Variation in potato microplant morphology in vitro and DNA methylation

Heterotrophic and autotrophic culture in agar and in polyurethane foam, the latter used as an alternative tissue support to agar, resulted in potato microplants with different in vitro morphologies. The microplants were visually characterised in terms of their relative developmental maturity, by comparing the respective leaf shapes in vitro with ontogenetic differences in leaf shape in glasshouse-grown potato plants. Cytosine methylation in the DNA of microplants of the different morphologies was determined using a method based on the AFLP technique but employing methylation-sensitive restriction enzymes (MSAP analysis) to test the hypothesis that DNA methylation could be used to characterise differences in microplant development in vitro. In three of the four treatments there was a good correlation between the visual assessment of relative morphological maturity and DNA base methylation levels. In these microplants there was increased DNA methylation in the leaves with mature leaf morphology represented by a decreased number of restriction fragments. The fourth in vitro morphology had the most juvenile leaf shape but did not have the predicted level of DNA methylation, having a relatively low number of restriction fragments. Subtraction analysis was used to discriminate the fragments that were unique to the juvenile and mature in vivo leaf morphologies. Comparison of the fragment patterns from the microplants with the latter reference profiles, confirmed the relationship with the total DNA methylation as detected by MSAP analysis, that is, the number of common fragments with the juvenile or mature in vivo leaf profiles, respectively. However, none of the fragment profiles, while sharing some common bands at random, was identical to any other; or to that of either the juvenile or mature in vivo leaf. The anomalous relationship of the microplants with most juvenile leaf shape and highest DNA methylation was confirmed. The measurement of DNA methylation in in vitro plants is discussed in the context of the development of a method to assess the quality of microplants produced by different in vitro protocols.     

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.     

Detection of DNA methylation pattern in thidiazuron-induced blueberry callus using methylation-sensitive amplification polymorphism

During the normal developmental process, programmed gene expression is an essential phenomenon in all organisms. In eukaryotes, DNA methylation plays an important role in the regulation of gene expression. The extent of cytosine methylation polymorphism was evaluated in leaf tissues collected from the greenhouse grown plants and in in vitro-derived callus of three lowbush and one hybrid blueberry genotypes, using methylation-sensitive amplification polymorphism (MSAP) technique. Callus formation started from the leaf segments after 4 weeks of culture on a thidiazuron (TDZ) containing medium. Maximum callus formation (98 %) was observed in the hybrid blueberry at 1.0 mg dm^-3 TDZ. Although noticeable changes in cytosine methylation pattern were detected within the MSAP profiles of both leaf and callus tissues, methylation events were more polymorphic in calli than in leaf tissues. The number of methylated CCGG sites varied significantly within the genotypes ranging from 75 to 100 in leaf tissues and from 215 to 258 in callus tissues. Differences in the methylation pattern were observed not only in a tissue-specific manner but also within the genotype in a treatment specific manner. These results demonstrated the unique effect of TDZ and the tissue culture process on DNA methylation during callus development.     

Genetic and molecular analysis of tissue-culture-derived Ac elements

Summary Our previous experiments on maize (Zea mays L.) plants regenerated from tissue culture revealed genetic activity characteristic of the transposable element Activator (Ac) in the progeny of 2–3% of the plants tested, despite the lack of Ac activity in the progenitor plants. The objective of the present study was to determine whether the presence of Ac activity in tissue-culture-derived plants was associated with changes in the number or structure of Ac-homologous DNA sequences. Families segregating for Ac activity were obtained by crossing plants heterozygous for Ac activity onto Ac-responsive tester plants. A DNA probe derived from a previously isolated Ac sequence was used to examine the Ac-homologous sequences within individual progeny seedlings of segregating families and noncultured control materials. All plants tested had six or more Ac-homologous DNA sequences, regardless of whether Ac activity was present. In the segregating progeny of one tissue-culturederived plant, a 30-kb Ac-homologous SstI restriction fragment and a 10-kb Ac-homologous BglII restriction fragment were found to cosegregate with Ac activity. We propose that these fragments contained a previously silent Ac sequence that had been activated during tissue culture. Although one or more Ac sequences were often hypomethylated at internal PvuII and HpaII sites in plants with Ac activity, hypomethylation was not a prerequisite for activity. Reduced methylation at these sites may have been a result rather than a cause of Ac activity.     

