- Research article
- Open Access
Tissue culture-induced transpositional activity of mPing is correlated with cytosine methylation in rice
- Frédéric Ngezahayo†1, 2,
- Chunming Xu†1,
- Hongyan Wang1,
- Lily Jiang1,
- Jinsong Pang1 and
- Bao Liu1Email author
© Ngezahayo et al; licensee BioMed Central Ltd. 2009
- Received: 27 December 2008
- Accepted: 15 July 2009
- Published: 15 July 2009
mPing is an endogenous MITE in the rice genome, which is quiescent under normal conditions but can be induced towards mobilization under various stresses. The cellular mechanism responsible for modulating the activity of mPing remains unknown. Cytosine methylation is a major epigenetic modification in most eukaryotes, and the primary function of which is to serve as a genome defense system including taming activity of transposable elements (TEs). Given that tissue-culture is capable of inducing both methylation alteration and mPing transposition in certain rice genotypes, it provides a tractable system to investigate the possible relationship between the two phenomena.
mPing transposition and cytosine methylation alteration were measured in callus and regenerated plants in three rice (ssp. indica) genotypes, V14, V27 and R09. All three genotypes showed transposition of mPing, though at various frequencies. Cytosine methylation alteration occurred both at the mPing-flanks and at random loci sampled globally in callus and regenerated plants of all three genotypes. However, a sharp difference in the changing patterns was noted between the mPing-flanks and random genomic loci, with a particular type of methylation modification, i.e., CNG hypermethylation, occurred predominantly at the mPing-flanks. Pearson's test on pairwise correlations indicated that mPing activity is positively correlated with specific patterns of methylation alteration at random genomic loci, while the element's immobility is positively correlated with methylation levels of the mPing's 5'-flanks. Bisulfite sequencing of two mPing-containing loci showed that whereas for the immobile locus loss of CG methylation in the 5'-flank was accompanied by an increase in CHG methylation, together with an overall increase in methylation of all three types (CG, CHG and CHH) in the mPing-body region, for the active locus erasure of CG methylation in the 5'-flank was not followed by such a change.
Our results documented that tissue culture-induced mPing activity in rice ssp. indica is correlated with alteration in cytosine methylation patterns at both random genomic loci and the elements' flanks, while the stability of mPing positively correlates with enhanced methylation levels of both the flanks and probably the elements per se. Thus, our results implicate a possible role of cytosine methylation in maintaining mPing stability under normal conditions, and in releasing the element's activity as a consequence of epigenetic perturbation in a locus-specific manner under certain stress conditions.
- Methylation Level
- Cytosine Methylation
- Donor Plant
- Bisulfite Sequencing
- Methylation Alteration
Transposable elements (TEs) are sequences capable of changing their physical locations in their host genomes [1, 2]. TEs are ubiquitous constituents of all eukaryotic genomes so far investigated, and particularly abundant in plants, where they can occupy more than 80% of the genomic sequences [3, 4]. TEs are composed of RNA retrotransposons (class I) and DNA transposons (class II). Whereas RNA retrotransposons require a reverse-transcription step to transpose in a "copy-and-paste" manner, DNA transposons transpose via a "cut-and-paste" mode . Therefore, whereas retrotransposons usually reach very high copy numbers, DNA transposons often retain low copies . One exception to this general rule is the miniature inverted-repeat TEs (MITEs), which are DNA transposons, yet they can reach high copy numbers in the range of thousands .
MITEs have been classified into two superfamilies, Tourist-like and Stowaway-like, based on the similarity of their terminal inverted repeats (TIRs) and target site duplications (TSDs) . The possible roles of MITEs in the evolution of structure and function of plant genes were implicated by their preferential association with low-copy, genic regions [6, 7], and shown by several documented cases wherein the presence vs. absence of a particular MITE being correlated with expression states of the genes in question [4–9].
Whole genome data mining in rice (Oryza sativa L.) revealed that MITEs are major components of interspersed repetitive sequences of the genome [10, 11]. Nonetheless, to date only one MITE family, called mPing, has been experimentally demonstrated as transpositionally active in the rice genome [12–14], though some other types of DNA transposons, e.g., nDart  was also shown as active. mPing is a 430 bp DNA sequence with terminal inverted repeats or TIRs (15 bp) and target site duplications or TSDs (TAA or TTA) typical of a Tourist-like MITE [12–14]. Albeit being exceptionally low in copy number compared with other characterized MITE families in plants [3, 16], mPing can be effectively mobilized by several stressful conditions like tissue culture [12, 14], irradiation , hydrostatic pressurization , and interspecific hybridization . Because mPing has no coding capacity, the transposase (TPase) required to catalyze its transposition is provided in trans by related autonomous element(s) [3, 12, 16]. Based on sequence homology, co-mobilization and transpositional capacity in a non-host genome (Arabidopsis thaliana) with mPing, both of the mPing-related, transposase-encoding elements, Ping and Pong, are demonstrated as TPase donors for mPing, though Pong appeared to have a higher mobilizing capacity [12, 14, 19].
