Isolation and characterization of isonicotinic acid hydrazide-resistant mutants of Nicotiana tabacum

Summary Twenty stable variant lines resistant to isonicotinic acid hydrazide (INH), an inhibitor of the conversion of glycine to serine in the glycolate pathway, were isolated in cell cultures initiated from allodihaploid Nicotiana tabacum. Plants were regenerated from 13 of these lines and explants were tested for resistance. For some lines virtually all of the regenerated plants scored as resistant; for others a mixed population of sensitive and resistant plants were obtained. One or more plants from 5 lines were fertile, presumably as a result of spontaneous diploidization of cells in the plant or culture. Callus initiated from the seed progeny of these plants was resistant to INH confirming the characteristic as a stable mutation. Seedlings from all INH-resistant plants were small and slow-growing, but the slow-growth trait could be separated from resistance in backcrosses of hybrids. In one case (line I21) crosses with sensitive lines show the resistant trait in that line to be dominant.     

Variation in nuclear DNA content of isonicotinic acid hydrazide-resistant cell lines and mutant plants of Nicotiana tabacum

Summary Isonicotinic acid hydrazide (INH)-resistant lines of Nicotiana tabacum have been maintained in callus culture for six years and mutant plants have been regenerated from a number of these lines. This study examines variations in DNA content in nuclei of several of these callus cultures, regenerated plants, and secondary callus from the regenerated plants. The lines selected for study include three easily regenerated lines (I 21, I 24, and I 9) and two lines of poor regenerating capacity (I 1 and I 18). Two of the regenerating lines eventually led to fertile plants and the third produced only sterile plants. In general, the range of total nuclear variability was not as high as anticipated from other studies of long-term tobacco callus cultures. The majority of nuclei in all the distributions were between 3 and 20 pg, and the most frequently encountered distributions concentrated in the 7–18 pg region corresponding to 2–5C by our estimate of the C value for tobacco. Distributions were not identical for plants regenerated from the same culture simultaneously, and the nuclear DNA content of secondary callus cultures from one of the plants examined did not reflect the quantitative DNA pattern of the plant from which it was derived. The greatest degree of variability and highest DNA content for individual nuclei were observed in the primary callus of the poorly- and non-regenerating lines. The variability in DNA content was not associated with the INH-resistant trait.     

Inheritance of Chloramphenicol Resistance, a Trait Selected in Cell Cultures of Nicotiana Sylvestris. Speg. and Comes

Three cell lines with improved resistance to growth inhibitionby chloramphenicol were selected from cell cultures of Nicotianasylvestris. Resistance was retained in callus cultures of twoout of three plants regenerated from one of the lines, but notin cultures of plants regenerated from the other two lines.Sexual progeny of the two resistant plants were either sensitiveor showed slow segregation for chloramphenicol resistance. Incallus from only two of the seedlings was inheritance of chloramphenicolresistance clearly demonstrated. Nicotiana sylvestris, cell culture, choramphenicol resistance     

Activation of the maize transposable element Suppressor-mutator (Spm) in tissue culture

Summary Previous experiments have revealed that the maize transposable element Activator (Ac) may become active during tissue culture. The objective of the present study was to determine whether a second transposable element, Suppressor-mutator (Spm), could also be activated in tissue culture and detected in regenerated maize plants. Approximately 500 R₁ progeny of 143 regenerated plants (derived from 49 embryo cell lines) were crossed as males onto an Spm-responsive tester stock. Spm activity was observed in two R₁ progeny of a single regenerated plant. This plant had been regenerated from Type II (friable embryogenic) callus of an A188 × B73 genetic background after 8 months in culture; the absence of Spm activity in four other plants regenerated from this same callus demonstrates that Spm activity was not present before culturing. Approximately 20 Spm-homologous DNA sequences were detected in each of the inbreds used to initiate the tissue cultures; it is presumed that one of these became active to give rise to Spm activity.     

Type I callus as a bombardment target for generating fertile transgenic maize (Zea mays L.)

