Somaclonal variation in high tannin sorghums

Summary Genetic variants were found among over 6,000 primary plants (R₁) regenerated from embryogenic tissue cultures of eight high tannin sorghums [Sorghum bicolor (L.) Moench]. Field assessment of somaclonal variation has progressed to the R₂ population, with over 48,000 R₂ seedlings (27,000 plants) in 1,126 rows from 1,055 R₁ plants. A total of 43 variant phenotypes was recovered, including several types of chlorophyll deficiencies, dwarfism, short culm, sterility, narrow leaf, and several previously unreported variants, such as ragged leaf, multibranched heads, and Hydra, a developmental variant which produces large numbers of panicles. Variation production greatly depends on parent genotype and appears to increase with increasing time in cultures. The toal average somaclonal variation rate (based per 100 R₁ plants) and somaclonal variant frequency (based per 100 R₂ plants) estimated in the tested population were 11.3 and 1.6, respectively. Chimerism was found in regenerants. The estimated size of the mutated sector carried by mutant regenerants ranged from the whole plant to less than 3% of a single head. The average proportion of mutated R₁ heads carrying large (80%–100%), medium (40%–80%), and small (<40%) mutated sectors was 38.7%, 26.0% and 35.3%, respectively. Some sector mutations do not appear until the R₃ generation. In order to avoid losing variants, the population for selecting somaclonal variation should be as large as possible. Some of these variants found may be useful for further study or for use in breeding programs.     

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.     

Somaclonal variation in tomato: effect of explant source and a comparison with chemical mutagenesis

Summary Plants were regenerated from leaf, cotyledon, and hypocotyl explants of tomato cv Moneymaker. Various phenotypic alterations were observed among regenerated plants (R₁), but were not transmitted to the progenies, except for ploidy variation. Variation in ploidy level, mainly tetraploidy, occurred in R₁ plants and their R₂ progenies, and the frequency of polyploid plants depended on the explant source. More than 50% of the regenerants derived from hypocotyl explants were found to be polyploid. A correlation was observed between the percentage of polyploid cells present in the explant material in vivo and the frequency of polyploid plants. Several monogenic mutations were recovered in the R₂, four of which were shown to be allelic to known, recessive, single-gene mutants. No significant effect of explant source or duration of tissue culture period on mutant frequency or spectrum was found. For several mutant types that could be scored unambiguously, somaclonal variation was compared to variation induced by treatment of seeds with ethyl methane sulphonate (EMS). The results showed that the mutant frequencies were higher after EMS treatment than those generated through tissue culture. With respect to the mutant spectrum, no clear differences were observed between the spectra obtained after EMS treatment and those after tissue culture. However, tissue culture gave rise to polyploid plants, whereas no ploidy variants occurred after EMS treatment.     

The expression and perpetuation of inherent somatic variation in regenerants from embryogenic cultures of Pennisetum glaucum (L.) R. Br. (pearl millet)

Summary Genetic analysis was conducted on the qualitative and quantitative traits of sexual progeny derived from embryogenic cultures of two inbred lines of Pennisetum glaucum (L.) R. Br. (pearl millet). These lines included a genetically stable inbred of Tift 23 BE and a genetic marker line, derived from Tift 23BE, which bore qualitative genetic markers for a dominant purple plant trait (P) and two recessive traits, early flowering (e₁) and yellow stripe (ys). Tissue culture regenerant populations (R₀) and progeny populations (R₁) produced from these plants by selfing showed no qualitative genetic variation when derived from the genetically stable inbred Tift 23BE. In contrast, stably inherited qualitative variation for a number of genetic markers was observed in R₀, R₁, and R₂ progeny of the genetic marker line. In a population of 1,911 plants regenerated over a 12-month period, 0.02% of the population lost or showed reduced expression of the purple plant trait and 92% of plants were chlorophyll deficient. Plants showing reduction or loss of anthocyanin synthesis also flowered later. None of the purple plants showed any significant variation in flowering time. The incidence of chlorophyll deficiency increased with time in culture, 51 % of the progeny regenerated after 1 month were chlorophyll deficient, while 100% of the plants regnerated after 12 months were chlorophyll deficient. Qualitative variation was also observed in control populations of the genetic marker line where 1 plant in a total of 1,010 lacked purple pigmentation and a total of 6% showed chlorophyll variation in the first generation (S₀). The presence of qualitative variation in controls suggests that the inherent variation present in the original explant was expressed and perpetuated in vitro. Quantitative variation was observed for a number of traits in the first sexual cycle (R₁) of the marker line but did not occur in a subsequent generation, suggesting that this variation was epigenetic.     

