RAPD and ISSR analyses of regenerated pea Pisum sativum L. plants

Long-term pea callus cultures of different genotypes (mutants R-9 and W-1 and cultivar Viola) were used to regenerate plants (generation R0). The regenerants displayed changes both in qualitative and in quantitative traits. The most dramatic morphological alterations and complete sterility were observed in regenerants of the cultivar Viola. To estimate the genetic differences, regenerants were compared with the original lines with the use of RAPD (random amplified polymorphic DNA) and ISSR (inter simple sequence repeat) analyses. The extent of divergence varied among regenerants and depended mostly on the original genotype. The genetic difference from the original line was no more than 1% in W-1 regenerants, 0.7-5.3% in R-9 regenerants, and 10-15% in sterile regenerants of the cultivar Viola. The genetic variation of plants regenerated from a callus culture maintained for ten years did not exceed that of plants obtained from a culture maintained for two years.     

The effect of the duration of callus culture on the accumulation of genetic alterations in pea Pisum sativum L.

Two groups of regenerant plants were obtained from different pea genotypes (lines R-9 and W-1 and cultivar Viola). The first group was derived after eight months of culture and the second, from calluses cultured for a prolonged (more than ten years) time. Using random amplified polymorphic DNA (RAPD) and inter simple sequence repeats (ISSR) methods, the regenerants and the original lines were compared with regard to genetic differences. The regenerants from both groups were shown to differ in DNA polymorphism from the original lines and from one another. The divergence of the regenerants was also different, depending largely on the original genotype. Examination of genetic differences between the first and the second group showed that the variability increased with culturing time. This was particularly evident for regenerants of the Viola cultivar, in which variability ranged from 0–5% (first group of regenerants) to 10% (second group of regenerants).     

The effect of the duration of callus culture on the accumulation of genetic alterations in regenerated pea Pisum sativum L

Two groups of regenerant plants were obtained from different pea genotypes (lines R-9 and W1 and cultivar Viola). The first group was derived after eight months of culture and the second, from calluses cultured for a prolonged (more than ten years) time. Using random amplified polymorphic DNA (RAPD) and inter simple sequence repeats (ISSR) methods, the regenerants and the original lines were compared with regard to genetic differences. The regenerants from both groups were shown to differ in DNA polymorphism from the original lines and from one another. The divergence of the regenerants was also different, depending largely on the original genotype. Examination of genetic differences between the first and the second group showed that the variability increased with culturing time. This was particularly evident for regenerants of the Viola cultivar, in which variability ranged from 0-5% (first group of regenerants) to 10% (second group of regenerants).     

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.     

Optimization of Agrobacterial (<Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis>) Transformation of Maize Embryogenic Callus

The method for genetic transformation of maize (Zea mays L.) via embryogenic callus infection with Agrobacterium tumefaciens was developed. Calli were co-cultivated with the overnight culture of A. tumefaciens strain LBA4404 harboring the pBI121 plasmid with the nptII and uidA genes. Thereafter, the sensitivity of calli and regenerated plantlets to kanamycin (Km) was determined. It was shown that kanamycin selection was more efficient at the stage of regenerated plantlets than in callus culture. Both vacuum infiltration at the infection step and preliminary activation of Agrobacterium by acetosyringone or by tobacco leaves exudate increased the frequency of Km-resistant plants. The frequency of Km-resistant plants also varied depending on the morphogenic ability of calli. Polymerase chain reaction confirmed the presence of the nptII gene in the genome of regenerated plants and their progeny. β-Glucuronidase gene expression was observed in roots of T1 plants.__________Translated from Fiziologiya Rastenii, Vol. 52, No. 4, 2005, pp. 600–607.Original Russian Text Copyright © 2005 by Danilova, Dolgikh.     