Cytosine DNA methylation is an important epigenetic marker that exists in most animal and plant genomes. Whereas in mammalian animals this modification occurs almost exclusively at the CG dinucleotides, cytosines of any sequence context including CG, CHG and CHH (H is any base other than G) can be methylated in plants [20, 21]. Cytosine methylation has been proposed to have diverse cellular functions in eukaryotes, but its primary role was believed to serve as a genome surveillance and defense system such as taming of TEs [22, 23]. Indeed, close correlations between TE activity and its methylation states were documented in several plants including maize [24–27], rice [28–30], and particularly Arabidopsis [31, 32]. More recent studies in Arabidopsis have further strengthened the relationship and even enabled the establishment of causal links between TE activity and its DNA methylation states. For example, it was found in Arabidopsis that silencing of an introduced retrotransposon (Tto1) was caused by hypermethylation of the element, and genome-wide hypomethylation (in the ddm1 mutant background) results in its reactivation and transposition . The ddm1 mutation in Arabidopsis, which results in genome-wide methylation reduction by 70% , has caused transposition of an otherwise dormant endogenous CACTA transposon, and produced a spectrum of new insertions . Furthermore, it was demonstrated that multiple TEs were activated in single, double and triple loss-of-function mutants of the various DNA methyltransferases, MET1, CMT3 and DRM2 in Arabidopsis,which have provided unequivocal evidence for the deterministic role of DNA methylation in controlling both transcriptional and transpositional activities of specific families of TEs [35–37]. These studies also revealed that methylation of CG and CHG play both overlapping and distinct functional roles in maintaining transcriptional quiescence and transpositional immobility of specific types of TEs .
Although stress-induced mobility of mPing has been studied extensively both in its native host (rice) [14, 17, 18] and in an alien genome (Arabidopsis) , it is unclear whether cytosine methylation plays any role in the element's activity. As a first step to explore possible epigenetic mechanisms underlying the regulation of mPing activity, we tested whether alteration of status of cytosine methylation of random genomic loci and regions immediately flanking the element copies might be associated with the element's transposition in rice. To address this issue, we employed tissue culture of three rice ssp. indica cultivars in which mPing can be efficiently mobilized and marked alteration in cytosine methylation of various types occurs. We report that statistically meaningful correlations exist between mPing activity and alteration in cytosine methylation at random genomic loci, and between mPing stability and heavy methylation status of mPing per se as well as regions immediately flanking the element. We propose that cytosine methylation likely plays an important role in maintaining mPing stability under normal conditions, and in releasing the element's activity as a consequence of perturbation in the epigenetic modification by certain stress conditions like tissue culture.
Tissue culture-induced mPingtransposition
Tissue culture-induced alteration in cytosine methylation at random loci across the genome revealed by methylation-sensitive amplified polymorphism (MSAP) analysis
HpaII and MspI are a pair of isoschizomers that recognize the same restriction site (5'-CCGG) but have differential sensitivity to certain methylation states of the two cytosines: HpaII will not cut if either of the cytosines is fully (double-strand) methylated, whereas MspI will not cut if the external cytosine is fully- or hemi- (single-strand) methylated . Thus, for a given DNA sample, the full methylation of the internal cytosine, or hemi-methylation of the external cytosine, at the assayed CCGG sites can be unequivocally identified by MSAP [41–45]. For clarity, we hereby refer to these two types of patterns as CG and CHG methylations, respectively.
Tissue culture-induced alteration in cytosine methylation at mPing-flanking regions revealed by transposon-methylation display (TMD)
Correlation between mPingactivity and alteration in cytosine methylation at random genomic loci
Pearson's correlation coefficient values between the four types of methylation alteration at the CCGG sites detected by MSAP and mPing activity in each or all three rice (ssp. indica) genotypes
Different types of alteration in cytosine methylation and correlation coefficient values
Correlation between mPingimmobility and cytosine methylation level at the mPing-flanking regions
Pearson's correlation coefficient values between mPing stability and cytosine methylation levels at the CCGG sites of genomic regions immediately flanking the immobile copies of mPing in each or all three rice (ssp. indica) genotypes
Methylation level at the CCGG sites flanking immobile mPing copies
Cytosine methylation status of an inactive (immobile) and an active mPing-containing loci determined by bisulfite genomic sequencing
It has been demonstrated that among all kinds of TEs, MITEs are most closely associated with plant genes [6–9]. This, together with their propensity to accumulate to high-copy numbers (relative to other types of Class II or DNA transposons) in the process of transposition, has rendered MITEs as a major cause for natural allelic diversity within or adjacent to plant genes [39, 46]. The rice endogenous MITE mPing is the most active TE so far documented in any organism, and hence, provides an ideal system for studying the cellular mechanism controlling a TE's activity, as well as a tool for elucidating impact of its activity on adjacent genes. Induced transposition of mPing has been firstly discovered independently in three laboratories working with different rice materials, long-term somatic cell cultures of indica rice , newly initiated anther cultures of japonica rice , and gamma-ray irradiated japonica rice lines . The observation of the sharp difference in the copy numbers of mPing between the two cultivated rice subspecies, indica and japonica, as well as between the two groups of japonica cultivars (temperate vs. tropical) has led to the suggestion that its transpositional activity has also been induced by other sources of factors. Indeed, it was found that mPing can be induced to transpose by interspecific hybridization  and hydrostatic pressurization . More recently, it was discovered that in some landraces of japonica rice mPing has undergone dramatic amplifications associated with domestication and breeding , implicating that more potent induction conditions for the element's activity remains to be identified.
