Strategies for the selection and characterization of aluminum-resistant variants from cell cultures of Nicotiana plumbaginifolia

The development of strategies for selecting and characterizing aluminum-resistant variants from Nicotiana plumbaginifolia Viv. cell cultures is described. Plated cells, smeared callus, in-vitro-grown shoots, and seedlings of wild-type N. plumbaginifolia all showed similar responses to Al, with total growth inhibition at or above 600 M Al. The strict control of both cell density and aggregate size is important in selection experiments for total inhibition of the growth of wild-type cells. Two approaches for the selection of Al-resistant variants were used. In a direct method, cells were plated onto medium containing 600 M Al which inhibited growth and chlorophyll synthesis in wildtype cells. A double selection strategy based on both cell growth and greening was used to isolate 29 Al-resistant variants. In the other approach, a rescue method, suspensions were cultured for 10 d in medium containing 600 M Al, then plated onto standard medium for recovery of survivors. Using this strategy, 217 Al-resistant variants were selected. After six to twelve weeks of growth in the absence of Al, each variant was cloned and reselected from single cells. Al resistance was retained in 31% and 51% of the variants selected by the direct and rescue strategies, respectively. Seedling segregation data are presented for the progeny (selfed and backcrossed) of plants regenerated from one of the variants and are consistent with those expected for a single dominant mutation.     

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.     

Sodium chloride resistant cell line from haploidDatura innoxia mill

Summary A cell line resistant to sodium chloride was selected from callus cultures of haploidDatura innoxia by cloning under selective pressure. Cells of the resistant cell line retained their resistance even after subculture in absence of NaCl. Plantlets could be regenerated from resistant cells in the presence as well as absence of NaCl. In contrast, regeneration of plantlets was not possible from normal cells in the presence of NaCl, although regeneration readily occurred in the absence of NaCl.To examine the stability of the resistance in the long-term, callus cultures were initiated in presence of NaCl from stem expiants of the differentiated plantlets. All expiants of plantlets derived from resistant cells showed callus formation. This callus, derived from resistant explants, retained the trait of resistance upon subculture.     

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.     

Karyotypic variability in plants of Solanum melongena regenerated from callus grown in presence of culture filtrate of Verticillium dahliae

Summary Plantlets were regenerated from calli derived from leaf expiants of three genotypes of Solanum melongena (two parental genotypes and their hybrid). The cytological analysis showed that a) plants regenerated were all mixoploid, b) toxic medium (basal medium added with filtrate culture of Verticillium dahliae) was able to evidence karyotypic differences between genotypes not displayed by plants regenerated from callus grown on control medium, c) chromosomal mosaicism persists up to plant maturity and also in the selfed progeny. The results are discussed in terms of a selective process involving genes controlling chromosome number and/or a direct effect of toxic medium on the activity of the same genes.This research is supported by a grant from ERSO (Ente per la Ricerca e Sperimentazione in Ortoflorifrutticoltura e Sementi) — Regione Emilia Romagna     

Characterization of rice transformed via an Agrobacterium-mediated inflorescence approach

Rice inflorescences were inoculated with Agrobacterium tumefaciens strain LBA4404 carrying plasmid pJD4 with application of vacuum infiltration. After co-cultivation, callus was initiated and subjected to hygromycin selection, and plants were regenerated from resistant callus lines. Based on the total number of co-cultivated inflorescences bearing flowers 1 to 3 mm in length, the average frequency for recovering independent transgenic rice plants was at least 30%. Seeds from selfed R0 plants were harvested within 6 months after initiation of the experiments. Genomic DNA blot analysis showed that genes in the T-DNA of the binary plasmid were stably integrated into the rice genome, typically at low copy number. In most, but not all, cases the transgene was transmitted to R1 progeny at a frequency characteristic for Mendelian inheritance of a single dominant trait. For selfed progeny of one two-locus insertion line, reactivation of GUS expression was observed for a single copy locus that segregated from a silenced multicopy locus. For this line and some additional plants, fluorescence in situ hybridization was used to visualize the chromosomal location of the transgene insert.     