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.     

Somaclonal variation in plants regenerated from cultures of soybean

Plants were regenerated from embryogenic and organogenic cultures derived from immature embryos of nine soybean (Glycine max L. Merr.) genotypes and extensive qualitative variation was noted in different regenerated families. Three lethal sectoral albinos were seen in the regenerated plants (R₀). Variants observed in later selfed generations included twin seeds, multiple shoots, dwarfs, abnormal leaf morphology, abnormal leaflet number, wrinkled leaves, chlorophyll deficiency, partial sterility and complete sterility. The frequency of possible mutations ranged from 0 to 4% in R plants as determined by studies of corresponding R₁, R₂, R₃ and R₄ families. No significant differences were seen in the frequencies of possible mutations for embryogenic as compared to organogenic culture derived plants. Chlorophyll deficiency, sterility and wrinkled leaf traits were followed in two or more generations and showed that these traits were inherited stably. The known traits of this nature are controlled by single recessive nuclear genes. Other traits occurred more randomly and not in all generations. The genetic basis of the random variation is not known at the present time. This study indicates that heritable somaclonal variation does occur in tissue culture derived plants of soybean.Abbreviations R₀ Original regenerated plant - R₁ Selfed seeds of R₀ plants - R₂ Selfed seeds of R₁ plants - R₃ Selfed seeds of R₂ plants This research was supported by funds from the Illinois Agricultural Experiment Station and Agrigenetics Inc.     

Screening for grain polyphenol variants from high-tannin sorghum somaclones

Several hundred somaclones established from plants regenerated from embryogenic callus cultures of six high tannin sorghum lines were screened for variants with altered levels of polyphenols in the grain. Grain from over 6000 plants including the R ₁ (primary), R₂, and R₃ generations were analyzed for total phenols, flavan-4-ols, and proanthocyanidins (condensed tannins). Although many variants which had lost the ability to synthesize chlorophyll were found, none of the somaclones tested had lost or greatly reduced the ability to synthesize any of the polyphenols assayed. However, we did observe statistically significant differences in polyphenol concentration between tissue culture-derived R₁ plants and the parental controls. In the R₂ generation the proportion of somaclones which differed significantly from the parents varied from 47% to 68% depending upon genotype. The average somaclonal variation rate and somaclonal variant frequency estimated in the tested population for the three polyphenol characteristics ranged from 37.3% to 40.7% and 5.3% to 7.8%, respectively. Variants with decreased levels of polyphenols were usually epigenetic and reverted back to normal levels in subsequent generations, but those with increased levels usually persisted after two meiotic cycles, indicating they are heritable. Variants with polyphenol levels increased up to 80% or decreased by 30% were selected for in the R₃ generation.     

Agronomic evaluation of tissue-culture-derived soybean plants

Summary Genetic alterations of regenerated plants based on the tissue culture process (somaclonal variation) have become common for many plant species including soybean [Glycine max (L.) Merr.]. The objective of this study was to test for the presence of tissue-culture-derived genetic variation in eight agronomic traits in homozygous progeny regenerated by organogenesis using the commercially important cultivar Asgrow A3127. A total of 86 lines derived by repeated self-pollination of nine regenerated plants was grown in two locations for 2 years. When compared to the unregenerated parent, statistically significant variation (P<0.05) was found for maturity, lodging, height, seed protein and oil, but not for seed quality, seed weight, or seed yield. All of the variation noted was beneficial and did not involve decreased yield. Since the differences were not large, the results indicate that the tissue culture process is not necessarily detrimental to plant performance, which is an important consideration since tissue culture techniques are used in many genetic engineering methods.     

Selection of somaclonal variants with low-temperature germinability in melon (Cucumis melo L.)

