Interspecific protoplast fusion to rescue a cytoplasmic lincomycin resistance mutation into fertile Nicotiana plumbaginifolia plants

Summary A lincomycin-resistant cell line, LR105, was isolated in a mutagenized (0.1 mM N-ethyl-N-nitrosourea) callus culture initiated from a haploid Nicotiana sylvestris plant. The regenerated plants had an abnormal morphology and did not set viable seeds.Transfer of lincomycin resistance was attempted from the original N. sylvestris nuclear background into Nicotiana plumbaginifolia by protoplast fusion, since it was expected that resistance would be cytoplasmically coded. LR105 protoplasts were irradiated with a lethal dose (120 J kg^-1; ⁶⁰ Co source), fused with sensitive N. plumbaginifolia protoplasts and the colonies grown from the fused population were screened for lincomycin resistance. Expression of resistance was expected only if the cytoplasm of the irradiated cells had mixed with nonirradiated cytoplasm, and was reactivated as a result of cell fusion (Menczel et al. 1982).Plants were regenerated in 44 resistant clones. Plants in 41 clones had a N. plumbaginifolia nuclear genome. In three clones somatic hybrids were obtained. The resistant N. plumbaginifolia cybrid plants were fertile, unlike the original LR105 plants. Lincomycin resistance was inherited maternally in the eight clones in which crosses were made. In these clones the introduction of N. sylvestris chloroplasts into a N. plumbaginifolia nuclear background was confirmed by the SmaI restriction endonuclease pattern of the chloroplast DNA. The involvement of chloroplast DNA in determining lincomycin resistance is therefore implied.     

Differential fate of plastid and mitochondrial genomes in Petunia somatic hybrids

Summary The chloroplast (cp) and mitochondrial (mt) DNAs of Petunia somatic hybrid plants, which were derived from the fusion of wild-type P. parodii protoplasts with albino P. inflata protoplasts, were analyzed by endonuclease restriction and Southern blot hybridization. Using ³²P-labelled probes that distinguished the two parental cpDNAs at a BamH1 site and at a HpaII site, only the P. parodii chloroplast genome was detected in the 10 somatic hybrid plants analyzed. To examine whether cytoplasmic mixing had resulted in rearrangement of the mitochondrial genome in the somatic hybrids, restriction patterns of purified somatic hybrid and parental mtDNAs were analyzed. Approximately 87% of those restriction fragments which distinguish the two parental genomes are P. inflata-specific. Restriction patterns of the somatic hybrid mtDNAs differ both from the parental patterns and from each other, suggesting that an interaction occurred between the parental mitochondrial genomes in the somatic fusion products which resulted in generation of the novel mtDNA patterns. Southern blot hybridization substantiates this conclusion. In addition, somatic hybrid lines derived from the same fusion product were observed to differ in mtDNA restriction pattern, reflecting a differential sorting-out of mitochondrial genomes at the time the plants were regenerated.     

Regeneration of somatic hybrid plants formed between Lycopersicon esculentum and Solatium rickii

Summary A single somatic hybrid callus clone was identified following the fusion of Lycopersicon esculentum protoplasts and Solanum rickii suspension culture protoplasts. The hybrid nature of the callus and the plants regenerating from it was determined by assaying phosphoglucomutase-2 isozyme expression. The chloroplast genome present in four somatic hybrid plants was characterized by probing digests of total DNA with nick translated L. esculentum chloroplast DNA(cpDNA). All four somatic hybrid plants had inherited S. rickii cpDNA. Two clones of plant mitochondrial DNA (mtDNA), soybean 18S and 5S rDNA and maize cytochrome oxidase subunit II were used to characterize the mtDNA present in total DNA digests of four somatic hybrid plants. In both cases, the somatic hybrid plants had inherited most but not all of the S. rickii specific fragments, but none of the L. esculentum specific fragments.     

