomato nuclear genomes. The mutants were identified based on two features, a variegated sectoring of light and dark green regions on their leaves, stems, and fruit, and reduced growth in the field. The mutants produced 50% of the shoot fresh weight and 20% of the fruit fresh weight of the parental type, UC82. The variegated sectoring was maternally inherited. The chloroplast genome in the mutants was indistinguishable from the chloroplast genome in UC82, when distribution of restriction endonuclease sites was used as an assay. The mitochondrial genome in the mutants, however, was recombinant, containing genes from UC82 and L. pennellii. Light microscopic analysis of the leaves of the mutants demonstrated an absence of the palisade layer in the variegated sectors. Electron microscopic analysis of these same regions demonstrated an absence of normal inner membranes in the mitochondria of these cells.     

Comparative transcript profiling of a male sterile cybrid pummelo and its fertile type revealed altered gene expression related to flower development

Male sterile and seedless characters are highly desired for citrus cultivar improvement. In our breeding program, a male sterile cybrid pummelo, which could be considered as a variant of male fertile pummelo, was produced by protoplast fusion. Herein, ecotopic stamen primordia initiation and development were detected in this male sterile cybrid pummelo. Histological studies revealed that the cybrid showed reduced petal development in size and width, and retarded stamen primordia development. Additionally, disorganized cell proliferation was also detected in stamen-like structures (fused to petals and/or carpel). To gain new insight into the underlying mechanism, we compared, by RNA-Seq analysis, the nuclear gene expression profiles of floral buds of the cybrid with that of fertile pummelo. Gene expression profiles which identified a large number of differentially expressed genes (DEGs) between the two lines were captured at both petal primordia and stamen primordia distinguishable stages. For example, nuclear genes involved in nucleic acid binding and response to hormone synthesis and metabolism, genes required for floral bud identification and expressed in particular floral whorls. Furthermore, in accordance with flower morphology of the cybrid, expression of PISTILLATA (PI) was reduced in stamen-like structures, even though it was restricted to correct floral whorls. Down-regulated expression of APETALA3 (AP3) coincided with that of PI. These finding indicated that, due to their whorl specific effects in flower development, citrus class-B MADS-box genes likely constituted 'perfect targets' for CMS retrograde signaling, and that dysfunctional mitochondria seemed to cause male sterile phenotype in the cybrid pummelo.     

Protoplast fusion mediated transfer of oligomycin resistance from Nicotiana sylvestris to Solanum tuberosum by intergeneric cybridization

Summary We have successfully bridged the intergeneric barriers between Nicotiana and Solanum with respect to chondriome transfer. To enable this transfer we utilized the donor-recipient protoplast-fusion procedure. Consequently protoplasts of a Nicotiana sylvestris line with putativly oligomycin-resistant mitochondria (line Oli ^R 38) were used as irradiated chondriome donors and iodoacetate-treated protoplasts of Solanum tuberosum cv. Desiree served as recipients. The plated fusion products as well as their derived colonies and calli were exposed to gradually increasing levels of oligomycin. The resulting plantlets had potato morphology and were analyzed with respect to their mitochondrial DNA and chloroplast DNA. Fifteen out of 50 regenerated plants were verified as true cybrids. Detailed analyses of one cybrid revealed chondriome components from the oligomycin-resistant donor line, Oli ^R 38, but retention of the plastome of potato. This cybrid was oligomycin-resistant as revealed by root-culture analysis. It was thus verified that due to selection, chondriome components could be transferred from a N. sylvestris donor into a cybrid having all the phenotypic features controlled by the nucleus of the recipient fusion partner (S. tuberosum).     

Organelle transfer by microfusion of defined protoplast-cytoplast pairs

Summary Defined cybridization was performed by one-to-one electrofusion (microfusion) of preselected protoplast-cytoplast pairs of male-fertile, streptomycin-resistant Nicotiana tabacum and cytoplasmic male-sterile, streptomycin-sensitive N. tabacum cms (N. bigelovii), followed by microculture of the fusion products until plant regeneration. Dominant selectable markers, namely, kanamycin resistance (nptII) and hygromycin B resistance (hpt) genes had been previously integrated in the nuclear genomes of the otherwise almost fully isogenic parental strains using direct gene transfer to protoplasts. In addition to chromosome counts indicating the expected allotetraploid tobacco count of 48, the absence of the nucleus from the cytoplast donor line was confirmed by Southern blot hybridization using nptII and hpt probes, as well as by an in vitro selection test with leaf expiants and the corresponding enzyme assays for 30 cybrids. The cytoplasmic composition of the cybrids obtained was analyzed for chloroplast type using the streptomycin resistance/sensitivity locus. The fate of mitochondria in cybrids was checked by species-specific patterns in Southern analysis of restriction endonuclease digests of total DNA with N. sylvestris mitochondrial DNA probes.     

Protoplast electrofusion between common wheat (Triticum aestivum L.) and Italian ryegrass (Lolium multiflorum Lam.) and regeneration of mature cybrids

Summary This study describes the development of electrofusion techniques using the ‘donor-recipient’ model for the production of cybrids between common cultivated winter wheat (Triticum aestivum L.) cv. Jinghua No. 1 and a phylogenetically remote, sexually incompatible grass species, Italian ryegrass (Lolium multiflorum Lam.), which belong to two different subtribes: Triticinae and Loliinae. Wheat protoplasts were metabolically inactivated by iodoacetamide before fusion, while protoplasts of Italian ryegrass were X-ray irradiated before protoplast isolation. The suspension cells were directly used to optizmize the inactivation parameters. By exploring the minimum irreversible membrane breakdown strength, the electrofusion parameters were optimized just a few minutes before electrofusion began. A total of 108 green plantlets were obtained, and about half of the green plants uncontrollably necrotized. Among all green plants, 14 were rooted normally and transplanted in growth chamber or field and developed to maturity. All these transplanted plants were male sterile with smaller and off-white anthers. Seeds were obtained by crossing with Jinghua No. 1. Three transplanted regenerants possessed the characteristics of glume facing the rachis, which was the taxonomic characteristic distinguishing the two subtribes of Triticinae and Lolliinae. Although Southern blot hybridization analysis of 33 randomly selected regenerants using a wheat ribosomal DNA probe (pHA71) did not find any differences to wheat, analysis using two mitochondrial probes B342 (cox l), 490 (Pro II) and one chloroplastidic probe pHve H5 revealed that 31 plants were ‘true cybrids’ by showing ryegrass-specific band(s) or new band(s). It also showed that the mitochondria and chloroplasts were not coexistent as the restriction fragment length polymorphism band of Italian ryegrass was not detected by the mitochondrial probes 7 (26s), B342 (cox I), pHJ2-7-1 (cox II), B30 (atp9), and the chloroplast probe pHvc P5. To regenerate the cybrids, the regeneration capacity of the recipient (wheat) was crucial in this study.