Compared with the situation of japonica rice, mPing activity is less studied in indica rice. In this study, somatic cell-derived calli and their regenerants of three rice ssp. indica genotypes which are currently under cultivation in large acreages in Burundi and several other African countries showed high frequencies of transpositional activation of mPing, though genotypic difference in both excision and insertion frequencies are evident.
Accumulated evidence in various organisms has pointed to the importance of epigenetic modification in the form of cytosine methylation as an important mechanism for repressive control of TEs activity (see Introduction). It is unknown whether alteration in this epigenetic modification has contributed to the activation of mPing in any of the hitherto reported cases. Nonetheless, given the inducible nature of mPing transposition by various stressful conditions and under which epigentic modifications are known to alter, it is likely that epigenetic mechanisms like cytosine methylation are involved. To address this issue, it is important to have a system wherein both mPing activity and alteration in cytosine can be concomitantly induced.
We have shown in this study that various types of cytosine methylation alteration occurred in calli and their regenerants in all three studied rice genotypes, which included both hypo- and hyper-methylation that occurred at CG or CHG sites. Therefore, the tissue culture system (donor seed-plants, calli and regenerants) of these rice ssp. indica genotypes provides a system whereby the possible relationship between mPing activity and cytosine methylation can be addressed. Indeed, the often-observed phenomenon of somaclonal variation in plant tissue cultures is the results of concerted action of both genetic and epigenetic instabilities induced by the tissue culture process , and activity of transposons is known to be involved [47, 48]. Furthermore, we recently found that both genetic and epigenetic instabilities in sorghum tissue cultures likely share a common mutagenic basis, as both kinds of instabilities are significantly correlated with disturbed transcript abundance of a set of genes encoding for DNA methyltransferases and 5-methyl-cytosine DNA glycosylases . Therefore, it is reasonable to deduce that there might exist some intrinsic relationships between tissue culture-induced mPing activation and perturbed patterns or levels in cytosine methylation in the rice genome.
As a first step to address this issue, we have demonstrated in this study that tissue culture-induced mPing activity is indeed correlated with alteration in cytosine methylation at randomly sampled loci across the genome. However, this correlation is cryptic, and which becomes evident only when both the mPing activity and methylation alteration are further dissected into more specific aspects. Under such conditions, significant correlations were detected between mPing activity and specific types of cytosine methylation alteration both within each genotype and when all three genotypes were considered as a whole.
Recent studies by transposon-methylation display (TMD) showed that in the rice genome various TEs (including mPing) appeared to reside in genomic regions with different degrees of cytosine methylation modifications . Thus, given the relationship between the mPing activity and alteration in cytosine methylation at globally sampled random genomic loci, discussed above, it is pertinent to ask two questions: (1) Are the genomic regions immediately flanking the mPing copies also underwent methylation alteration? (2) Are the methylation states of the mPing immediate flanking regions important for the element's stability? To answer these two questions, we performed TMD analysis targeting at the various immobile mPing copies in the calli and regenerants from each of the three rice genotypes. We found that both the 5'- and 3'-mPing flanks underwent extensive methylation alteration that could also be classified into four types as in the case of random genomic loci detected by MSAP. However, a striking feature characterizing the methylation alteration of the mPing flanks is that a specific type of alteration, i.e., CNG hypermethylation, occurred at markedly higher frequencies relative to that of the random genomic loci, in all three genotypes (Figure 2). We consider this as an interesting observation, as it suggests that, specifically at the mPing-flanks, loss of CG methylation (commonly occur in tissue culture) was accompanied by rapid hypermethylation of CNG. Given that only the genomic regions flanking the immobile mPing copies were analyzed by the TMD method, this observation may implicate that one factor for ensuring stability of the immobile mPing copies is due to the rapid CHG hypermethylation which might have been capable of compensating for the almost inevitable loss of CG methylation during callus culture (Figure 2). Indeed, the mPing immobility was found as positively correlated only with CNG methylation levels of the 5'-flanking regions but not with that of the 3'-flanks (Table 2). Conceivably, methylation status of the 5'-flanking regions is likely more important for maintaining stability of a TE. Thus, the correlation results are fully supportive for the above speculation that rapid CHG hypermethylation probably have played an important role in maintaining immobility of these mPing copies. Indeed, this possibility was further bolstered by the bisulfite genomic sequencing data for an immobile mPing-containing locus and an active one. This experiment showed that in callus whereas in the immobile locus loss of CG methylation in the 5'-flank was accompanied by an increase in CHG methylation, such a simultaneous loss of CG and gain of CHG methylation did not occur in the active mPing-containing locus; instead, at this locus only loss of CG methylation and no gain of CHG methylation were observed, which though was accompanied with a slight gain of CHH methylation.