Summary Plants were regenerated from adventitious buds and somatic embryos (R₀) of melon (Cucumis melo L.), the cultivar Andes. Somaclonal variants of melon with low temperature germinability were selected from the progenies (R₁) of R₀ plants. Among 5,618 R₁ seeds harvested from 23 R₀ plants that were regenerated from adventitious buds 4 seeds germinated after 5 days of culture at 15 °C (selection rate; 0.07%). However, among 374 R₂ seeds harvested from 2 R₁ plants no seed germinated after 7 days of culture at 14 °C. Among 9,181 R₁ seeds harvested from 50 R₀ plants regenerated from somatic embryos 110 seeds germinated after 5 days of culture at 15 °C (selection rate; 1.20%). Among 3,717 R₂ seeds harvested from 17 R₁ plants 113 seeds germinated after 7 days of culture at 14 °C (selection rate; 3.04%). R₃ seeds were collected from these R₂ plants following self-pollination. Forty-five of the 47 lines (R₃) originated from 10 R₀ plants showed higher germination rates than that of the original cultivar. Selected lines with low-temperature germinability showed greater fruit growth rate than the original cultivar during the middle stage when they were cultivated in a greenhouse under low-temperature conditions. Of fruits harvested from 31 lines, 15 lines showed greater fruit volume than the original cultivar.     

Characterization of transgenic plants derived from hairy roots ofHyoscyamus muticus

Mature plants were regenerated via protoplasts fromAgrobacterium rhizogenes-transformed root cultures ofHyoscyamus muticus L., and chemical analyses were performed on 34 individual plants. The regenerated plants showed strong phenotypic differences from clone to clone as well as from the control plants. Polymerase chain reaction studies revealed that the plants exhibiting the strongest phenotypic alterations contained therol (A, B and C) genes, whereas the plants with fewer alterations had lost them. The plants produced hyoscyamine, scopolamine and a range of different calystegins, and considerable somaclonal variation was observed. Alkaloid production in the plants transgenic for therol genes was clearly reduced. The pattern of calystegins was similar within all the regenerated plants lackingrol genes. Among the plants withrol genes, the calystegin B₁ was not detectable. It seems clear that the presence ofrol genes is detrimental to the alkaloid accumulation in the transgenic plants in contrast to hairy root cultures.Abbreviation PCR Polymerase chain reaction     

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.     

Quantitative trait variation in phenotypically normal regenerants of cotton

Summary Somaclonal variation for quantitative traits could affect the practical utilization of regenerants in cotton improvement. Three groups of experimental lines were derived to analyze variation, including one control group from the explant-source cultivar and two groups of R₃ somaclones from different R₀’s (R₀ = initial regenerant) free of observable chromosomal rearrangements. A three-environment field trial was conducted to evaluate group means, genetic variance, and line performance. Mean seedcotton yields of the somaclonal groups were reduced by 21 and 26% relative to the Coker 310 standard at two locations, but lint percentage and certain fiber properties were improved. Group-by-environment interactions were significant (P<0.05) for 10 of the 12 measured traits. Genetic variance tended to decrease in the somaclones, plant height being an exception. Line performance of the somaclones indicated that 50-boll weight, seed index, and fiber length did not reach the Coker 310 group means. These data suggest that genetic gain will be improved if regenerants of cotton are self-pollinated and the progenies evaluated for quantitative traits before crossing somaclones with the explantsource cultivar or other elite germplasm.     