Independent segregation of the plastid genome and cytoplasmic male sterility in Petunia somatic hybrids

Summary The chloroplast genomes of three sets of Petunia somatic hybrids were analyzed to examine the relationship between chloroplast DNA (cpDNA) composition and cytoplasmic male sterility (CMS). Chloroplast genomes of somatic hybrid plants were identified either by restriction and electrophoresis of purified cpDNAs or by hybridization of total DNA digests with cloned cpDNA probes that distinguish the parental genomes.The chloroplast genomes of a set of seven somatic hybrids derived from the fusion of Petunia CMS line 2423 and fertile line 3699 were analyzed. All seven plants were fertile, and all exhibited the cpDNA restriction pattern of the sterile cytoplasm. Similarly, four fertile somatic hybrids derived from the fusion of CMS line 3688 and fertile line 3677 were found to contain the CMS chloroplast genome. The cpDNA compositions of four fertile and two sterile somatic hybrids derived from the fusion of CMS line 3688 and fertile line 3704 were determined by restriction analysis of purified cpDNAs; all six plants exhibited the cpDNA restriction pattern of line 3704. Thus the CMS phenotype segregates independently of the chloroplast genome in Petunia somatic hybrids, indicating that CMS in Petunia is not specified by the chloroplast genome.     

Metabolic complementation for a single gene function associated with partial and total loss of donor DNA in interspecific somatic hybrids

Summary We report here on the obtainment of interspecific somatic, asymmetric, and highly asymmetric nuclear hybrids via protoplast fusion. Asymmetric nuclear hybrids were obtained after fusion of mesophyll protoplasts from a nitrate reductase-deficient cofactor mutant of N. plumbaginifolia with irradiated (100 krad) kanamycin resistant leaf protoplasts of a haploid N. tabacum. Selection for nitrate reductase (NR) and/or kanamycin (Km) resistance resulted in the production of three groups of plants (NR⁺, NR⁺, Km^R, and NR^-Km^R). Cytological analysis of some hybrid regenerants showed the presence of numerous tobacco chromosomes and chromosome fragments, besides a polyploid N. plumbaginifolia genome (tetra or hexaploid). All the regenerants tested were male sterile but some of them could be backcrossed to the recipient partner. In a second experiment, somatic and highly asymmetric nuclear hybrids were obtained after fusion of mesophyll protoplasts from the universal hybridizer of N. plumbaginifolia with suspension protoplasts of a tumor line of N. tabacum. Selection resulted in two types of colonies: nonregenerating hybrid calli turned out to be true somatic hybrids, while cytological analysis of regenerants obtained on morphogenic calli did not show any presence of donor-specific chromosomes. Forty percent of the hybrid regenerants were completely fertile, while the others could only be backcrossed to the recipient N. plumbaginifolia. Since the gene we selected for is not yet cloned, we were not able to demonstrate the transfer of genetic material at the molecular level. However, since no reversion frequency for the nitrate reductase mutant is known, and due to a detailed cytological knowledge of both fusion partners, we feel confident in speculating that intergenomic recombination between N. plumbaginifolia and N. tabacum has occurred.     

Regeneration of somatic hybrid plants formed between Lycopersicon esculentum and L. pennellii

Summary Somatic hybrid plants have been regenerated following polyethylene glycol mediated fusion of leaf mesophyll protoplasts from tomato and protoplasts from Lycopersicon pennellii callus. Three different cultivars of tomato were used as sources of protoplasts: Early Girl, Manapal, and UC82B. Fusions were performed between protoplasts of these tomato cultivars and protoplasts of L. pennellii, and between protoplasts of the cultivars and protoplasts of L. pennellii that had been exposed to 3 or 6 krads of gamma radiation. Somatic hybrid plants were identified on the basis of heterozygous isozyme banding patterns, and leaf and flower morphology. Somatic hybrid plants were regenerated following fusion of tomato protoplasts with either untreated or irradiated L. pennellii protoplasts. All were heterozygous for isozyme loci on five different chromosomes. Regenerated somatic hybrids showed inheritance of either or both parental chloroplast genomes, but predominantly the L. pennellii mitochondrial genome. The regenerated somatic hybrid plants exhibited reduced fertility, less than 20% viable pollen. A total of 34 somatic hybrid calli were identified. Of these, 21 regenerated shoots, and 7 produced seed following manual pollinations.     