The bisulfite sequencing data further suggested that cytosine methylation alteration in the mPing-body regions is also likely playing a role in the element's activity or immobility, depending on the loci. The general hypermethylation in all three types of cytosine methylation, CG, CHG and CHH, in the immobile mPing copy in callus is striking, as the general trend of alteration in cytosine methylation in tissue culture is genome-wide hypomethylation . Therefore, there must be a mechanism protecting loss of methylation from, and even enhancing methylation at, certain genomic regions wherein the immobile mPing copies reside. Conceivably, the small interference (si)-RNA-based RNA-directed DNA methylation (RDM) mechanism is most likely responsible [51–53], and which is in accord with the result that it was CHG and CHH methylation that was increased in the callus (see above). Although it was not possible to analyze the methylation status in the body-region of active mPing copies (they were excised), it is probably safe to speculate that it would not have undergo similar enhancement in methylation. Although in theory the siRNA-based RDM mechanism should act in trans, it is easy to imagine that the different mPing copies being residing at different epigenetic chromatin environments  may cause differential accessibility to the siRNAs cues, and hence, produce the difference [51–53]. Further studies which perhaps entail the construction of loss-of-function mutants for each of the genes encoding for the various chromatin structure-maintenance enzymes including DNA methyltransferases, 5-methylcytosine DNA glycosylases and proteins involved in the siRNA-biogenesis pathways, are required to establish if there exists any causal relationships between mPing activity and alteration in localized and/or more global cytosine methylation modifications in the rice genome.
To investigate a possible role of cytosine methylation in the transpositional activity of mPing, we analyzed the relationship between TD-based mPing transpositions and MSAP- or TMD-based alteration in cytosine methylation in callus and regenerants of three indica rice genotypes. We found that, on one hand, mPing transpositional activity is correlated with alteration in cytosine methylation patterns at randomly sampled genomic loci (revealed by MSAP), and on the other hand,mPing stability is positively correlated with methylation levels of genomic regions immediately flanking the immobile mPing copies (revealed by TMD). In addition, high frequency of CNG hypermethylation occurred specifically at the genomic regions flanking immobile mPing copies, suggesting that this particular type of methylation modification probably plays an immediate role in fortifying local epigenetic control and ensuring mPing stability at these loci, while the failure in this fortification at other mPing-flanking regions might be associated with the element's transposition. Bisulfite sequencing of a locus containing an immobile mPing copy and one containing an active one further bolstered this possibility.
Callus induction, plant regeneration, and genomic DNA extraction
Embryos from mature seeds of three rice, Oryza sativa L., ssp. indica cultivars (V14, V27 and R09), widely cultivated in Burundi and some other Africa countries, were used as source of calli. Sterilization and culture/subculture conditions were essentially as reported  with the following minor modifications: the macro-nutrients of NMB [N6 , micronutrients of MS  and vitamins of B5  were used, which were supplemented with 2 mg/L 2,4-D (2,4-dichlorophenoxyacetic acid), 1 mg/L NAA (naphthaleneacetic acid), and 0.5 mg/L KT (kinetin). After six months of subculture, one portion of the calli were transferred onto regeneration medium, which was the maintenance medium with different growth regulators, namely, containing 2 mg/L BAP (benzyl aminopurine) and 0.1 mg/L NAA, while another portion was used for genomic DNA extraction. Shoots of about 10 cm in length were dissected and transferred onto a rooting medium containing 1 mg/L NAA and 0.1 mg/L BAP. Intact plantlets were transferred into autoclaved loamy soil mixed with sand, where they were maintained in a greenhouse conditions at ~25°C with mild illumination. The plantlets survived and developed into healthy plants at high frequencies (> 80%).
Genomic DNA was extracted from fully expanded leaves of five randomly selected regenerated plants for each genotype (designated as V14Reg1–5, V27Reg1–5 and R09Reg1–5, respectively), two pools of calli for each genotype (designated as V14Ca1–2, V27Ca1–1, and R09Ca1–2, respectively), and the donor plants (pools plants germinated from five seeds) for each genotype (V14D, V27D and R09D). A modified CTAB (hexadecyltrimethylammonium bromide) protocol  was used, and the DNAs were further purified by two-rounds of phenol extractions.
Transposon Display (TD) and methylation-sensitive amplified polymorphism (MSAP) assays
The calli and regenerants together with their corresponding donor plants were subjected to transposon-display (TD) analysis , using nested mPing-specific primers together with a primer designed according to the MseI adapter sequences (see Additional file 1). Digestion/ligation reactions were performed using 300 ng of genomic DNA digested with MseI at conditions specified by the supplier (New England Biolabs Inc.). The MSAP (methylation-sensitive amplified polymorphism) analysis was essentially as reported  using various primer combinations (see Additional file 1). Amplification products were separated by 6% polyacrylamide gel electrophoresis. Only clear and highly reproducible bands between two technical replications (starting fro the digestion/ligation step) were scored. Rational for scoring the variable methylation patterns was based on differential presence/absence of a particular band in HpaII and MspI digestions (see Additional file 4). A subset of variable bands representing mPing excisions or insertions, and different types of alteration in cytosine methylation patterns were excised from the dried polyacrylamide gels and re-amplified with appropriate primers. mPing excisions and insertions were then confirmed by a third mPing-specific primer (further internal of the other two) in combination with the MseI primer (see Additional file 1). Isolated TD and MSAP bands were then cloned and sequenced. BlastN was performed against the whole genome draft sequence of the indica rice genotype 93–11 to determine chromosomal location of active (excisions and insertions) mPing copies, and loci showing alteration in cytosine methylation. BlastX was used for homology analysis of the isolated loci.
