Rapid alterations of DNA sequence and cytosine methylation induced by somatic hybridization between Brassica oleracea L. var. italica and Brassica nigra (L.) Koch

Somatic hybrids were produced between hypocotyl protoplasts of Brassica oleracea L. var. italica (broccoli) and mesophyll protoplasts of B. nigra (black mustard) using polyethylene glycol—mediated protoplast fusion. A total of fifteen somatic hybrids derived from six calli (no. 1, 3, 8, 21, 38 and 44) were obtained. Cytological analysis showed that all the hybrids possessed 2n = 34, the sum of the parental chromosomes and the genomic in situ hybridization analysis revealed their BBCC genome constitutes. Moreover, all the hybrids exhibited different type of meiosis abnormalities, which were more usually observed in pollen mother cells at metaphase II/anaphase II (MII/AII, 16.1–39.6 %) than at metaphase I/anaphase I (MI/AI, 7.8–15.2 %). Simple sequence repeat analysis revealed that all the hybrids showed the same cytoplasmic genome as broccoli. Structure and methylation-variation of the nuclear were investigated by amplified fragment length polymorphism (AFLP) and DNA methylation-sensitive amplification polymorphism (MSAP). Our results indicated that all the hybrids mainly had the AFLP and MSAP banding patterns from the addition of two parents plus some alterations. The incidences of the AFLP polymorphic bands in the hybrids showed a range of 9.8–18.7 % while the DNA methylation alteration in the hybrid no. 38 was 4.07 %. This result suggested that somatic hybridization could induce more DNA sequence changes than methylation alterations in the early stage of allotetraploid hybrids.     

红豆杉脱分化过程中的遗传和表观遗传变异

采用扩增片段长度多态性（AFLP）和甲基化敏感扩增多态性（MSAP）技术分析红豆杉脱分化前后基因组DNA和DNA甲基化状态的变化。选用32个AFLP引物组合从红豆杉植株及其愈伤组织分别扩增出1834个片段,无多态性片段产生。这说明红豆杉植株在诱导形成愈伤组织的过程中基因组DNA保持高度的遗传稳定性。另用32个MSAP引物组合从红豆杉植株及其愈伤组织分别扩增出1197个片段,总扩增位点的甲基化水平由脱分化前的12．4％上升为16．2％,表明红豆杉在脱分化过程中的某些位点发生了甲基化。红豆杉脱分化前后的DNA甲基化模式也存在较大差异,说明DNA甲基化对愈伤组织形成有调控作用。     

Analysis of DNA methylation polymorphism in a set of stable chromosome translocation lines

Interspecific hybridization is associated with the origin of novel traits and confers increased vigor compared with the parent lines, although its molecular basis is poorly understood. We report here the identification of genetic and epigenetic changes in a set of wheat–rye translocation lines (R59, R57, and R25) which exhibited novel heritable morphological characteristics compared with the parent lines (MY11 and L155). Genome in situ hybridization and amplified fragment length polymorphism analyses revealed no obvious variations in the primary structure of the genome in different translocation lines, with the exception of the same 1RS chromosome translocation. Global assessment of the extent and pattern of cytosine methylation alterations by methylation-sensitive amplified polymorphism (MSAP) analyses revealed differences in the extent of genomic DNA methylation between the rye and wheat parent lines. Fully-methylated sites were significantly increased and hemi-methylated sites were markedly decreased in the genome of translocation lines compared with the wheat parental cultivar MY11. Comparisons of different MSAP patterns revealed both monomorphic and polymorphic sites between translocation lines and wheat parents. Sequencing of 44 isolated fragments that showed methylation alterations indicated that cellular genes and especially transposable elements were targets for methylation alterations in translocation lines. The present study provides further understanding of the rules governing the distribution and existence of DNA methylation variations induced in the wheat genome during alien germplasm introduction. Furthermore, our study provides insights into the relationship between DNA methylation and hybrid vigor as well as a theoretical basis for further fundamental research and breeding application.     

