Organelle transfer. Plant Molecular Biology. Elsevier; 1986. pp. 595-611. [DOI: 10.1016/0076-6879(86)18103-1]

A point mutation in the chloroplast rps12 gene from Nicotiana plumbaginifolia confers streptomycin resistance

In an effort to understand the mechanism of streptomycin resistance in Nicotiana plumbaginifolia, we have sequenced the chloroplast rps12 gene, a potential molecular target. We report that a streptomycin-resistant mutant isolated from protoplast cultures of N. plumbaginifolia contains an A-to-G transition at nucleotide position 149 in exon 2 of the chloroplast rps12 gene. The detected point mutation predicts a substitution of arginine for lysine in a phylogenetically conserved region.

Analysis of the mitochondrial DNA of the somatic hybrids of Solanum brevidens and S. tuberosum using non-radioactive digoxigenin-labelled DNA probes

Mitochondrial (mt) DNAs of somatic hybrids obtained by electrical and chemical fusion of mesophyll protoplasts of S. brevidens and a dihaploid line of S. tuberosum PDH 40 were analysed by Southern hybridization using the digoxigenin-labelled mtDNA sequences nad5 or orf25. In the Southern analysis of the hybrid mtDNA probed with nad5, most of the 19 hybrids analyzed had an RFLP pattern similar, but not identical, to one of the parents, S. tuberosum, PDH40. Nineteen percent of the hybrids had most of the S. brevidens fragments. Five of the hybrids had an identical RFLP pattern to either one of the parents while another two hybrids had novel RFLP patterns. Similar results were obtained by Southern analysis with orf25. These results clearly show that mtDNA rearrangements had occurred at a high frequency in the somatic hybrids. There were no differences in the frequencies of rearrangements observed between the hybrids regenerated from chemical and electrical fusions.

Subcellular location of lincomycin resistance in Nicotiana mutants

Lincomycin-resistant Nicotiana plumbaginifolia plastid mutants were considered also to carry mitochondrial mutations on the basis of their ability to grow in the dark under selective conditions. To clarify the role of mitochondria, individual protoplasts of the green, lincomycin-resistant N. plumbaginifolia mutant LR400 were microfused with protoplasts of the N. tabacum plastid albino line 92V37, which possesses N. undulata cytoplasm. the production of lincomycin-resistant albino cybrid lines, with N. undulata plastids and recombinant mitochondria, strongly indicated a determining role for mitochondria in the lincomycin resistance. Sequence analysis of the region encompassing putative mutation sites in the 26S rRNA genes from the LR400 and several other lincomycin-resistant N. plumbaginifolia mutants revealed, however, no differences from the wild-type sequence. As an alternative source of the resistance of the fusion products, the N. tabacum fusion partner was also taken into account. Surprisingly, a natural lincomycin resistance of tobacco was detected, which was inherited as a dominant nuclear trait. This result compromises the interpretation of the fusion data suggested above. Thus, to answer the original question definitively, the mutant LR400 was crossed as a female parent with a N. plumbaginifolia line carrying streptomycin-resistant N. tabacum plastids. Calli were then induced from the seedlings. Occasional paternal plastid transmissions were selected as streptomycin-resistant calli on selective medium. These cell lines were shown by restriction enzyme analysis to contain paternal plastids and maternal mitochondria. They were tested for greening and growing ability in the presence of lincomycin. These resistance traits proved to be genetically linked and exclusively located in the plastids.