Genetic instability during embryogenic cloning of celery

Genetically marked tissues of celery (Apium graveolens) were employed to contrast genetic and chromosomal stability in serially bulk-transferred callus and regenerated plants. After six months in culture, 84% of the callus cells were karologically indistinguishable from normal, while the remainder exhibited chromosome loss and/or fusion. All of 50 clones derived from this tissue expressed the control phenotype with respect to heterozygous isozyme markers. Of 95 plants regenerated from the same tissue, 94 were phenotypically indistinguishable from the original explant donor, and cytogenetic analyses revealed the presence in 4.3% of an accessory chromosome, while the remainder were normal diploids. Analysis of the selfed progeny of these regenerated plants revealed the presence of a new recessive mutation causing abnormal leaf morphology at a frequency of 1.8%. Only one of 40 cells in 12-month-old callus tissue was karyologically indistinguishable from normal, the remainder consisting primarily of hypodiploids. The observation that all 50 clones were phenotypically heterozygous was statistically inconsistent with the hypothesis that hypodiploidy was associated with random complete chromosome loss. The culture had, at this point, lost the ability to regenerate. It is speculated that embryogenic cloning of celery may be suitable under certain circumstances for direct field establishment, but that levels of new genetic variation are sufficiently high to preclude its use for seed production.     

The frequency of marker changes in sugarcane plants regenerated from callus culture

This study investigates the frequency of apparent and permanent expression of marker change following two types of tissue culture, conventional callus and direct regeneration cultures, and for two markers it relates this frequency to that following breeding. Each clone was used for only one marker. After conventional callus culture, plants of the sugarcane clone Arundoid B, a clone having a growth habit with shortened internodes and leaves, were freed of this marker at a rate of 1 in 172 plants. Marker remission in a second clone with a leaf blotch was enhanced in the presence of a mutagen. Callus culture alone gave a remission rate of 1/280 plants, while treatment of callus with ethyl methanesulfonate gave a remission rate of 1/42 plants. Of two markers subjected to vegetative and sexual transmission, the first, a leaf marker, was stable in callus culture with no remissions; crossing with non-marker parents produced progeny with 54% lacking the marker. The second, a stalk marker (multibud), showed epigenetic effects during two generations of vegetative propagation; plants lacking the multibud marker produced vegetative progeny in which the marker reappeared. Nine crosses to nonmarker parents produced progeny of which an average of 29% had the marker. The use of stalk chimeras as markers demonstrated that passage through conventional callus or direct regeneration culture resulted in the loss of the donor phenotype in all plants regenerated. Phenotypic variation in plants derived from callus culture appears to arise from several sources; chimeral segregants, epigenetic transients, and mutational variants.     

General features of chromosome substitutions in Triticum aestivum x T. timopheevii hybrids

Summary Tissue culture of the Zea mays inbred line A188 resulted in the regeneration of plants having a high level of phenotypic variation compared to seed-grown control plants. To determine how such variation was induced and whether this could be related to specific in vitro culture methods, callus cultures were established and maintained on different, commonly used culture media. Plants were regenerated and the genomic DNA of callus cultures and regenerants analysed for RFLP differences. The results show that regardless of the gene probe used, callus formation resulted in significant deviations from the DNA pattern normally found in seed-grown control plants. Alterations in gene copy number also occurred. As differentiation and organogenesis began, the level of DNA variation fell, and most of the regenerated plants showed a genetic similarity to the controls; those with RFLP differences were the somaclonal variants.     

Production of fertile transgenic maize by electroporation of suspension culture cells

Fertile, transgenic maize plants were generated by electroporation of suspension culture cells that were treated with a pectin-degrading enzyme. Electroporation of cells from two different suspension cultures, one derived from A188 X B73 and one derived from a B73-related inbred, with a plasmid containing the bar gene, resulted in high-frequency recovery of stably transformed callus lines. Plants were regenerated from thirteen transformed callus lines and transmission of bar to progeny was demonstrated.     