Agronomic evaluation of inbred lines derived from tissue cultures of maize

Summary Tissue culture-induced variation has been proposed as a novel source of variation for crop improvement. In maize (Zea mays L.), chromosome aberrations and qualitative genetic variants have been induced during in vitro culture. The proportion of regenerated plants carrying such variants has been shown to increase with culture age. The objective of this research was to evaluate the relationship between culture age and somaclonal variation for several agronomic traits. Six sib-pollinated ears of S₀ (F₂) plants in four OH43 ms/A188 populations each provided control seed and embryos for culture initiation. S₂ lines derived from control seed and from plants regenerated 4 and 8 months after culture initiation were grouped according to their source ear and grown in 6 separate trials. A total of 305 tissue culture-derived and 48 control lines were evaluated as lines per se and in a testcross at each of three locations. Tissue culturederived lines and their testcrosses generally had lower grain yield and moisture. Since grain yield and moisture were not positively correlated in any trial, the highest yielding lines could be selected without increasing grain moisture. Grain yield and plant height tended to decrease with culture age. Although tissue culture-derived lines were, on average, inferior, the highest yielding line per se in three of six trials and the top-ranked line in five of six trials for yield and moisture were derived from tissue culture. The results indicate that tissue culture may generate variation for agronomic traits. Some of the variation, particularly the trend towards earlier maturity, could be useful. However, this method may require screening large populations because of the tendency to generate a large proportion of inferior lines.Contribution from Department of Agronomy and Plant Genetics, University of Minnesota, St. Paul, MN 55108. Minnesota Agric. Exp. Stn. Scientific Journal Series Paper No. 15,172     

Chromosome doubling of 2x Solanum species by oryzalin: method development and comparison with spontaneous chromosome doubling in vitro

A potato breeding scheme implies the possibility of ploidy level manipulation either by reducing the chromosome number of cultivars from 48 to 24 to be able to cross them with diploid related species or by doubling diploid material to reach the generally optimal tetraploid level. In vitro spontaneous chromosome doubling is widely used but can lead to somaclonal variation. Since oryzalin has proven to be efficient as a chromosome doubling agent on potato cell suspension cultures, we tried this herbicide on various Solanum species and interspecific diploid hybrids. A 24 h dip in a 28.8 M aqueous oryzalin solution applied on apical buds was the most efficient treatment in terms of tetraploid plant production (mean = 4.1 tetraploid plants for 10 treated buds over 4 genotypes). However 50–100% of the regenerated tetraploid plants acclimatized after in vitro treatment proved to be chimaeric. Consequently, a selection procedure in the progeny was necessary to obtain real and stable doubled clones and final yields were low. This technique is easy to apply and could be a good alternative to chromosome doubling by spontaneous in vitro regeneration in the case of refractory genotypes especially where somaclonal variation is problematic. Percentage of tetraploids among the regenerated plants varied from 6 to 29% with the oryzalin doubling technique while it varied from 20 to 78% by in vitro spontaneous doubling for five diploid genotypes. An observation of the progeny indicated that chimaeras were more frequent using oryzalin (50–100% of the initially supposed tetraploid plants) than when chromosomes doubled spontaneously (4–67% of the initially supposed tetraploid plants).     

Morphological Alterations in Sterile Mutant of Pisum Sativum Obtained Via Somatic Embryogenesis

A sterile mutant of pea (Pisum sativum L. line HM-6) with a number of morphological alterations was found after plant regeneration via somatic embryogenesis. Embryogenic callus was derived from the whole immature zygotic embryo on medium with 2.26 M 2,4-dichlorophenoxyacetic acid. Morphological changes included altered leaflet shape, one pair of leaflets only, altered stipule morphology, shortened internodia, irregular or opposite leaf position on the stem, shortened flower stalk, and aborted flowers resulting in complete sterility. If the isolation of the shoot apex and axillary buds from evidently sterile plant and their culture in vitro resulted in morphologically normal and fertile regenerated plants, the chimaeric nature of R₀ mutant is considered.     

Somaclonal variation in rye (<Emphasis Type="Italic">Secale cereale</Emphasis> L.) analyzed using polymorphic and sequenced AFLP markers

Amplified fragment length polymorphism (AFLP) analysis of 24 in vitro regenerated rye plants was performed in order to evaluate the somaclonal variation rate in this species and to identify rye genomic regions where mutations are preferentially promoted by in vitro culture processes. Regenerated plants were obtained from cell lines derived from immature embryos and plants were regenerated by somatic embryogenesis. Twenty-three regenerants showed variation when compared against sibling plants obtained from the same cell line. A total number of 887 AFLP markers were scored, and 8.8% identified the same polymorphism in plants obtained independently from different cell lines, revealing putative mutational hot spots. Using controlled crossings and analysis of the corresponding progenies, we were able to verify the genetic stability in the next generation for only five of these polymorphisms. The nucleotide sequence of the AFLP amplicon of four of the polymorphic markers was obtained, but only the sequence of two markers was clearly identified in the databases. The sequence of marker A1-303 was identified as part of a tandemly repeated sequence, the 120-bp family, which is located at telomeric regions and is widely distributed among rye chromosomes. The marker A5-375 showed high similarity with regions of Angela retrotransposons.     