Nuclear-organelle interaction in Solanum: interspecific cybridizations and their correlation with a plastome dendrogram

Alloplasmic compatibility, namely the functional interaction between the nuclear genome of a given species with plastomes and chondriomes of alien species, is of considerable relevance in plant biology. The genus Solanum encompasses a wide spectrum of species and is therefore suitable for a study of this compatibility. We thus chose the nuclear genome of Solanum tuberosum (potato) and organelles (chloroplast and mitochondria) from 14 other Solanum species to initiate an investigation of intrageneric nucleus/organelle interactions. An assessment of the diversity of the chloroplast DNAs from these 15 species resulted in the construction of a plastome dendrogram (phylogenetic tree). In parallel we extended a previous study and performed ten additional fusion combinations by the "donor-recipient protoplast fusion" procedure, using potato protoplasts as recipients and protoplasts from any of ten other Solanum species as donors. We found that two fusion combinations did not yield cybrids and that the chloroplasts of S. polyadenium and the mitochondria (or mitochondrial components) from S. tarijense could not be transferred to cybrids bearing potato nuclei. In general, there is a correlation, albeit not perfect, between the cybridization data and the plastome dendrogram. These results furnish valuable information toward future transfer of plasmone-encoded breeding traits from wild Solanum species into potato. This information should also be useful for the planning of asymmetric protoplast fusion between potato and wild accessions for the improvement of pathogen and stress resistance of potato cultivars.

Transfer of defined numbers of chloroplasts into albino protoplasts using an improved subprotoplast/protoplast microfusion procedure: transfer of only two chloroplasts leads to variegated progeny

A procedure is described by which it is possible to perform controlled microfusion of microscopically selected protoplast fusion partners with high efficiencies. The procedure is applied to fusion of Nicotiana tabacum (line 92V37. N. undulata cytoplasm) plastid albino protoplasts as a recipient and spontaneously formed subprotoplasts of green N. tabacum (line SR1) as donor. Products of individual electrofusion events are cloned via single cell nurse culture and the derived cell lines are analysed for the occurrence of variegated or green regenerating shoots, which are indicative of the establishment of the transferred organelles in the cell progeny. The plastid population in green regenerants recovered after the transfer of only two chloroplasts was demonstrated to have originated from the donor subprotoplast organelles by restriction analysis of total DNA using a plastome-specific probe.

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

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 putatively oligomycin-resistant mitochondria (line OliR38) 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, OliR38, 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).

Protoplast-fusion-derived Solanum cybrids: application and phylogenetic limitations

We established interspecific Solanum cybrids in order to study the intrageneric nuclear-organelle compatibility and the introgression of advantageous plasmone-coded breeding traits into potato. Cybridization was performed by the donor-recipient protoplast-fusion procedure. We found that the plastomes of S. chacoense, S. brevidens, and S. etuberosum could be transferred into the cybrids having S. tuberosum nuclear genomes; chondriome components were likewise transferred from the former species into these cybrids. The combination with S. chacoense as organelle donor and potato as recipient resulted in green fertile plants with potato morphology. By using S. etuberosum as an organelle donor and potato as recipient, male-sterile cybrid plants, most of them having pigmentation abnormalities, were obtained. The combination of S. brevidens with potato resulted in palegreen (almost albino) regenerants. The latter albino plantlets had both the chloroplast DNA and the mitochondrial DNA of the donor (S. brevidens) and did not survive the transfer into the greenhouse. An immediately applicative result of this study is the de novo establishment of male-sterile plants in a potato cultivar. Such plants should be useful as seed parents in the production of hybrid, true-potato seeds.

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

Iodoacetate-treated Citrus protoplasts from embryogenic nucellar calli of Sour orange (C. aurantium) or from Rough lemon (C. jambhiri) were fused with γ-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.