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.     

Resistance responses to Phoma lingam of plants regenerated from selected cell and embryogenic cultures of haploid Brassica napus

Summary Resistant plants and plants with reduced susceptibility against the pathogen Phoma lingam could be regenerated from selected callus and embryogenic cultures of haploid rape (Brassica napus) previously treated with mutagens. In the two in vitro selection systems used — absence of fungus growth on the cultures after incubation with parasite spores and resistance to the toxic filtrate — the resistance to the toxin was effective. In addition, some regenerants with increased tolerance were obtained from unselected cultures. Resistance tests on regenerated plants were carried out by inoculation of whole plants in the greenhouse, reproducing as much as possible the infection mechanisms which take place under natural conditions. Preliminary results on resistance of the progeny of single susceptible and tolerant regenerants seem to indicate that the acquired resistances are of a genetic nature.Part of these results was reported in a scientific meeting (Die höhere Pflanzenzelle: Möglichkeiten und Grenzen der Forschung) dedicated to Professor G. Melchers in the Max-Planck-Institut für Zellbiologie (Ladenburg) in January 1981     

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.     

The production of callus capable of plant regeneration from immature embryos of numerous Zea mays genotypes

In the summer of 1983, immature embryos from 101 selfed inbred lines and germplasm stocks of Zea mays L. were examined for their ability to produce callus cultures capable of plant regeneration (regenerable cultures) using a medium with which some limited success had previously been obtained. Forty-nine of the genotypes (49%) produced callus which visually appeared similar to callus previously cultured and shown to be capable of plant regeneration. After five months, 38 of these genotypes were alive in culture and plants were subsequently regenerated from 35 (92%) of them. No correlation was observed between plant regeneration and callus growth rate, the vivipary mutation (genes vp1, 2, 5, 7, 8 and 9), or published vigor ratings based on K⁺ uptake by roots. When F₁ hybrid embryos were cultured, 97% of the hybrids having at least one regenerable parent also produced callus capable of plant regeneration. No regenerable cultures were obtained from any hybrid lacking a parent capable of producing a regenerable callus culture.In the summer of 1984, immature embryos from 218 additional inbred lines and germplasm stocks were plated and examined for their ability to produce regenerable callus cultures on media containing altered micronutrient concentrations, 3,6-dichloro-o-anisic acid (dicamba), glucose, and elevated levels of vitamin-free casamino acids and thiamine. Of these genotypes 199 (91%) produced callus that was regenerable in appearance. In the 1984 study, plant regeneration was noted in many commercially important inbreds, including B73, Mo17, B84, A632, A634, Ms71, W117, H99³H95 and Cm105. Thus tissue-culture techniques are now available to obtain callus cultures capable of plant regeneration from immature embryos of most maize genotypes.Abbreviations trade names 2,4-D 2,4-dichlorophenoxyacetic acid - dicamba 3,6-dichloro-o-anisic acid     

Assessment of somaclonal variation in <Emphasis Type="Italic">Dieffenbachia</Emphasis> plants regenerated through indirect shoot organogenesis

The occurrence of somaclonal variation among regenerants derived through indirect shoot organogenesis from leaf explants of three Dieffenbachia cultivars Camouflage, Camille and Star Bright was evaluated. Three types of somaclonal variants (SV1, SV2, and SV3) were identified from regenerated plants of cv. Camouflage, one type from cv. Camille, but none from cv. Star Bright. The three variants had novel and distinct foliar variegation patterns compared to cv. Camouflage parental plants. Additionally, SV1 was taller with a larger canopy and longer leaves than parental plants and SV2. SV2 and SV3 did not produce basal shoots (single stem) but basal shoot numbers between SV1 and parental plants were similar ranging from three to four. The variant type identified from regenerated cv. Camille had lanceolate leaves compared to the oblong leaves of the parent. This variant type also grew taller and had a larger canopy than parental plants. The rates of somaclonal variation were up to 40.4% among regenerated cv. Camouflage plants and 2.6% for regenerated cv. Camille. The duration of callus culture had no effect on somaclonal variation rates of cv. Camouflage as the rates between plants regenerated from 8 months to 16 months of callus culture were similar. The phenotypes of the identified variants were stable as verified by their progenies after cutting propagation. This study demonstrated the potential for new cultivar development by selecting callus-derived somaclonal variants of Dieffenbachia.     