Absence of mitochondrial and chloroplast DNA recombinations in Brassica napus plants regenerated from protoplasts,protoplast fusions and anther culture

Summary Over 400 Brassica napus plants regenerated from individual protoplasts, from protoplast fusions and from anther culture were analysed for chloroplast and mitochondrial genome rearrangements by restriction fragment length polymorphisms. None were detected, attesting to the fidelity of the tissue culture procedures employed. In the majority of protoplast fusion products, the cytoplasmic organelles had completely sorted out at the callus stage but three regenerated plants possessed mixed parental populations of mitochondrial genomes and one regenerant contained mixed chloroplast genomes. In all four examples, the cytoplasmic genome sorted out in planta in favor of one parental type which was faithfully maternally transmitted to progeny.     

DNA variation in tissue-culture-derived rice plants

Summary Regenerants of rice were examined by RFLP analysis to determine the occurrence and extent of somaclonal variation. DNA polymorphisms were observed both among plants regenerated from different callus cultures as well as among sibling plants derived from a single callus. Regardless of the basal medium, a higher degree of genetic instability was found among plants regenerated from callus cultures maintained for longer incubation periods (67 days) than among those from shorter incubation periods (28 days). Detailed analysis showed that in several regenerants, there was a close correlation among those plants exhibiting DNA rearrangements and those with apparent methylation changes. Such alterations were observed with both structural and housekeeping genes.     

Comprehensive molecular characterization of tissue-culture-derived Hordeum marinum plants

Summary Scuttelar calli of Hordeum marinum readily and efficiently regenerate functional plants. In order to assess genetic variability among the regenerants we employed multiple analytic tools, which included molecular and biochemical assays. Total DNA extract from regenerated plants was digested with at least two restriction enzymes and hybridized to four nuclear and six mitochondrial coding sequences, in addition to one nuclear and three mitochondrial noncoding probes. SDS-PAGE analyses of hordein extracted from seeds of regenerated plants and activity assays of -amylase were also performed. The nuclear and mitochondrial genomes of 50 regenerated plants demonstrated relative stability when assessed with coding sequences and by biochemical analyses. However, the mitochondrial noncoding probes revealed one qualitative somaclonal variant characterized by a loss of a hybridizing fragment. Moreover, changes in the methylation patterns of the rRNA genes and the nontranscribed spacer were revealed in another regenerated plant. The albino plant regenerated was characterized by a loss of three chloroplast DNA BamHI fragments.     

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.     

Non-symmetrical cytosine methylation in tobacco pollen DNA

We have detected sequence-specific non-symmetrical cytosine methylation within a 140 bp region of the promoter for the tobacco auxin-binding protein gene T85 in pollen DNA. Direct sequencing of the population of bisulphite reaction products showed that, in this region, 10 out of a possible 49 cytosine residues were methylated at a high frequency in pollen whereas the corresponding region from somatic cells (leaf DNA) did not show a detectable level of methylation. The context of these sites was 1×m⁵CpTpC, 1×m⁵CpGpT, 1×m⁵CpCpT, 2×m⁵CpTpT, 2×m⁵CpGpG, and 3×m⁵CpApT of which only m⁵CpGpG and m⁵CpGpT fitted the consensus sequence for symmetrical methylation in plants.     

Analysis of DNA methylation in different maize tissues

DNA methylation plays an important role in gene expression regulation during biological development and tissue differentiation in plants. This study adopted methylation-sensitive Amplified fragment length polymorphism （AFLP） to compare the levels of DNA cytosine methylation at CCGG sites in tassel, bracteal leaf, and ear leaf from maize inbred lines, 18 White and 18 Red, respectively, and also examined specific methylation patterns of the three tissues. Significant differences in cytosine methylation level among the three tissues and the same changing tendency in two inbred lines were detected. Both MSAP （methylation sensitive amplification polymorphism） ratio and full methylation level were the highest in bracteal leaf, and the lowest in tassel. Meanwhile, different methylation levels were observed in the same tissue from the inbred lines, 18 White and 18 Red. Full methylation of internal cytosine was the dominant type in the maize genome. The differential methylation patterns in the three tissues were observed. In addition, sequencing of nine differentially methylated fragments and the subsequent blast search revealed that the cytosine methylated 5 ＇ -CCGG-3 ＇ sequences were distributed in repeating sequences, in the coding and noncoding regions. Southern hybridization was used to verify the methylation polymorphism. These results clearly demonstrated the power of the MSAP technique for large-scale DNA methylation detection in the maize genome, and the complexity of DNA methylation change during plant growth and development. The different methylation levels may be related to specific gene expression in various tissues.     