To develop a less genotype-dependent maize-transformation procedure, we used 10-month-old Type I callus as target tissue for microprojectile bombardment. Twelve transgenic callus lines were obtained from two of the three anther-culture-derived callus cultures representing different gentic backgrounds. Multiple fertile transgenic plants (T₀) were regenerated from each transgenic callus line. Transgenic leaves treated with the herbicide Basta showed no symptoms, indicating that one of the two introduced genes, bar, was functionally expressing. Data from DNA hybridization analysis confirmed that the introduced genes (bar and uidA) were integrated into the plant genome and that all lines derived from independent transformation events. Transmission of the introduced genes and the functional expression of bar in T₁ progeny was also confirmed. Germination of T₁ immature embryos in the presence of bialaphos was used as a screen for functional expression of bar; however, leaf painting of T₁ plants proved a more accurate predictor of bar expression in plants. This study suggests that maize Type I callus can be transformed efficiently through microprojectile bombardment and that fertile transgenic plants can be recovered. This system should facilitate the direct introduction of agronomically important genes in to commercial genotypes.     

Photorespiration-deficient Mutants of Arabidopsis thaliana Lacking Mitochondrial Serine Transhydroxymethylase Activity

Three allelic mutants of Arabidopsis thaliana which lack mitochondrial serine transhydroxymethylase activity due to a recessive nuclear mutation have been characterized. The mutants were shown to be deficient both in glycine decarboxylation and in the conversion of glycine to serine. Glycine accumulated as an end product of photosynthesis in the mutants, largely at the expense of serine, starch, and sucrose formation. The mutants photorespired CO₂ at low rates in the light, but this evolution of photorespiratory CO₂ was abolished by provision of exogenous NH₃. Exogenous NH₃ was required by the mutants for continued synthesis of glycine under photorespiratory conditions. These and related results with wild-type Arabidopsis suggested that glycine decarboxylation is the sole site of photorespiratory CO₂ release in wild-type plants but that depletion of the amino donors required for glyoxylate amination may lead to CO₂ release from direct decarboxylation of glyoxylate. Photosynthetic CO₂ fixation was inhibited in the mutants under atmospheric conditions which promote photorespiration but could be partially restored by exogenous NH₃. The magnitude of the NH₃ stimulation of photosynthesis indicated that the increase was due to the suppression of glyoxylate decarboxylation. The normal growth of the mutants under nonphotorespiratory atmospheric conditions indicates that mitochondrial serine transhydroxymethylase is not required in C₃ plants for any function unrelated to photorespiration.     

Selection of Glyphosate-Tolerant Tobacco Calli and the Expression of this Tolerance in Regenerated Plants

From nonmutagenized haploid suspensions of Nicotiana tabacum L. cv Wisconsin 38 cells, 51 cell lines capable of growth in the presence of 1 millimolar glyphosate (N-phosphonomethyl glycine) were initially isolated at a frequency of 2.3 × 10⁻⁸. Eighteen cell lines retained tolerance when grown on selective medium for 3 years. Tolerance persisted for at least 14 months in six cell lines cultured in the absence of glyphosate. Some plants regenerated from four glyphosate-tolerant cell lines were tolerant. Glyphosate-tolerant tissue was isolated from some sensitive as well as some tolerant regenerated plants. Six of the tolerant cell lines were also tolerant to the herbicide amitrole (3-amino-1,2,4-triazole). Five cell lines selected for amitrole tolerance were glyphosate tolerant. Some plants regenerated from three of these five cell lines were glyphosate tolerant and glyphosate-tolerant tissue was obtained from several of these regenerated plants. Amitrole uptake in suspension cultures of several variants was assessed in terms of influx rate constants. This parameter was not sufficiently different indicating that altered membrane properties could not account for the herbicide tolerance.     

Inhibition of glycine decarboxylation and serine formation in tobacco by glycine hydroxamate and its effect on photorespiratory carbon flow

Glycine hydroxamate is a competitive inhibitor of glycine decarboxylation and serine formation (referred to as glycine decarboxylase activity) in particulate preparations obtained from both callus and leaf tissue of tobacco. In preparations from tobacco callus tissues, the K_i for glycine hydroxamate was 0.24 ± 0.03 millimolar and the K_m for glycine was 5.0 ± 0.5 millimolar. The inhibitor was chemically stable during assays of glycine decarboxylase activity, but reacted strongly when incubated with glyoxylate. Glycine hydroxamate blocked the conversion of glycine to serine and CO₂in vivo when callus tissue incorporated and metabolized [1-¹⁴C]glycine, [1-¹⁴C]glycolate, or [1-¹⁴C]glyoxylate. The hydroxamate had no effect on glyoxylate aminotransferase activities in vivo, and the nonenzymic reaction between glycine hydroxamate and glyoxylate did not affect the flow of carbon in the glycolate pathway in vivo. Glycine hydroxamate is the first known reversible inhibitor of the photorespiratory conversion of glycine to serine and CO₂.     