Genetic diversity analysis of Jatropha curcas L. (Euphorbiaceae) based on methylation-sensitive amplification polymorphism

Genetic analysis of 56 samples of Jatropha curcas L. collected from Thailand and other countries was performed using the methylation-sensitive amplification polymorphism (MSAP) technique. Nine primer combinations were used to generate MSAP fingerprints. When the data were interpreted as amplified fragment length polymorphism (AFLP) markers, 471 markers were scored. All 56 samples were classified into three major groups: γ-irradiated, non-toxic and toxic accessions. Genetic similarity among the samples was extremely high, ranging from 0.95 to 1.00, which indicated very low genetic diversity in this species. The MSAP fingerprint was further analyzed for DNA methylation polymorphisms. The results revealed differences in the DNA methylation level among the samples. However, the samples collected from saline areas and some species hybrids showed specific DNA methylation patterns. AFLP data were used, together with methylation-sensitive AFLP (MS-AFLP) data, to construct a phylogenetic tree, resulting in higher efficiency to distinguish the samples. This combined analysis separated samples previously grouped in the AFLP analysis. This analysis also distinguished some hybrids. Principal component analysis was also performed; the results confirmed the separation in the phylogenetic tree. Some polymorphic bands, involving both nucleotide and DNA methylation polymorphism, that differed between toxic and non-toxic samples were identified, cloned and sequenced. BLAST analysis of these fragments revealed differences in DNA methylation in some known genes and nucleotide polymorphism in chloroplast DNA. We conclude that MSAP is a powerful technique for the study of genetic diversity for organisms that have a narrow genetic base.     

Evaluation of Genetic and Epigenetic Modification in Rapeseed （Brassica napus） Induced by Salt Stress

Salinity is an important limiting environmental factor for rapeseed production worldwide. In this study, we assessed the extent and pattern of DNA damages caused by salt stress in rapeseed plants. Amplified fragment length polymorphism （AFLP） analysis revealed dose-related increases in sequence alterations in plantlets exposed to 10-1000 mmol/L sodium chloride. In addition, individual plantlets exposed to the same salt concentration showed different AFLP and selected region amplified polymorphism banding patterns. These observations suggested that DNA mutation in response to salt stress was random in the genome and the effect was dose-dependant. DNA methylation changes in response to salt stress were also evaluated by methylation sensitive amplified polymorphism （MSAP）. Three types of MSAP bands were recovered. Type Ⅰ bands were observed with both isoschizomers Hpa Ⅱ and Msp Ⅰ, while type Ⅱ and type Ⅲ bands were observed only with Hpa Ⅱ and Msp Ⅰ, respectively. Extensive changes in types of MSAP bands after NaCI treatments were observed, including appearance and disappearance of type Ⅰ, Ⅱ and Ⅲ bands, as well as exchanges between either type Ⅰand type Ⅱ or type Ⅰ and type Ⅲ bands. An increase of 0.2-17.6% cytosine methylated CCGG sites were detected in plantlets exposed to 10- 200 mmol/L salt compared to the control, and these changes included both de novo methylation and demethylation events. Nine methylation related fragments were also recovered and sequenced, and one sharing a high sequence homology with the ethylene responsive element binding factor was identified. These results demonstrated clear DNA genetic and epigenetic alterations in planUets as a response to salt stress, and these changes may suggest a mechanism for plants adaptation under salt stress.     

Identification of exotic genetic components and DNA methylation pattern analysis of three cotton introgression lines from Gossypium bickii

The impact of alien DNA fragments on plant genome has been studied in many species. However, little is known about the introgression lines of Gossypium. To study the consequences of introgression in Gossypium, we investigated 2000 genomic and 800 epigenetic sites in three typical cotton introgression lines, as well as their cultivar (Gossypium hirsutum) and wild parents (Gossypium bickii), by amplified fragment length polymorphism (AFLP) and methylation-sensitive amplified polymorphism (MSAP). The results demonstrate that an average of 0.5% of exotic DNA segments from wild cotton is transmitted into the genome of each introgression line, with the addition of other forms of genetic variation. In total, an average of 0.7% of genetic variation sites is identified in introgression lines. Simultaneously, the overall cytosine methylation level in each introgression line is very close to that of the upland cotton parent (an average of 22.6%). Further dividing patterns reveal that both hypomethylation and hypermethylation occurred in introgression lines in comparison with the upland cotton parent. Sequencing of nine methylation polymorphism fragments showed that most (7 of 9) of the methylation alternations occurred in the noncoding sequences. The molecular evidence of introgression from wild cotton into introgression lines in our study is identified by AFLP. Moreover, the causes of petal variation in introgression lines are discussed.     