In vitro selection for methomyl resistance in CMS-T maize

Summary Many plants resistant to methomyl (Lannate), an insecticide which selectively damages maize with the Texas (T) type of cytoplasmic male sterility (CMS-T), were obtained by in vitro selection and also without selection. The selection procedure used 0.6–0.7mM methomyl and callus from CMS-T versions of several field and sweet corn genotypes (W182BN, Wf9, P39, MDM1, SW1 and hybrids of SW1, IL766A1, IL766A2, and 442 with W182BN-N). Addition of 1 mM methomyl to the regeneration medium greatly reduced recovery of methomyl-sensitive escapes. Resistance was linked with reversion to male fertility and maternally inherited. Most progeny of resistant plants exhibited stable maternally inherited resistance for two generations in field tests. First-generation progeny of seven culture-derived plants segregated for resistance and sensitivity; this suggests that ears of these seven regenerants were cytoplasmically chimeral. Resistance to methomyl was associated with resistance to T toxin from Helminthosporium maydis race T and with changes in mitochondrial physiology. Prolonged culture (14–16 months versus 6–8 months) increased the frequency of resistance among both selected and non-selected regenerants. Little or no resistance was found among regenerants from certain genotypes. Selection with methomyl may be useful for production of improved sweet corn lines and as a source of mitochondrial mutants. This system is also convenient for studies of the effects of nuclear background and of culture and selection systems on the generation of cytoplasmic mutants.     

In vitro culture of Cucumis sativus L. XVIII. Plants from protoplasts through direct somatic embryogenesis

A procedure is described for the isolation and culture of protoplasts from embryogenic callus (gel-like callus — GLC) and embryogenic suspension cultures (ESC) of Cucumis sativus c.v. Borszczagowski. Maximal protoplast yields from GLC and ESC were 5×10⁶ and 1×10⁷ protoplasts/g tissue respectively. They were obtained following 14–16 h digestion with 1.2% Cellulase Onozuka R-10, 1.2% Macerozyme R-10 and 0.3% Driselase. At a plating density of 2×10⁵ / ml, first divisions occurred in 4–5 days and 7–8 days in ESC-and GLC-derived protoplasts respectively. The highest percentage of direct embryogenesis (over 80%) was observed with ESC. It was possible to obtain approximately 5000 embryo structures / g tissue. Some embryos converted into plants after 6 weeks, but most of them after 2 months of culture. ESC-derived plants, when transferred into the glasshouse, bloomed normally, and set seeds.Abbreviations CMS Murashige & Skoog (1962) medium for cucumber - GLC gel-like callus - ESC established embryogenic suspension culture - 2,4-d 2,4-dichlorophenoxyacetic acid     

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.     

Heterozygous diploid plants regenerated from anther culture of F1 rice plants

Summary Plants derived from anther culture are theoretically haploid, but diploid plants are also known to arise. Anther culture-derived diploid plants are usually homozygous and are believed to be due to spontaneous doubling of chromosomes in either microsporocytes or callus cells during the culture process. However, heterozygous diploid regenerants may also arise from a) regeneration from cultured somatic cells, b) mutation occurring during or after a spontaneous doubling event, c) fusion of unlike haploid cells in chimeric callus, and d) regeneration from diploid microsporocytes resulting from aberrant meioses. This study was designed to elucidate the frequency and origin of diploid regenerants from rice anther culture. Regenerants were obtained from 11 F₁ genotypes. Progeny testing detected heterozygosity in 7 out of 211 regenerants. Each of the heterozygous regenerants were from ‘Calrose 76’/waxy ‘M-101’, Half of the diploid regenerants from this cross were heterozygous. No heterozygous regenerants arose from the other 10 F₁ genotypes. Progeny testing indicated that two of the heterozygous regenerants were as heterozygous as the F₁ plants for three parental characters. The other five regenerants exhibited decreased levels of heterozygosity. One of the heterozygous regenerants exhibited evidence of mutation for a non-parental character. However, mutation is an unlikely cause of the observed high levels of parental-type heterozygosity. No evidence for the occurrence of chimeric callus was detected, making this an unlikely cause as well. The most likely origin of the observed partial heterozygosity is regeneration from diploid microspores, which could also produce plants exhibiting complete parental-type heterozygosity.     

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.     