Isolation of paraquat-tolerant mutants from tomato cell cultures

Summary Tomato callus clones selected for the ability to grow at paraquat concentrations lethal to wild-type cells were found at an approximate frequency of 5×10^–8 per viable cell. Diploid plants were regenerated from nine of the nineteen paraquat-tolerant callus clones isolated. Although some of these plants appeared normal, others had altered morphology and reduced vigor and fertility. New callus cultures initiated from these regenerated plants typically had at least a 30-fold increase over the wild type in tolerance to paraquat. Tests on callus from sexual progeny showed that the paraquat-tolerant phenotypes of clones PQT⁴, PQT⁶, and probably also PQT¹³ resulted from dominant nuclear mutations, but the number of loci involved is not yet known. Paraquat spray experiments indicated that slight paraquat-tolerance was expressed at the plant level in PQT¹³, but not in any of the other clones tested.     

Selection of ethionine-resistant variants with increased accumulation of methionine from embryogenic protoplasts of the forage legume <Emphasis Type="Italic">Astragalus adsurgens</Emphasis>

In vitro selection was carried out to obtain ethionine-resistant plants with increased contents of free methionine in the vegetative tissues of the forage legume Astragalus adsurgens Pall. Three-week-old cell colonies were derived from protoplasts mutagenized with N-methyl-N-nitrosoguanidine from embryogenic callus and were selected with 0.6mM ethionine. Four colony lines were isolated and their resistance to ethionine was 7–8 times that of the wild-type callus. No plant regeneration occurred on these colony lines in the differentiation medium containing ethionine. Only one colony line (R-1) regenerated plants through somatic embryogenesis in the absence of ethionine. Stem and leaf segments from the regenerated plants showed the same potential to produce callus in the presence of ethionine as in the absence of ethionine. The formed callus kept continuously growing in ethionine-containing medium. Free amino acid analysis revealed that colony line R-1, its regenerated plants and callus from the regenerated plants accumulated methionine at levels at 5–9 times higher than in wild-type. These results suggested that ethionine resistance and methionine over-accumulation were also expressed at plant level. Thus, the obtained resistant colony line that could regenerate plants with over-accumulation of methionine might provide an alternative approach to improve the nutritional quality of this forage.     

Large scale selection of aluminum-resistant mutants from plant cell culture: expression and inheritance in seedlings

Summary A large number of aluminum-resistant variants, selected from non-mutagenized homozygous diploid cell cultures of Nicotiana plumbaginifolia Viv., are characterized. Of 115 variants cloned and reselected from single cells, 67 retained Al resistance in callus cultures after 6–9 months of growth in the absence of Al. There was no association between Al resistance and callus growth in the absence of Al, suggesting that the Al-resistant phenotype is not detrimental in the absence of Al challenge and that Al resistance is not the result of increased vigor. Plants regenerated from initially resistant callus lines that subsequently lost their resistance failed, with one exception, to transmit resistance to their seedling progeny. Fertile plants were regenerated from 40 of the 67 variants that retained stable Al resistance in callus culture. All 40 transmitted Al resistance to their seedling progeny (selfed and backcrossed) in segregation ratios expected for a single dominant mutation. The selfed progeny of many variants also segregated for recessive lethal mutations which were attributed to independent mutations that occurred during cell culture.     

Somatic embryogenesis in Asparagus officinalis can be an in vitro selection process leading to habituated and 2,4-D dependent embryogenic lines

Long-term embryogenic lines were repeatedly obtained from nine asparagus (Asparagus officinalis L.) genotypes by the selection of rare events, which consisted of the emergence of either a few somatic embryos or an embryogenic callus from a restricted area of a primary callus. In the first case, somatic embryos emerged from 1 % of calli induced with naphtaleneacetic acid and transferred to a medium without auxin. Isolated and subcultured on hormone free medium, these embryos developed habituated embryogenic lines (H lines) growing by adventive embryogenesis. In the second case, 3 % of primary calli developed then subcultured on 2,4-dichlorophenoxyacetic acid (2,4-D) produced a new type of friable and yellowish-white callus, constituted of clusters of globular somatic embryos which can be continuously maintained on 2,4-D (2,4-D lines). Among 2,4-D lines, two types were identified by subculturing them on hormone–free medium. Half of the 2,4-D lines were habituated and half were 2,4-D dependent. Most plants regenerated from H lines exhibited a strong increase in embryogenic capacity compared to control plants, unlike plants regenerated from the 2,4-D dependent lines. This increased embryogenic capacity was transmitted to the progeny as a monogenic dominant trait. H lines would therefore be issued from mutation(s) occurring in vitro, conferring both the embryogenic and habituated phenotypes. On the contrary, in the 2,4-D dependent lines, the embryogenic processes appeared to remain under exogenous auxin control and no evidence of a mutational origin could be inferred from the behaviour of regenerated plants.     