Characterization of Kanamycin-Resistant Cell Lines of Nicotiana tabacum

Two kanamycin-resistant variants of Nicotiana tabacum were derived by culturing seedling leaf sections on a shoot-inducing medium containing kanamycin. The variants displayed a higher resistance to the structurally related antibiotic streptomycin than to kanamycin. The resistance phenotype was expressed when the tissue was cultured either as callus or as a differentiating tissue and was stably maintained in the absence of kanamycin. Plants regenerated from the variant lines had morphologically abnormal flowers and produced few viable seeds. These resistant lines are potentially useful for protoplast fusion or genetic modification experiments requiring selectable phenotypic markers.     

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.     

The influence of plant growth regulator concentrations and callus age on somaclonal variation in callus culture regenerants of strawberry

The effect of plant growth regulator concentrations and ageing of callus on the extent and nature of variation among callus culture regenerants of strawberry (Fragaria × ananassa) cv. Redcoat was examined. Plants regenerated from callus culture had reduced plant vigour, shorter petiole length and smaller leaf size, but more leaves and runners under greenhouse conditions. These responses appeared to be due to a physiological influence of plant growth regulators. No distinct phenotypic variants were observed at plant growth regulator concentrations in the range of 1–10 M each of BA and 2,4-d combination, but the highest concentration (20 M each) of this combination produced a high frequency (10%) of dwarf type variants. The dwarf nature of these variants was maintained in the runner plants produced by the primary regenerants. The plants regenerated from 8-week-old calli did not show any distinct morphological variants. However, a significant proportion of deformed leaf shape (6–13%) and yellow leaf (21–29%) variants was obtained among plants regenerated from 16 and 24-week-old calli. The primary regenerants of the leaf shape variants were established as chimeras. The chimeric plants produced runner progeny with normal plants and plants with completely distorted leaf morphology. Both leaf shape and yellow leaf variants remained stable through runner propagation. Isozyme analysis failed to distinguish any of the variants from the standard runner plants. Flow cytometric analysis indicated the aneuploid nature of leaf shape variants but it could not distinguish dwarf and yellow leaf variants from standard runner plants.     

Differential metabolism of sodium azide in maize callus and germinating embryos

Sodium azide is a potent mutagen of maize (Zea mays L.) kernels that may have potential as a point mutagen for inducing biochemical mutations in maize tissue cultures. Azide mutagenicity was evaluated in friable, embryogenic maize callus and a nonregenerable maize suspension culture by determining the number of resistant variant cell lines able to grow on media containing inhibitory concentrations of lysine plus threonine (LT). The number of LT-resistant variants selected from either culture type did not increase in response to azide treatment. In addition, there was no increase in somatic mutations in more than 100 plants regenerated from azide treated LT-resistant lines. The levels of mutagenic metabolite of azide (presumably azidoalanine), were determined by bioassay in the two azide-treated maize callus types and compared to levels of mutagenic metabolite in embryos isolated from azide-treated kernels. The two types of maize tissue cultures and isolated embryos contained similar levels of mutagenic metabolite 4 h after azide treatment indicating similar uptake and conversion of azide to mutagenic metabolite in the three tissues. Mutagenic metabolite in azide-treated embryos did not significantly decrease after 40 h. However, mutagenic metabolite levels in both azide-treated tissue cultures decreased to near background levels within 20 h providing evidence for rapid metabolism of the azide mutagenic metabolite. The lack of evidence for azide mutagenicity in maize callus and its known potent mutagenicity in kernels appears to be associated with specific differences in azide metabolism between callus tissues and kernel embryos.