Chloroplast transfer in Nicotiana based on metabolic complementation between irradiated and iodoacetate treated protoplasts

Protoplasts of a light sensitive plastome mutant of Nicotiana tabacum (2 n=48) were irradiated and fused with iodoacetate-treated Nicotiana plumbaginifolia (2 n=20) protoplasts. Treated parental protoplasts were unable to divide. Metabolic complementation, however, helped the recovery of interspecific fusion products which survived and formed calli. Altogether 40 clones were investigated. N. plumbaginifolia plants were obtained in 15 clones (38%), somatic hybrids in 23 clones, and both types of regenerates were found in 2 clones. Irradiation therefore significantly increased the frequency of segregant formation with the non-irradiated N. plumbaginifolia nuclei (the frequency was 1.4% in the absence of irradiation). Regenerated plants in most cases (31 out of 34) contained chloroplasts from the irradiated parent. In 6 clones plants were obtained with both types of chloroplast. Thus, irradiated N. tabacum chloroplasts had an improved chance of dominating the heterokaryonderived cells, many of which contained N. plumbaginifolia nucleus. The system described should be generally applicable for the transfer of chloroplasts without the use of selectable genetic markers.     

Comparative studies on the structural gene for the ribosomal protein S1 in ten bacterial species

Summary Callus protoplasts of a plastome chlorophyll-deficient mutant of tobacco, Nicotiana tabacum, were fused with mesophyll protoplasts from one of the following five sources: cms-analogs of tobacco bearing the cytoplasms of N. suaveolens, N. undulata, N. repanda, and N. plumbaginifolia, respectively, and the wild species N. glauca. In the sixth experiment, callus cells of the tobacco chlorophyll-deficient genome mutant, homozygous for the Su gene, were hybridized with mesophyll protoplasts of the plastome chlorophyll-deficient mutant of tobacco. Individual dividing heteroplasmic fusion products were isolated mechanically and cloned in microdroplets of nutrient medium. Among the regenerants in all parental combinations, though not in all clones, besides pure green and pure chlorophyll-deficient plants, numerous variegated plant forms were obtained. The variegation of cybrid and hybrid plants was connected with their heterozygocity for chloroplast DNA composition, as demonstrated by restriction analysis. In analytical crosses, the variegation was inherited maternally by part of the sexual progeny, and variegated F₁ progeny were also heterozygous for chloroplast DNA composition. As demonstrated by electron microscopic studies, the variegation is connected with the presence of mixed, i.e., heteroplastidic cells in leaves. The results obtained demonstrate that (1) upon somatic cell fusion, plastome genes are inherited biparentally in most fusion products, and (2) despite an evident mitotic segregation process, heterozygosity for plastome genes is a relatively durable state and can be revealed in cell hybrids of different specific combinations of plasmons after a great number of cell generations. In this regard the plastome cytogetes obtained by somatic cell fusion do not differ qualitatively from the cytoplasmic heterozygotes that arise as a result of the mutation process.     

Regeneration of asymmetric somatic hybrid plants from the fusion of two types of wheat with Russian wildrye

Two types of protoplasts of wheat (Triticum aestivum L. cv. Jinan 177) were used in fusion experiments—cha9, with a high division frequency, and 176, with a high regeneration frequency. The fusion combination of either cha9 or 176 protoplasts with Russian wildrye protoplasts failed to produce regenerated calli. When a mixture of cha9 and 176 protoplasts were fused with those of Russian wildrye, 14 fusion-derived calli were produced, of which seven differentiated into green plants and two differentiated into albinos. The morphology of all hybrid plants strongly resembled that of the parental wheat type. The hybrid nature of the cell lines was confirmed by cytological, isozyme, random amplified polymorphic DNA (RAPD) and genomic in situ hybridization (GISH) analyses. GISH analysis revealed that only chromosome fragments of Russian wildrye were transferred to the wheat chromosomes of hybrid calli and plants. Simple sequence repeat (SSR) analysis of the chloroplast genome of the hybrids with seven pairs of wheat-specific chloroplast microsatellite primers indicated that all of the cell lines had band patterns identical to wheat. Our results show that highly asymmetric somatic hybrid calli and plants can be produced via symmetric fusion in a triparental fusion system. The dominant effect of two wheat cell lines on the exclusion of Russian wildrye chromosomes is discussed.Abbreviations GISH Genome in situ hybridization - RAPD Random amplified polymorphic DNA - SCF Small chromosome fragment - SSR Simple sequence repeat     

Effect of radiation dosage on efficiency of chloroplast transfer by protoplast fusion in Nicotiana