Genetic variability in regenerated plants of Ungernia victoris

To determine the suitability of micropropagation techniques developed for conserving rare medicinal herb Ungernia victoris we estimated the genetic fidelity of plants produced through direct regeneration from the bulb scale segments and organogenesis from long-term callus culture. Average value of the Jaccard’s distances between explant-derived regenerants and maternal plants calculated from RAPD data was 0.5 %, while that of estimated between callus-derived regenerants and maternal cell line was 4.2 %; average distances between the objects among the explant-derived and callus-derived regenerants were 0.7 % and 2.5 %, respectively. The data obtained suggest that conditions for in vitro culture applied in this work provide relatively high genetic stability of the species upon the direct regeneration in vitro and regeneration from the long-term cultured callus.     

Regeneration of plants from protoplasts of rapid cycling Brassica oleracea L.

Rapid cycling Brassica species have great potential in plant genetic research because of their short life cycles and their minimal space requirements. Rapid cycling B. oleracea can be grown with up to six generations per year. Protoplast culture of this genotype can be applied for gene transfer by direct DNA uptake and by protoplast fusion. We here report on fast regeneration of flowering plants from protoplasts of rapid cycling B. oleracea. Regeneration frequencies of 27–65% were achieved with multiple shoots developing from individual calli. The regenerated plants were grown to maturity, and flowering and other morphological characteristics were monitored. The regenerants flowered within a similar time frame as plants grown from seeds. The ploidy level of regenerated and seed-grown plants was measured by flow cytometry. Many (20–45%) of the regenerants were tetraploid. Although only few seeds could be obtained from the tetraploids, large numbers of seeds with good germination were recovered from the diploid regenerants.Abbreviations MS-3,0 Murashige and Skoog medium containing 3% sucrose and no growth regulators - MES 1-morpholino-ethane sulfonate     

Embryogenesis and Regeneration of Green Plantlets from Wheat (Triticum aestivum) Leaf Base

A short-term regeneration system from leaf-base-derived callus of wheat (Triticum aestivum L.) was developed. Embryogenic callus formation and shoot regeneration were achieved from the first basal segments of 3–4-day-old seedlings. Callus formation frequency as well as plantlet regeneration frequency was dependent on the composition of basal medium and the concentration of 2,4-dichlorophenoxyacetic acid (2,4-D). MS medium with 2,4-D 4.5–9.0 mol l^–1 was optimal for the culture of wheat leaf base. Effects of different combinations of plant growth regulators, which were added in either callus induction medium or shoot regeneration medium, were tested. Adding of BAP in callus induction medium shortened the time of shoot emergence but could not improve the producing of embryogenic calli and green plantlets. Optimal ratio of 2,4-D, BAP and NAA gave similar regeneration frequency to control. Existence of cytokinins in regeneration medium had no effect on increasing the regeneration frequency. The regenerants could grow to normal, fertile plants after they were transferred into soil.     

Salt tolerance improvement in some wheat cultivars after application of in vitro selection pressure

Somatic embryogenesis through callus initiation has been quantified under salt stress conditions for 8 wheat cultivars currently cultivated in Morocco. The cultivars were classed according to the mean number of somatic embryos formed per immature embryo half and regenerated plants per 100 explants under saline conditions. Regenerated plants from control callus (R_0–0) and callus initiated on 10 g l^–1 NaCl (R_0–10) did not show significant differences concerning plant height, spike length and grain number per ear but, the R₀ plants remained less developed than parent plants. When watered with a solution containing more than 20 g l^–1 NaCl, the seeds of cultivar Te derived from R_0–10 regenerated plants exhibited the best elongation of roots and coleoptiles. Furthermore, a chlorophyll fluorescence test showed a clear improvement in salt tolerance of R_0–10 plants at four to five-leaf stage, compared to R_0–0 plants. It is concluded that plant regeneration from callus initiated on high NaCl levels may be a valid method of selection for salt tolerance.     