Transposon Methylation Display (TMD) analysis
Transposon methylation display (TMD) is a combination of transposon-display (TD) and methylation-sensitive amplified polymorphism (MSAP) . Thus, the mPing-TMD was performed essentially as TD, with modifications only in the restriction enzymes used, namely, MseI in TD being replaced by a pair of isoschizomers, HpaII and MspI. Two sets of consecutive mPing – specific primers respectively targeting the 5'- and 3'-mPing ends were designed and combined with HpaII/MspI adaptor-primers (see Additional file 1). For amplification and silver-based polyacrylamide gel electrophoresis, the same conditions as in TD and MSAP were used . Because of possible confounding effects of mPing transpositions (excisions and insertions), only altering patterns in one of the two enzyme digests (HpaII or MspI) but not in both, which can be unequivocally assigned as due to alteration in cytosine methylation were scored (see Additional file 4).
Data scoring and analysis
In all three studied markers, TD, MSAP and TMD, changes in the calli and/or regenerated plants relative to the donor plants for a given genotype, which were reproducible between two independent experiments, were scored. For TD, bands disappeared from or appeared in calli and/or regenerated plant(s) relative to the donor plants were scored as mPing excisions and insertions, respectively (indeed, all being validated by sequencing). For MSAP, the changing patterns were divided into four major types, CG hypomethylation, CG hypermethylation, CNG hypomethylation and CNG hypermethylation for each genotype (see Additional file 4), as detailed in . For TMD, the scoring rational is similar to MSAP, but only those variable bands that occurred in one of the isoschizomer-digestions, and which can be unequivocally assigned as methylation changes, were scored (see Additional file 4).
Possible correlations between mPing activity (excisions and insertions, based on the TD data) and alteration in cytosine methylation at random genomic loci (based on the MSAP data) were tested by using the Pearson correlation analysis. By the same method, Possible correlations between mPing stability and two types of methylation levels respectively at the 5' and 3' immobile mPing-flanking regions (based on the TMD data) were tested. In both cases, the software SPSS 11.5 for Windows, Bivariate Correlation, Two-tailed, Correlation coefficients, Pearson" http://www.spss.com/statistics/ was used, and the statistical significance was determined.
Genomic DNA from a pool of calli (V27Ca2), one regenerant (V27Reg5), and their corresponding seed-plant of cv. V27 was modified using the EZ DNA Methylation-Gold kit (Zymo Research, http://zymoresearch.com) according to the manufacturer's instructions. Briefly, 900 μl ddH2O, 50 μl M-dissolving buffer and 300 μl M-dilution buffer were added per tube of CT conversion reagent (Zymo Research) prior to use. Then, 130 μl of bisulfite-containing CT conversion reagent was added to 1 μg of DNA in a volume of 20 μl (150 μl total) and mixed, and the samples were then incubated at 98°C for 10 min, and 64°C for 2.5 h. Modified DNA was purified using a Zymo-Spin IC column (Zymo Research) and stored at -20°C until use. The bisulfite sequencing amplifications primer pairs respectively for a locus containing an immobile mPing copy (ITDTG8) and a locus containing an active mPing (showing excision in callus) (ITDTA6), both being arbitrarily chosen from the sequenced bands isolated from the TD profiles (Figure 1), were designed using the Kismeth program (http://katahdin.mssm.edu/kismeth/revpage.pl) and are given in Additional file 6. For each PCR amplification, 2 μl of bisulfite-treated DNA was used as template, and the PCR products were cloned into the pMD18-T vector and sequenced. From 7 to 13 clones for each sample (seed-plant, callus and regenerant), which gave quality sequence reads were included in the analysis. The methylation levels expressed as percentage (%) per site for each of the three types of cytosines, CG, CNG and CHH, were calculated by dividing the number of non-converted (methylated) cytosines by the total number of cytosines of each type within the sequenced regions.
This study was supported by the the State Key Basic Research and Development Plan of China (2005CB120805), the Program for Changjiang Scholars & Innovative Research Team (PCSIRT) in University (#IRT0519) and the Programme for Introducing Talents to Universities (B07017). We express our heartfelt gratefulness to Professor Diter von Wettstein of the Washington State University for constructive discussions pertinent to this study, and to one anonymous reviewer as well as the journal editor for critical comments and suggestions to improve the manuscript.