Chondriome analysis in sexual progenies of Nicotiana cybrids

We studied the chondriomes (the mitochondrial genomes) of sexual-progeny plants derived from eleven Nicotiana cybrids which resulted from donor-recipient protoplast fusions. The recipients were either N. tabacum or N. sylvestris and the donor (of the cytoplasm) was N. bigelovii. The chondriomes were characterized by the mitochondrial DNA (mtDNA) restriction-patterns. The differences in mtDNA restriction patterns were revealed after Sal I digestions and probing the respective Southern-blots with three mtDNA fragments. The hybridization patterns of mtDNAs from 35 second-generation plants (i.e. the sexual progeny derived from the cybrid plants) indicated only minor variations between plants derived from the same cybrid but pronounced variations among sibs derived from different cybrids. The mtDNA of 32 second-generation plants varied from both original fusion partners but the mtDNA of one (male-sterile) plant was apparently identical with the mtDNA of one of the original donor (N. bigelovii) and the mtDNA of two other (male-fertile) plants was apparently identical to the mtDNA of an original recipient (N. sylvestris). Generally, the mtDNAs of male-fertile, second-generation plants were similar to the mtDNAs of the original recipients while the mtDNAs of the male-sterile second-generation plants were similar to the mtDNA of the donor (N. begelovii). The analyses of mtDNAs from the thirdgeneration plants indicated stabilization of the chondriomes; no variations were detected between the mtDNAs of plants derived from a given second-generation plant.

A protoplast-to-tree system in Microcitrus based on protoplasts derived from a sustained embryogenic callus

Adventitious embryos derived from a zygotic embryo in an in vitro cultured ovule of Microcitrus were transferred several times on solidified medium containing benzyladenine and 3-indoleacetyl-L-alanine to induce embryogenic callus. This callus was maintained for several years on medium devoid of growth regulators without losing its embryogenic capacity. Exposure of this callus to maceration enzymes led to protoplast suspensions. Purified protoplasts were plated in solid medium devoid of growth regulators. Somatic embryos were derived efficiently from individual protoplasts and most of these could be regenerated into mature trees bearing normal flowers and typical fruits. This system differs from the Citrus protoplast-to-tree system. In the latter embryogenic callus was derived from the nucellus of polyembryonic species while Microcitrus is monoembryonic and required hormone-induced callus formation from proliferating zygotic embryos.

Restoration of male fertileNicotiana by fusion of protoplasts derived from two different cytoplasmic male-sterile cybrids

Using the 'donor-recipient' protoplast-fusion technique, we have recently constructed several alloplasmic-like lines ofNicotiana in which the original cytoplasms (or part of them) of eitherN. tabacum orN. sylvestris were replaced respectively, either byN. undulata or byN. bigelovii cytoplasms. These cybridizations resulted in two kinds of cytoplasmic male-sterile (CMS) cybrid plants:N. tabacum withN. undulata-like cytoplasm andN. sylvestris withN. bigelovii-like cytoplasm. Fusion of protoplasts, derived from the above two CMS types, by the 'donor-recipient' technique, lead to the recovery of 21 cybrid calli. One of these regenerated a cybrid with fertile pollen but having shortened filaments and slighly tappered anthers. Self pollination of the latter cybrid resulted in a second generation progeny having almost normal filaments and anthers. Further selfings produced a third generation in which numerous plants had normal stamens and fertile pollen. Mitochondrial DNA (mtDNA) analysis of second and third generation progenies revealed a novel pattern which differed from each of the parental CMS cybrids and also from the mtDNA of normal, male-fertileNicotiana species. The results suggest that mtDNA recombination between different types of CMS can lead to restoration of male-fertility.

Does pretreatment by rhodamine 6-G affect the mitochondrial composition of fusion-derived Nicotiana cybrids?

Rhodamine-6G(R6G), a lipophilic dye which degrades mammalian mitochondria, was shown to arrest the division of Nicotiana protoplasts. When albino recipient-protoplasts were treated with R6G and fused with X-irradiated (green) donor- protoplasts, only green cybrid plants were obtained. The mtDNA of the cybrids was analyzed by Southern-blot hybridization. We found that cybrids which resulted from N. rustica (donor) protoplasts, fused with R6G-treated albino protoplasts, had only parental-type mtDNA. When another donor, with N. undulata mtDNA, was used, most of the resulting cybrids contained non-parental mtDNA. Only one cybrid (out of 12) had N. undulata -type (donor) mtDNA.