Chloroplasts of Nicotiana tabacum SR1 were transferred into Nicotiana plumbaginifolia by protoplast fusion. The protoplasts of the organelle donor were irradiated with different lethal doses using a ⁶⁰Co source, to facilitate the elimination of their nuclei from the fusion products. After fusion induction, clones derived from fusion products and containing streptomycin-resistant N. tabacum SR1 chloroplasts were selected by their ability to green on a selective medium. When N. tabacum protoplasts were inactivated by iodoacetate instead of irradiation, the proportion of N. plumbaginifolia nuclear segregant clones was low (1–2%). Irradiation markedly increased this value: Using 50, 120, 210 and 300 J kg^-1 doses, the frequency of segregant clones was 44, 57, 84 and 70 percent, respectively. Regeneration of resistant N. plumbaginifolia plants with SR1 chloroplasts indicated that plastids can be rescued from the irradiated cells by fusion with untreated protoplasts. Resistant N. plumbaginifolia plants that were regenerated (43 clones studied) had diploid (2n = 2X = 20) or tetraploid chromosome numbers and were identical morphologically to parental plants. The absence of aneuploids suggests that in these clones irradiation resulted in complete elimination of the irradiated N. tabacum nuclei. Resistance is inherited maternally (five clones tested). The demonstration of chloroplast transfer and the presence of N. tabacum plastids in the N. plumbaginifolia plants was confirmed by chloroplast DNA fragmentation patterns after EcoRI digestion.     

Intergeneric somatic hybridization in Gramineae: somatic hybrid plants between tall fescue (Festuca arundinacea Schreb.) and Italian ryegrass (Lolium multiflorum Lam.)

Summary Tall fescue (Festuca arundinacea Schreb.) protoplasts, inactivated by iodoacetamide, and non-morphogenic Italian ryegrass (Lolium multiflorum Lam.) protoplasts, both derived from suspension cultures, were electrofused and putative somatic hybrid plants were recovered. Two different genotypic fusion combinations were carried out and several green plants were regenerated in one of them. With respect to plant habitus, leaf and inflorescence morphology, the regenerants had phenotypes intermediate between those of the parents. Southern hybridization analysis using a rice ribosomal DNA probe revealed that the regenerants contained both tall fescue- and Italian ryegrass-specific-DNA fragments. A cloned Italian ryegrass-specific interspersed DNA probe hybridized to total genomic DNA from Italian ryegrass and from the green regenerated somatic hybrid plants but not to tall fescue. Chromosome counts and zymograms of leaf esterases suggested nuclear genome instability of the somatic hybrid plants analyzed. Four mitochondrial probes and one chloroplast DNA probe were used in Southern hybridization experiments to analyze the organellar composition of the somatic hybrids obtained. The somatic hybrid plants analyzed showed tall fescue, additive or novel mtDNA patterns when hybridized with different mitochondrial gene-specific probes, while corresponding analysis using a chloroplast gene-specific probe revealed in all cases the tall fescue hybridization profile. Independently regenerated F. arundinacea (+) L. multiflorum somatic hybrid plants were successfully transferred to soil and grown to maturity, representing the first flowering intergeneric somatic hybrids recovered in Gramineae.     

Molecular analysis of the nuclear organellar genotype of somatic hybrid plants between tomato (Lycopersicon esculentum) and Lycopersicon chilense

Summary Somatic hybrid plants were recovered following fusion of leaf mesophyll protoplasts isolated from tomato (Lycopersicon esculentum) cultivar UC82 with protoplasts isolated from suspension cultured cells of L. chilense, LA 1959. Iodoacetate was used to select against the growth of unfused tomato protoplasts. Two somatic hybrids were recovered in a population of 16 regenerants. No tomato regenerants were recovered; all of the non-hybrid regenerants were L. chilense. The L. chilense protoplast regenerants were tetraploid. The hybrid nature of the plants was verified using species-specific restriction fragment length polymorphisms for the nuclear, chloroplast and mitochondrial genomes. The somatic hybrids had inherited the chloroplast DNA of the tomato parent, and portions of the mitochondrial DNA of the L. chilense parent. The somatic hybrids formed flowers and developed seedless fruit.     