Somaclonal variation and resistance to Verticillium wilt in lucerne,Medicago sativa L., plants regenerated from callus

Somaclonal variation in disease reaction type to infection by the vascular wilt pathogen Verticillium albo-atrum Reinke & Berth was assessed in a population of lucerne plants regenerated from callus lines obtained from a susceptible cultivar. Disease severity in the regenerant population was reduced by comparison with parental controls. Seed progeny and plants recovered via a second tissue culture cycle reverted to mainly susceptible reaction types. In a further experiment a low molecular weight toxic fraction from culture filtrates of the fungus was incorporated into the callus medium prior to regeneration. Toxin treatment reduced the regenerative capacity of callus, and there was little evidence for a higher frequency of wilt resistant plants in populations selected at low toxin concentrations. The results suggest that somaclonal variation as an alternative breeding strategy for disease resistance in lucerne offers no advantages over conventional recurrent selection.     

Genetic and physiological variability among cultured cells and regenerated plants of Nicotiana tabacum

Summary Tobacco cell lines selected for resistance to picloram (4-amino-3,5,6-trichloropicolinic acid) and plants regenerated from these cell lines manifest several traits not shown by the parental strains. Genetics analyses of the regenerated plants have permitted the sources of this variability to be identified.Tricotyledenous seedlings appeared at a much higher frequency among the progeny of a heterozygous mutant plant (PmR1/+) regenerated from culture than they did among progeny of normal regenerated plants. In crosses with the regenerated heterozygous mutant plant and with homozygous progeny of this plant (PmR1/PmR1) the frequency of tricotyly was influenced more by the generation than by the genotype of the parent plant. Therefore, it is concluded that tricotyly is a physiological response to passage through cell culture.More than half of the picloram-resistant cell lines isolated were also resistant to hydroxyurea. Segregation of these two resistances was analyzed in progeny of crosses with regenerated plants. In all cases hydroxyurea-resistance was genetically stable and inherited as a single dominant nuclear mutation (designated HuR). In crosses with plants PmR1/+ and PmR7/+ the HuR and PmR mutations assorted independently. In contrast, the HuR mutation recovered from plant PmR6/+ was linked to the PmR6 mutation.     

Anther and tissue culture-induced grain chalkiness and associated variants in rice

Rice, Oryza sativa, plants regenerated from anther culture with and without in vitro selection pressure were evaluated for chalky seed. Progeny evaluated included 21 spontaneously doubled haploids selfed 4 times, progeny from plants regenerated from S-aminoethylcysteine resistant callus selfed 4 times and backcrosses of both types to the parental type. All lines with in vitro histories had higher seed chalkiness than the controls both in the intensity of chalkiness and in the number of seeds expressing the character. The full range of intensity and amount of chalkiness was expressed in the progeny. The average intensity of anther/tissue culture-derived progeny was 4–5, based on a scale of 1 (translucent) to 10 (fully opaque), and the average amount of chalkiness within plants sampled was 50–75 percent. The chalky characteristic is transmitted from parent to offspring into a range of identifiable F₂ segregants. Disclaimer statement Mention of a trademark or proprietary product does not constitute a guarantee or warranty of the product by the USDA, and does not imply its approval to the exclusion of other products that may also be suitable.     