- McClintock B: The significance of responses of the genome to challenge. Science. 1984, 226 (4676): 792-801.PubMedView ArticleGoogle Scholar
- Slotkin RK, Martienssen R: Transposable elements and the epigenetic regulation of the genome. Nature Reviews Genetics. 2007, 8 (4): 272-285.PubMedView ArticleGoogle Scholar
- Feschotte C, Jiang N, Wessler SR: Plant transposable elements: Where genetics meets genomics. Nature Reviews Genetics. 2002, 3 (5): 329-341.PubMedView ArticleGoogle Scholar
- Dooner HK, Weil CF: Give-and-take: interactions between DNA transposons and their host plant genomes. Curr Opin Genet Dev. 2007, 17 (6): 486-492.PubMedView ArticleGoogle Scholar
- Bennetzen JL: Transposable element contributions to plant gene and genome evolution. Plant Molecular Biology. 2000, 42 (1): 251-269.PubMedView ArticleGoogle Scholar
- Bureau TE, Wessler SR: Mobile inverted-repeat elements of the Tourist family are associated with the genes of many cereal grasses. Proceedings of the National Academy of Sciences of the United States of America. 1994, 91 (4): 1411-1415.PubMedPubMed CentralView ArticleGoogle Scholar
- Zhang Q, Arbuckle J, Wessler SR: Recent, extensive, and preferential insertion of members of the miniature inverted-repeat transposable element family Heartbreaker into genic regions of maize. Proceedings of the National Academy of Sciences of the United States of America. 2000, 97 (3): 1160-1165.PubMedPubMed CentralView ArticleGoogle Scholar
- Xu L, Wang L, Liu T, Qian W, Gao Y, An C: Triton, a novel family of miniature inverted-repeat transposable elements (MITEs) in Trichosanthes kirilowii Maximowicz and its effect on gene regulation. Biochem Biophys Res Commun. 2007, 364 (3): 668-674.PubMedView ArticleGoogle Scholar
- Kimura S, Oyanagi M, Fukuda T, Ohno Y, Hongo C, Itoh Y, Koda T, Ozeki Y: Role of miniature inverted repeat transposable elements inserted into the promoter region of a carrot phenylalanine ammonia-lyase gene and its gene expression. Plant Biotechnology. 2008, 25 (5): 473-481.View ArticleGoogle Scholar
- Feng Q, Zhang Y, Hao P, Wang S, Fu G, Huang Y, Li Y, Zhu J, Liu Y, Hu X, et al: Sequence and analysis of rice chromosome 4. Nature. 2002, 420 (6913): 316-320.PubMedView ArticleGoogle Scholar
- Takagi K, Nagano H, Kishima Y, Sano Y: MITE-transposon display efficiently detects polymorphisms among the Oryza AA-genome species. Breeding Science. 2003, 53 (2): 125-132.View ArticleGoogle Scholar
- Jiang N, Bao Z, Zhang X, Hirochika H, Eddy SR, McCouch SR, Wessler SR: An active DNA transposon family in rice. Nature. 2003, 421 (6919): 163-167.PubMedView ArticleGoogle Scholar
- Nakazaki T, Okumoto Y, Horibata A, Yamahira S, Teraishi M, Nishida H, Inoue H, Tanisaka T: Mobilization of a transposon in the rice genome. Nature. 2003, 421 (6919): 170-172.PubMedView ArticleGoogle Scholar
- Kikuchi K, Terauchit K, Wada M, Hirano HY: The plant MITE mPing is mobilized in anther culture. Nature. 2003, 421 (6919): 167-170.PubMedView ArticleGoogle Scholar
- Fujino K, Sekiguchi H, Kiguchi T: Identification of an active transposon in intact rice plants. Mol Genet Genomics. 2005, 273 (2): 150-157.PubMedView ArticleGoogle Scholar
- Jiang N, Feschotte C, Zhang X, Wessler SR: Using rice to understand the origin and amplification of miniature inverted repeat transposable elements (MITEs). Current Opinion in Plant Biology. 2004, 7 (2): 115-119.PubMedView ArticleGoogle Scholar
- Lin X, Long L, Shan X, Zhang S, Shen S, Liu B: In planta mobilization of mPing and its putative autonomous element Pong in rice by hydrostatic pressurization. Journal of Experimental Botany. 2006, 57 (10): 2313-2323.PubMedView ArticleGoogle Scholar
- Shan X, Liu Z, Dong Z, Wang Y, Chen Y, Lin X, Long L, Han F, Dong Y, Liu B: Mobilization of the active MITE transposons mPing and Pong in rice by introgression from wild rice (Zizania latifolia Griseb.). Mol Biol Evol. 2005, 22 (4): 976-990.PubMedView ArticleGoogle Scholar
- Yang G, Zhang F, Hancock CN, Wessler SR: Transposition of the rice miniature inverted repeat transposable element mPing in Arabidopsis thaliana. Proceedings of the National Academy of Sciences of the United States of America. 2007, 104 (26): 10962-10967.PubMedPubMed CentralView ArticleGoogle Scholar