Genetic transformation of Arabidopsis thaliana zygotic embryos and identification of critical parameters influencing transformation efficiency.

Summary An efficient procedure for Agrobacterium-mediated transformation of zygotic embryos derived from three different Arabidopsis thaliana ecotypes has been developed. This procedure yielded an average transformation rate of 76% for ecotype C24, and 15–20% for ecotypes Landsberg-erecta and Columbia. A critical step for optimal transformation was the preculture of embryos on a phytohormone-containing medium. Light and electron microscopical studies showed that, during preculture, procambium cells of embryos became highly susceptible to Agrobacterium infection. Transformed cells developed calli and regenerated shoots within 4–5 weeks of culture. A total of 1500 fertile transgenic plants were regenerated. In regenerated plants the presence of inserted DNA was verified by genomic Southern blot analysis, assays of enzymatic activities of reporter genes (neomycin phosphotransferase II and -glucuronidase) as well as by genetic segregation tests. R1 progenies of 45 randomly chosen transformed lines and 150 independent regenerants did not show any somaclonal variations as ascertained by both morphological and cytological criteria. Short duration (7–8 weeks), high efficiency, reproducibility and low frequency of somaclonal variation makes the zygotic embryo transformation particularly well-suited for T-DNA tagging mutagenesis.     

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.     

In vitro response of strawberry cultivars and regenerants to Colletotrichum acutatum

Diseases affecting strawberry (Fragaria × ananassa Duch.) have been of major concern in recent years because of their widespread occurrence and potential for yield loss. Anthracnose, caused by the fungus Colletotrichum acutatum, is one of the most serious diseases of strawberry worldwide. Tissue-culture induced (somaclonal) variation provides one strategy for generating disease-resistant genotypes. As part of a program to generate strawberry germplasm resistant to anthracnose, an in vitro screening system was used to evaluate several commercial cultivars, Chandler, Delmarvel, Honeoye, Latestar, Pelican and Sweet Charlie propagated in vitro, and shoots regenerated from leaf explants of these cultivars for resistance to C.␣acutatum isolate Goff (highly virulent). Regenerants with increased levels of resistance were identified from all of the cultivars. The greatest increases in disease resistance were observed for regenerants from leaf explants of cultivars Pelican and Chandler that exhibited 17.5- and 6.2-fold increases in resistance, respectively. The highest levels of anthracnose resistance (2 to 6% leaf necrosis) were exhibited by regenerants from explants of cultivars Pelican and Sweet Charlie. These studies suggest that generating somaclonal variation may be a viable approach to obtaining strawberry plants with increased levels of anthracnose resistance.     

Using AFLP markers for species differentiation and assessment of genetic variability of in vitro-cultured Papaver bracteatum (section Oxytona)

Summary Amplified fragment length polymorphism (AFLP) markers were employed to deteet genetic variation among species of Papever (section Oxytona) and assess genetic fidelity between in vitro cell lines of Papaver bracteatum and mature plants derived from the propagation of their callus cultures. Regenerated plants exhibited morphological and phytochemical characteristics dissimilar to those of their source material. Thebaine, the dominant alkaloid produced by Papaver bracteatum, was not detected in capsules from mature regenerated accessions, indicating that there may have been a loss of genetic uniformity. Instead, the dominant alkaloid produced by the regenerated plant was shown to be isothebaine (by TLC and GC/MS), a metabolic characteristic of P. pseudo-orientale. A Neighbor-Joining tree constructed from AFLP fingerprints distinetly separates the three species of Oxytona while firmly grouping the in vitro-cultured plants with P. pseudo-orientale. Additionally phytochemical data and chromosome counts indicate that the seed used to initiate cultures was of hybrid origin and ihat the loss in genetic uniformity was not due to somaclonal variation occurring during the in vitro culture process. AFLP fingerprinting was therefore able to differentiate Oxytona species and invesgigate allopolyploidy in closely related papaver species.