A revised scheme for mass propagation of Easter Lily

Lilium longiflorum Thunb., commonly known as Easter Lily is widely propagated by vegetative means for its high ornamental value as a pot plant. Following in vitro technique, mass propagation has been achieved through direct production of bulblets from the explant as well as regeneration from callus. The chromosome analysis of the progeny derived from callus even from long term culture, did not reveal any marked variability in chromosome morphology. The stable nature of callus maintained in modified MS medium in long term culture has been confirmed. Along with rapid growth, the regenerating capacity of calli has been maintained for 3 years of culture in the above medium. Following shake culture, large number of bulblets could be obtained from such differentiated calli within 3–4 weeks. The shake culture technique of calli is ideally suited for securing stable regenerants on a mass scale in this species.Abbreviations MS Murashige & Skoog's medium - NAA -napthaleneacetic acid - IAA indole-3-acetic acid - 2,4-D 2,4-dichlorophenoxyacetic acid - BA 6-benzyladenine     

Plant regeneration from callus culture of Curcuma aromatica and in vitro detection of somaclonal variation through cytophotometric analysis

Callus cultures initiated from shoot base explants of Curcuma aromatica Salisb. were maintained on Murashige and Skoog (MS) media supplemented with 2 mg dm⁻³ 2,4-dichlorophenoxyacetic acid alone or with 0.5 mg dm⁻³ kinetin. Plantlets were regenerated from 60 and 180-d-old callus on MS media supplemented with 3 mg dm⁻³ benzyladenine and 0.5 mg dm⁻³ α-naphthalene acetic acid. Approximately 8–10 plantlets were produced after 30–40 d of culture per 50 mg of callus inoculated. Out of 113 regenerants analyzed 85 plants were exclusively diploid and 28 were predominantly diploid revealing presence of polyploid nuclei. Frequency of polyploid cells were more in regenerants obtained from 180-d-old callus then from 6-d-old callus which might be attributed to the ageing of callus.     

Elimination of Solanum phureja nucleolar chromosomes in S. tuberosum + S. phureja somatic hybrids

Summary The karyotype of the dihaploid SVP1 line of S. tuberosum (2n=2x=24) showed two nucleolar chromosomes with differently sized satellites. The diploid SVP5 line (2n=2x=24) and tetraploid regenerants of S. phureja had larger but similar satellites. Somatic hybrids between the diploid lines of these potato species with genome combinations 4 tub + 2 ph (plants 1–3), 2 tub + 4 ph (plants 4–7) and 4 tub + 4 ph (plant 8) had lost 2 phureja nucleolar chromosomes if 4 phureja genomes were present. One phureja nucleolar chromosome of plants 1–3 and both of plants 5 and 7 had rearranged satellites. Elimination of the two nucleolar chromosomes occurred preferentially, was under genetic control, and probably took place during early callus development. NOR activity resulting in rear-rangements between NORs may have caused the elimination.     

The heritable changes in metabolic profiles of plants regenerated in different types of <Emphasis Type="Italic">in vitro</Emphasis> culture

In this work we show how three types of cucumber in vitro cultures – leaf callus culture, cytokinin dependent cell suspension and liquid culture of meristematic clumps – influence the metabolite profiles of plants in the first generative progeny. Based on this study we conclude that there exists a specific and inheritable metabolic fingerprint reflecting the history of previous generations, probably related to specific stress factors accompanying the passage through different types of culture. The leaf callus culture generated the highest heritable differences in metabolite content and was the most distinctly separated cluster in PCA analysis. The smallest number of variable metabolites characterizes the plants regenerated from cytokinin dependent cell suspension whereas the liquid culture of meristematic clumps induced slightly more changes. Changes induced by these two culture types were not as pronounced as in the case of leaf callus culture. However the plants after these types of culture were well separated from the control on PCA diagram. The highest changes were over 2-fold increases in cystin and galactose-6-P and over 2-fold decreases in aspartate, myo-inositol, hydroxylamine, phosphate and putrescine. These changes concerned the plants, which were one generation after the leaf callus culture. The possible nature of observed heritable changes is discussed.     

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.     

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.