- Gruenbaum Y, Naveh-Many R, Cedar H, Razin A: Sequence specificity of methylation in higher plant DNA. Nature. 1981, 292 (5826): 860-862.PubMedView ArticleGoogle Scholar
- Vanyushin BF: DNA methylation in plants. Current topics in microbiology and immunology. 2006, 301: 67-122.PubMedGoogle Scholar
- Yoder JA, Walsh CP, Bestor TH: Cytosine methylation and the ecology of intragenomic parasites. Trends in Genetics. 1997, 13 (8): 335-340.PubMedView ArticleGoogle Scholar
- Martienssen RA, Colot V: DNA methylation and epigenetic inheritance in plants and filamentous fungi. Science. 2001, 293 (5532): 1070-1074.PubMedView ArticleGoogle Scholar
- Chandler VLWV: DNA modification of a maize transposable element correlates with loss of activity. Proc Natl Acad Sci USA. 1986, 83: 1767-1771.PubMedPubMed CentralView ArticleGoogle Scholar
- Wang L, Heinlein M, Kunze R: Methylation pattern of Activator transposase binding sites in maize endosperm. Plant Cell. 1996, 8 (4): 747-758.PubMedPubMed CentralView ArticleGoogle Scholar
- Cui H, Fedoroff NV: Inducible DNA demethylation mediated by the maize Suppressor-mutator transposon-encoded TnpA protein. Plant Cell. 2002, 14 (11): 2883-2899.PubMedPubMed CentralView ArticleGoogle Scholar
- Ros F, Kunze R: Regulation of Activator/Dissociation transposition by replication and DNA methylation. Genetics. 2001, 157 (4): 1723-1733.PubMedPubMed CentralGoogle Scholar
- Liu B, Wendel JF: Retrotransposon activation followed by rapid repression in introgressed rice plants. Genome. 2000, 43 (5): 874-880.PubMedView ArticleGoogle Scholar
- Cheng C, Daigen M, Hirochika H: Epigenetic regulation of the rice retrotransposon Tos17. Mol Genet Genomics. 2006, 276 (4): 378-390.PubMedView ArticleGoogle Scholar
- Ding Y, Wang X, Su L, Zhai J, Cao S, Zhang D, Liu C, Bi Y, Qian Q, Cheng Z, et al: SDG714, a histone H3K9 methyltransferase, is involved in Tos17 DNA methylation and transposition in rice. Plant Cell. 2007, 19 (1): 9-22.PubMedPubMed CentralView ArticleGoogle Scholar
- Miura A, Yonebayashi S, Watanabe K, Toyama T, Shimada H, Kakutani T: Mobilization of transposons by a mutation abolishing full DNA methylation in Arabidopsis. Nature. 2001, 411 (6834): 212-214.PubMedView ArticleGoogle Scholar
- Kato M, Takashima K, Kakutani T: Epigenetic control of CACTA transposon mobility in Arabidopsis thaliana. Genetics. 2004, 168 (2): 961-969.PubMedPubMed CentralView ArticleGoogle Scholar
- Hirochika H, Okamoto H, Kakutani T: Silencing of retrotransposons in Arabidopsis and reactivation by the ddm1 mutation. Plant Cell. 2000, 12 (3): 357-368.PubMedPubMed CentralView ArticleGoogle Scholar
- Jeddeloh JA, Stokes TL, Richards EJ: Maintenance of genomic methylation requires a SWI2/SNF2-like protein. Nature Genetics. 1999, 22 (1): 94-97.PubMedView ArticleGoogle Scholar
- Kato M, Miura A, Bender J, Jacobsen SE, Kakutani T: Role of CG and non-CG methylation in immobilization of transposons in Arabidopsis. Current Biology. 2003, 13 (5): 421-426.PubMedView ArticleGoogle Scholar
- Lippman Z, Gendrel AV, Black M, Vaughn MW, Dedhia N, McCombie WR, Lavine K, Mittal V, May B, Kasschau KB, et al: Role of transposable elements in heterochromatin and epigenetic control. Nature. 2004, 430 (6998): 471-476.PubMedView ArticleGoogle Scholar
- Rangwala SH, Richards EJ: Differential epigenetic regulation within an Arabidopsis retroposon family. Genetics. 2007, 176 (1): 151-160.PubMedPubMed CentralView ArticleGoogle Scholar
- Yu J, Hu S, Wang J, Wong GKS, Li S, Liu B, Deng Y, Dai L, Zhou Y, Zhang X, et al: A draft sequence of the rice genome (Oryza sativa L. ssp. indica). Science. 2002, 296 (5565): 79-92.PubMedView ArticleGoogle Scholar
- Naito K, Cho E, Yang G, Campbell MA, Yano K, Okumoto Y, Tanisaka T, Wessler SR: Dramatic amplification of a rice transposable element during recent domestication. Proceedings of the National Academy of Sciences of the United States of America. 2006, 103 (47): 17620-17625.PubMedPubMed CentralView ArticleGoogle Scholar
- McClelland M, Nelson M, Raschke E: Effect of site-specific modification on restriction endonucleases and DNA modification methyltransferases. Nucleic Acids Research. 1994, 22 (17): 3640-3659.PubMedPubMed CentralView ArticleGoogle Scholar