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.     

DNA methylation inhibits propagation of tomato golden mosaic virus DNA in transfected protoplasts

The effects of methylation on plant viral DNA replication have been studied inNicotiana tabacum protoplasts transfected with DNA of the geminivirus tomato golden mosaic virus (TGMV). The transfected cells were also used to determine whether experimentally introduced methylation patterns are maintained in extrachromosomal viral DNA. Replacement of cytosine residues with 5-methylcytosine (m⁵C) reduced the amount of viral DNA which accumulated in transfected protoplasts. The reduction was observed whether m⁵C residues were substituted for cytosine residuesin vitro in either the viral strand or the complementary strand of double-stranded circular inoculum DNAs containing tandemly repeated copies of the A component of the TGMV genome. Both limited and extensive cytosine methylation of TGMV DNA sequencesin vitro was not propagated in progeny viral DNA. The absence of detectable maintenance-type methylation of the transfecting TGMV DNA sequences may be related to the lack of methylation observed in double-stranded TGMV DNA isolated from infected plants.     

DNA methylation increases throughout Arabidopsis development

We used amplified fragment length polymorphisms (AFLP) to analyze the stability of DNA methylation throughout Arabidopsis development. AFLP can detect genome-wide changes in cytosine methylation produced by DNA demethylation agents, such as 5-azacytidine, or specific mutations at the DDM1 locus. In both cases, cytosine demethylation is associated with a general increase in the presence of amplified fragments. Using this approach, we followed DNA methylation at methylation sensitive restriction sites throughout Arabidopsis development. The results show a progressive DNA methylation trend from cotyledons to vegetative organs to reproductive organs.     

A DNA target of 30 bp is sufficient for RNA-directed DNA methylation

In higher plants, RNA-DNA interactions can trigger de novo methylation of genomic sequences via a process that is termed RNA-directed DNA methylation (RdDM). In potato spindle tuber viroid (PSTVd)-infected tobacco plants, this process can potentially lead to methylation of all C residues at symmetrical and nonsymmetrical sites within chromosomal inserts that consist of multimers of the 359-bp-long PSTVd cDNA. Using PSTVd cDNA subfragments, we found that genomic targets with as few as 30 nt of sequence complementarity to the viroid RNA are detected and methylated. Genomic sequencing analyses of genome-integrated 30- and 60-bp-long PSTVd subfragments demonstrated that de novo cytosine methylation is not limited to the canonical CpG, CpNpG sites. Sixty-base-pair-long PSTVd cDNA constructs appeared to be densely methylated in nearly all tobacco leaf cells. With the 30-bp-long PSTVd-specific construct, the proportion of cells displaying dense transgene methylation was significantly reduced, suggesting that a minimal target size of about 30 bp is necessary for RdDM. The methylation patterns observed for two different 60-bp constructs further suggested that the sequence identity of the target may influence the methylation mechanism. Finally, a link between viroid pathogenicity and PSTVd RNA-directed methylation of host sequences is proposed.     

DNA methylation of retrotransposons,DNA transposons and genes in sugar beet (Beta vulgaris L.)