Non-random inheritance of organellar genomes in symmetric and asymmetric somatic hybrids between Lycopersicon esculentum and L. pennellii

Summary The organization of the mitochondrial genome and the genotype of the chloroplast genome was characterized using restriction fragment length polymorphisms in a population (82 individuals) of symmetric and asymmetric somatic hybrids of tomato. The protoplast fusion products were regenerated following the fusion of leaf mesophyll protoplasts of Lycopersicon esculentum (tomato cv UC82) with suspension cell protoplasts of L. pennellii that had been irradiated with 5, 10, 15, 25, 50, or 100 kRads from a gamma source. The chloroplast genome in the somatic hybrids showed a random pattern of inheritance, i.e., either parental genome was present in equal numbers of regenerants, while in asymmetric somatic hybrids, the chloroplast genotype reflected the predominant nuclear genotype, i.e., tomato. The mitochondrial genome in the symmetric somatic hybrids showed a non-random pattern of inheritance, i.e., predominantly from the L. pennellii parent; asymmetric somatic hybrids had more tomato-specific mitochondrial sequences than symmetric somatic hybrids. The non-random inheritance of the chloroplast and mitochondrial DNA in these tomato protoplast fusion products appears to be influenced by the nuclear background of the regenerant.     

Molecular,cytogenetic and morphological characterization of somatic hybrids of dihaploid Solanum tuberosum and diploid S. brevidens

Summary Fifty-eight somatic hybrid plants, produced both by chemical (11) and electrical fusion (47) of protoplasts of dihaploid Solanum tuberosum and S. brevidens, have been analysed by molecular, cytological and morphological methods. The potentially useful euploid plants constituted 34% of the total, of which 20% were tetraploid and 14% hexaploid; the remainder were aneuploid at the tetraploid, hexaploid and octoploid levels. Analysis of chloroplast DNA showed that 55% of hybrids contained chloroplasts from S. brevidens and 45% from S. tuberosum. Hexaploids, the products of three protoplasts fusing together, were analyzed with specific DNA probes, and this revealed that nuclear genome dosages could be either 21 S. tuberosumS. brevidens, or vice-versa. Chloroplast types of hexaploids were not influenced by nuclear genome dosage, and all six possible combinations of genome dosage and chloroplast types were found amongst tetraploids and hexaploids. To examine the morphology of the hybrid population and its possible relation to the chromosome number and chloroplast DNA type, 18 morphological characteristics were measured on greenhouse-grown plants and analyzed by principal component and canonical variate analyses. Both analyses showed that nuclear ploidy has the most prominent influence on the overall morphology of the hybrids. Differential parental genome expression in the morphology of the hybrids is discussed. These results provide useful data on the range of genetic combinations that can be expected to occur amongst somatic hybrid plants.     

Transmission of organelle genomes in citrus somatic hybrids

Restriction fragment length polymorphisms (RFLPs), were used to analyze the organelle composition of two-year-old trees, recovered from two different experiments: protoplasts from embryogenic cell suspensions of `Succari' sweet orange (C. sinensis L. Osbeck) were fused with leaf protoplasts of Citropsis gilletiana Swingle & M. Kell or to leaf protoplasts of Atalantia ceylanica(Arn.) Oliv. The somatic hybrids of both fusion combinations had the mitochondrial genome from the embryogenic partner. In some somatic hybrids, non-parental fragments were observed among the mitochondrial patterns. Somatic hybrids between `Succari' + Atalantia had plastid DNA from the embryogenic parent, while the somatic hybrids of `Succari' + Citropsis all had both parental chloroplast genomes. The relative abundance of organelle DNAs in the donor embryogenic and leaf cells may explain the consistent transmission of the embryogenic parent mitochondrial DNA and the inheritance of the chloroplast genome from either parent. This revised version was published online in June 2006 with corrections to the Cover Date.     

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.     

Amplification of repetitive DNA from Nicotiana plumbaginifolia in asymmetric somatic hybrids between Nicotiana sylvestris and Nicotiana plumbaginifolia