- Reyna-Lopez GE, Simpson J, Ruiz-Herrera J: Differences in DNA methylation patterns are detectable during the dimorphic transition of fungi by amplification of restriction polymorphisms. Mol Gen Genet. 1997, 253 (6): 703-710.PubMedView ArticleGoogle Scholar
- Xiong LZ, Xu CG, Saghai Maroof MA, Zhang Q: Patterns of cytosine methylation in an elite rice hybrid and its parental lines, detected by a methylation-sensitive amplification polymorphism technique. Mol Gen Genet. 1999, 261 (3): 439-446.PubMedView ArticleGoogle Scholar
- Ashikawa I: Surveying CpG methylation at 5'-CCGG in the genomes of rice cultivars. Plant Molecular Biology. 2001, 45 (1): 31-39.PubMedView ArticleGoogle Scholar
- Cervera MT, Ruiz-Garcia L, Martinez-Zapater JM: Analysis of DNA methylation in Arabidopsis thaliana based on methylation-sensitive AFLP markers. Mol Genet Genomics. 2002, 268 (4): 543-552.PubMedView ArticleGoogle Scholar
- Dong ZY, Wang YM, Zhang ZJ, Shen Y, Lin XY, Ou XF, Han FP, Liu B: Extent and pattern of DNA methylation alteration in rice lines derived from introgressive hybridization of rice and Zizania latifolia Griseb. Theor Appl Genet. 2006, 113 (2): 196-205.PubMedView ArticleGoogle Scholar
- Huang X, Lu G, Zhao Q, Liu X, Han B: Genome-wide analysis of transposon insertion polymorphisms reveals intraspecific variation in cultivated rice. Plant physiology. 2008, 148 (1): 25-40.PubMedPubMed CentralView ArticleGoogle Scholar
- Kaeppler SM, Kaeppler HF, Rhee Y: Epigenetic aspects of somaclonal variation in plants. Plant Molecular Biology. 2000, 43 (2–3): 179-188.PubMedView ArticleGoogle Scholar
- Hirochika H, Sugimito K, Otsuki Y, Tsugawa H, Kanda M: Retrotransposon of rice involved in mutations induced by tissue culture. Proc Natl Acad Sci USA. 1996, 93 (15): 7783-7788.PubMedPubMed CentralView ArticleGoogle Scholar
- Zhang MS, Xu CM, Yan HY, Zhao N, von Wettstein D, Liu B: Limited tissue culture-induced mutations and linked epigenetic modifications in F1 hybrids of sorghum pure lines are accompanied by increased transcription of DNA methyltransferases and 5-methylcytosine glycosylases. Plant Journal. 2009, 57: 666-679.PubMedView ArticleGoogle Scholar
- Takata M, Kiyohara A, Takasu A, Kishima Y, Ohtsubo H, Sano Y: Rice transposable elements are characterized by various methylation environments in the genome. BMC Genomics. 2007, 8: 469PubMedPubMed CentralView ArticleGoogle Scholar
- Mathieu O, Reinders J, Caikovski M, Smathajitt C, Paszkowski J: Transgenerational Stability of the Arabidopsis Epigenome Is Coordinated by CG Methylation. Cell. 2007, 130 (5): 851-862.PubMedView ArticleGoogle Scholar
- Mathieu O, Bender J: RNA-directed DNA methylation. Journal of Cell Science. 2004, 117 (21): 4881-4888.PubMedView ArticleGoogle Scholar
- Huettel B, Kanno T, Daxinger L, Aufsatz W, Matzke AJM, Matzke M: Endogenous targets of RNA-directed DNA methylation and Pol IV in Arabidopsis. EMBO Journal. 2006, 25 (12): 2828-2836.PubMedPubMed CentralView ArticleGoogle Scholar
- Liu ZL, Han FP, Tan M, Shan XH, Dong YZ, Wang XZ, Fedak G, Hao S, Liu B: Activation of a rice endogenous retrotransposon Tos17 in tissue culture is accompanied by cytosine demethylation and causes heritable alteration in methylation pattern of flanking genomic regions. Theor Appl Genet. 2004, 109 (1): 200-209.PubMedView ArticleGoogle Scholar
- Chu CC, Wang CC, Sun CS: Establishment of an efficient medium for anther culture of rice through comparative experiments on the nitrogen sources. Scientia Sinica. 1975, 18: 659-668.Google Scholar
- Murashige T: A revised medium for rapid growth and bio assays with tobacco tissue cultures. Phys Plant. 1962, 15: 473-497.View ArticleGoogle Scholar
- Gamborg OL, Miller RA, Ojima K: Nutrient requirements of suspension cultures of soybean root cells. Experimental Cell Research. 1968, 50 (1): 151-158.PubMedView ArticleGoogle Scholar
- Kidwell KK, Osborn TC: Simple plant DNA isolation procedures.In Plant genomes: methods for genetic and physical mapping. Edited by: Beckman JS, Osborn TC. Kluwer Academic Publishers, Dordrecht, The Netherlands; 1992:1-13.View ArticleGoogle Scholar
- Broeck Van den D, Maes T, Sauer M, Zethof J, De Keukeleire P, D'Hauw M, Van Montagu M, Gerats T: Transposon Display identifies individual transposable elements in high copy number lines. Plant Journal. 1998, 13 (1): 121-129.PubMedGoogle Scholar
This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.