In Vitro selection of groundnut cell lines fromCercosporidium personatum culture filtrates and regeneration of resistant plants through cell culture

Cell suspensions derived from immature leaves of the groundnut (Arachis hypogaea L.) were cultured in the presence and absence ofCercosporidium personatum pathotoxic culture filtrates. Cell viability and reactions of cell lines were determined after exposure to various concentrations (25–100%, v/v) of the filtrates. Cell lines have been selected for resistance to the toxin(s) produced byC. personatum. Selected cell lines were used for plant regeneration on regeneration media containingC. personatum culture filtrates. Plant regeneration frequency was found to be low in long-term cultures, whereas it was high in short-term cultures. The selfed progeny of the plants regenerated from the resistant cell lines showed resistance to the pathogen in the field. Six out of 82 plants exhibited enhanced resistance in the R₂ generation. The culture filtrate stimulated callus proliferation as well as plant regeneration at lower concentrations, a response that could prove to be very useful for obtaining disease resistant plants throughin vitro selection.     

Regeneration and characterization of somatic hybrids between Brassica napus and Diplotaxis harra

Stem cortex protoplasts of Brassica napus, inactivated with iodoacetate, were fused with cell suspension - derived protoplasts of Diplotaxis harra by polyethylene glycol (PEG) treatment. PEG at 15–18% (w/v) induced 5–9% heterofusions. The hybrid callus selection was based on morphology: D. harra calli were yellow and very fine, while B. napus protoplasts typically produced green, well defined calli. A number of green, large calli were selected after fusion experiments and flowering plants were regenerated from two of these callus lines. The morphological traits as well as cytological and biochemical analysis of four isoenzymes confirmed the hybrid nature of the regenerants.     

Tissue culture-induced DNA methylation polymorphisms in repetitive DNA of tomato calli and regenerated plants

The propagation of plants through tissue culture can induce a variety of genetic and epigenetic changes. Variation in DNA methylation has been proposed as a mechanism that may explain at least a part of these changes. In the present study, the methylation of tomato callus DNA was compared with that of leaf DNA, from control or regenerated plants, at MspI/HpaII sites around five middle-repetitive sequences. Although the methylation of the internal cytosine in the recognition sequence CCGG varied from zero to nearly full methylation, depending on the probe used, no differences were found between callus and leaf DNA. For the external cytosine, small differences were revealed between leaf and callus DNA with two probes, but no polymorphisms were detected among DNA samples of calli or DNA samples of leaves of regenerated plants. When callus DNA cut with HindIII was studied with one of the probes, H9D9, most of the signal was found in high-molecular-weight DNA, as opposed to control leaf DNA where almost all the signal was in a fragment of 530 bp. Also, an extra fragment of 630 bp was found in the callus DNA that was not present in control leaf DNA. Among leaves of plants regenerated from tissue culture, the 630-bp fragment was found in 10 of 68 regenerated plants. This 630-bp fragment was present among progeny of only 4 of these 10 plants after selfing, i.e. it was partly inherited. In these cases, the fragment was not found in all progeny plants, indicating heterozygosity of the regenerated plants. The data are interpreted as indicating that a HindIII site becomes methylated in callus tissue, and that some of this methylation persists in regenerated plants and is partly transmitted to their progeny.     

Multiplication of tobacco mosaic virus in tobacco callus tissues and in vitro selection for viral disease resistance

Tobacco mosaic virus-resistant tobacco was selected in vitro using callus tissues induced from axillary buds of systemically infected tobacco plants. Callus lines in which the virus was continuously multiplying were first isolated and redifferentiated into shoots. By the procedure, non-diseased, healthy shoots were successfully isolated from diseased shoots, which showed typical mosaic symptoms of the virus, and regenerated into intact plants.These regenerated plants showed resistance to virus inoculation, and selfed progeny of virus-resistant regenerants segregated the resistance and susceptibility according to the Mendelian system.     

Variation ofHelminthosporium resistance and biochemical and cytological characteristics in somaclonal generations of barley

SC₂ and SC₃ progenies of nineteenin vitro regenerated barley plants (SC₁) from resistant calli selected against purified culture filtrate ofHelminthosporium sativum and one parent ‘Dissa’ genotype were studied for stability of resistance and protein, soluble protein, maltose and saccharose contents. Cytological studies were also carried out on the SC₃ generation. Stability of resistance toHelminthosporium sativum was found in 50% of the somaclonal lines. Significant variation among different somaclonal lines and among different callus lines from which the plants were regenerated were found for yield, disease score and biochemical characters assessed except saccharose content in the somaclonal lines. Significant increase and decrease over the donor parent for most of the characters were obtained. Cytological abnormalities such as multilobed nuclei, multinucleate cells, abnormal anaphase and mixoploidy were also observed.