Summary Asymmetric somatic hybrids were obtained between a chlorophyll-deficient mutant of Nicotiana sylvestris (V42) and a nitrate-reductase (NR)-deficient line of N. plumbaginifolia (cnx20 or Nia26), using each of the parents alternately as the irradiated donor. Irradiation doses applied ranged from 10 to 1,000 Gy of gamma-rays. Hybrid selection was based on complementation of NR deficiency with wild-type NR genes. To aid in the analysis of somatic hybrids, species-specific repetitive DNA sequences from N. plumbaginifolia (NPR9 and NPR18) were cloned. NPR18 is a dispersed repetitive sequence occupying about 0.4% of the N. plumbaginifolia genome. In turn, NPR9, which is part of a highly repetitive DNA sequence, occupies approximately 3% of the genome. The species-specific plant DNA repeats, together with cytological analysis data, were used to assess the relative amount of the N. plumbaginifolia genome in the somatic hybrids. In fusion experiments using irradiated N. plumbaginifolia, an increase in irradiation dose prior to fusion led to a decrease in N. plumbaginifolia nuclear DNA content per hybrid genome. For some hybrid lines, an increase in the quantity of repetitive sequences was detected. Thus, hybrid lines 1NV/21, 100NV/7, 100NV/ 9, and 100NV/10 (where N. plumbaginifolia was the irradiated donor) were characterized by amplification of NPR9. In the reverse combination (where N. sylvestris was the irradiated donor), an increase in the copy number of NPR18 was determined for hybrid clones 1VC/2, 1VC/3, 100VC/2 and oct100/7. Possible reasons for the amplification of the repeated sequences are discussed.     

A light sensitive recipient for the effective transfer of chloroplast and mitochondrial traits by protoplast fusion in Nicotiana

Summary A light sensitive mutant was used as a recipient in the transfer of chloroplasts from a wildtype donor. Gamma irradiated (lethal dose) mesophyll protoplasts of Nicotiana gossei were fused with mesophyll protoplasts of a N. plumbaginifolia line carrying light sensitive plastids from a N. tabacum mutant. After fusion, colonies containing wild-type plastids from the cytoplasm donor were selected by their green colour. Most of the regenerated plants had N. plumbaginifolia morphology, but were a normal green in colour. The presence of donor-type plastids was confirmed by the restriction pattern of chloroplast DNA in each plant analysed. These cybrids were fully male sterile with an altered flower morphology typical of certain types of alloplasmic male sterility in Nicotiana. The use of the cytoplasmic light sensitive recipient proved to be suitable for effective interspecific transfer of wild-type chloroplasts. The recombinant-type mitochondrial DNA restriction patterns and the male sterility of the cybrids indicated the co-transfer of chloroplast and mitochondrial traits. On leave from: Department of Genetics, Section of Biosciences, Martin Luther University, Domplatz 1, DDR-4020 Halle/ S., German Democratic Republic     

Fusion-mediated transfer of triazine-resistant chloroplasts: Characterization of Nicotiana tabacum cybrid plants

Summary Terbutryn-resistant plastids of the Nicotiana plumbaginifolia TBR2 mutant were introduced into N. tabacum plants by protoplast fusion following X-irradiation of TBR2 protoplasts. The N. tabacum chloroplast recipient line, SR1-A15, carried mutant (albino) plastids. Following protoplast fusion, potential cybrid cell lines with an N. tabacum (SR1-A15) nucleus and N. plumbaginifolia (TBR2) chloroplasts were identified by their green color. The presence of TBR2 plastids in regenerated green N. tabacum plants was confirmed by hybridization with a chloroplast DNA probe and by the modified chloroplast fluorescence transients characteristic of the TBR2 mutant. Cybrid plants were resistant to high levels of atrazine (10 kg/ha). The protruding stigma and shorter than normal filaments of the cybrids resulted in male sterility. In the cybrids atrazine resistance was associated with reduced vigour, suggesting a causal relationship.     

Detection of the Nicotiana rustica chloroplast genome coding for the large subunit of Fraction I protein in a somatic hybrid in which only the N. tabacum chloroplast genome appeared to have been expressed

Nine plants were produced from anthers of a somatic hybrid which had been obtained by fusion of Nicotiana tabacum L. and N. rustica L. protoplants. As determined by electrofocusing, the Fraction I protein of the original somatic hybrid had largesubunit polypeptides exclusively of the N. tabacum type. Two of the plants regenerated from anthers contained Fraction-I-protein large subunits exclusively of the N. rustica type. Since each plant was regenerated from a single cell, the somatic hybrid must have had cells containing both the N. tabacum and N. rustica chloroplast genome although the latter was not expressed. Possibilities to account for this non-expression of a chloroplast genome in the somatic hybrid are discussed.