The methylation of cytosines shapes the epigenetic landscape of plant genomes, coordinates transgenerational epigenetic inheritance, represses the activity of transposable elements (TEs), affects gene expression and, hence, can influence the phenotype. Sugar beet (Beta vulgaris ssp. vulgaris), an important crop that accounts for 30% of worldwide sugar needs, has a relatively small genome size (758 Mbp) consisting of approximately 485 Mbp repetitive DNA (64%), in particular satellite DNA, retrotransposons and DNA transposons. Genome‐wide cytosine methylation in the sugar beet genome was studied in leaves and leaf‐derived callus with a focus on repetitive sequences, including retrotransposons and DNA transposons, the major groups of repetitive DNA sequences, and compared with gene methylation. Genes showed a specific methylation pattern for CG, CHG (H = A, C, and T) and CHH sites, whereas the TE pattern differed, depending on the TE class (class 1, retrotransposons and class 2, DNA transposons). Along genes and TEs, CG and CHG methylation was higher than that of adjacent genomic regions. In contrast to the relatively low CHH methylation in retrotransposons and genes, the level of CHH methylation in DNA transposons was strongly increased, pointing to a functional role of asymmetric methylation in DNA transposon silencing. Comparison of genome‐wide DNA methylation between sugar beet leaves and callus revealed a differential methylation upon tissue culture. Potential epialleles were hypomethylated (lower methylation) at CG and CHG sites in retrotransposons and genes and hypermethylated (higher methylation) at CHH sites in DNA transposons of callus when compared with leaves.     

水稻花药培养植株后代的DNA变异

对籼稻圭６３０和粳稻０２４２８及其Ｆ１通过花药培养获得的８１个ＤＨ系进行了ＲＦＬＰ分析,有２８个探针揭示了ＤＮＡ变异。８１个ＤＨ系不同程度地发生了变异,并具有以下特点：（１）ＤＮＡ变异类型包括限制性片段长度的变化、９ＮＡ片段的丢失以及ＤＮＡ序列的扩增;（２）变异发生在籼稻圭６３０供体片段中的频率高于粳稻０２４２８,表现出基因型差异;（３）染色体组中第３、８、９和１０染色体较少发生变异,在其它染色体上均存在易变异位点;（４）在染色体的一些区段,相邻的探针均揭示了ＤＮＡ变异,表明在染色体上存在ＤＮＡ易变异区域;（５）变异位点和变异类型具有特异性,在同一位点不同的ＤＨ系中发生相同的变异。     

Amplification of repeated DNA sequences in wheat X rye hybrids regenerated from tissue culture

Summary Previous C-banding analysis of wheat (Triticum aestivum)X rye (Secale cereale) hybrids regenerated from tissue culture revealed enlarged C-bands in some rye chromosomes, but the molecular nature of the change was not determined. In situ hybridization using two DNA probes containing repeated sequences from rye telomeric heterochromatin was conducted on these wheatX rye hybrids and their progeny to investigate the occurrence of amplification in repeated sequences. Clones pSC 74 and pSC 119, which contain sequences from the 480-bp and 120-bp repeated DNA families of rye, respectively, were used as probes. Amplification of 480-bp repeated sequences in the short arm telomere of chromosome 7R was detected in three wheatxrye hybrids and their progeny. The amplified 480-bp sequences were detected by an enlarged hybridization site for pSC 74 at the 7RS telomere, and by the appearance at this same telomeric site of an unlabeled, blue chromosome segment in an otherwise completely brown chromosome hybridizing entirely to the biotin-labeled pSC 119 probe. This variant form of chromosome 7R was not observed in several Chaupon plants, or in the other hybrids derived from the same embryos, indicating the origin of the change in tissue culture. The amplified sequences were inherited up to at least three generations. Deletions and translocations were also observed.Contribution No. 87-9-J, Kansas Agricultural Experiment Station, Kansas State University     

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.     

Inhibition of cytosine methylation allows efficient cloning of T-DNA tagged plant DNA ofArabidopsis thaliana by plasmid rescue

Summary Plasmid rescue can provide an efficient way of cloning T-DNA-tagged genomic DNA of plants. However, rescue has often been hampered by extensive rearrangements in the cloned DNA. We have demonstrated using a transgenic line ofArabidopsis thaliana that the plant DNA flanking the T-DNA tag was heavily cytosine methylated. This methylation could be completely inhibited by growing the plants in the presence of azacytidine. Rescue of the T-DNA tag together with the flanking plant genomic DNA sequences from nontreated control plants into an modified cytosine restriction (mcr) proficient strain ofEscherichia coli resulted in rearrangements of the majority of the rescued plasmids. These rearrangements could be avoided if the methylation was inhibited in the transgenic plants by azacytidine treatment or by cloning into anmcr-deficient strain ofE. coli. The results indicate that cytosine methylation of the DNA in the transgenic plants is the main cause of the DNA rearrangements observed during plasmid rescue and suggest efficient strategies to eliminate such artifacts.