Patterns of cytosine methylation in an elite rice hybrid and its parental lines, detected by a methylation-sensitive amplification polymorphism technique

DNA methylation is known to play an important role in the regulation of gene expression in eukaryotes. In this study, we assessed the extent and pattern of cytosine methylation in the rice genome, using the technique of methylation-sensitive amplified polymorphism (MSAP), which is a modification of the amplified fragment length polymorphism (AFLP) method that makes use of the differential sensitivity of a pair of isoschizomers to cytosine methylation. The tissues assayed included seedlings and flag leaves of an elite rice hybrid, Shanyou 63, and the parental lines Zhenshan 97 and Minghui 63. In all, 1076 fragments, each representing a recognition site cleaved by either or both of the isoschizomers, were amplified using 16 pairs of selective primers. A total of 195 sites were found to be methylated at cytosines in one or both parents, and the two parents showed approximately the same overall degree of methylation (16.3%), as revealed by the incidence of differential digestion by the isoschizomers. Four classes of patterns were identified in a comparative assay of cytosine methylation in the parents and hybrid; increased methylation was detected in the hybrid compared to the parents at some of the recognition sites, while decreased methylation in the hybrid was detected at other sites. A small proportion of the sites was found to be differentially methylated in seedlings and flag leaves; DNA from young seedlings was methylated to a greater extent than that from flag leaves. Almost all of the methylation patterns detected by MSAP could be confirmed by Southern analysis using the isolated amplified fragments as probes. The results clearly demonstrate that the MSAP technique is highly efficient for large-scale detection of cytosine methylation in the rice genome. We believe that the technique can be adapted for use in other plant species. Received: 23 October 1998 / Accepted: 11 January 1999     

Comparative analyses of genetic/epigenetic diversities and structures in a wild barley species (Hordeum brevisubulatum) using MSAP, SSAP and AFLP

We analyzed genetic diversity and population genetic structure of four artificial populations of wild barley (Hordeum brevisubulatum); 96 plants collected from the Songnen Prairie in northeastern China were analyzed using amplified fragment length polymorphism (AFLP), specific-sequence amplified polymorphism (SSAP) and methylation-sensitive amplified polymorphism (MSAP) markers. Indices of (epi-)genetic diversity, (epi-)genetic distance, gene flow, genotype frequency, cluster analysis, PCA analysis and AMOVA analysis generated from MSAP, AFLP and SSAP markers had the same trend. We found a high level of correlation in the artificial populations between MSAP, SSAP and AFLP markers by the Mantel test (r > 0.8). This is incongruent with previous findings showing that there is virtually no correlation between DNA methylation polymorphism and classical genetic variation; the high level of genetic polymorphism could be a result of epigenetic regulation. We compared our results with data from natural populations. The population diversity of the artificial populations was lower. However, different from what was found using AFLP and SSAP, based on MSAP results the methylation polymorphism of the artificial populations was not significantly reduced. This leads us to suggest that the DNA methylation pattern change in H. brevisubulatum populations is not only related to DNA sequence variation, but is also regulated by other controlling systems.     

Identification of exotic genetic components and DNA methylation pattern analysis of three cotton introgression lines from <Emphasis Type="Italic">Gossypium bickii</Emphasis>

The impact of alien DNA fragments on plant genome has been studied in many species. However, little is known about the introgression lines of Gossypium. To study the consequences of introgression in Gossypium, we investigated ∼2000 genomic and ∼800 epigenetic sites in three typical cotton introgression lines, as well as their cultivar (Gossypium hirsutum) and wild parents (Gossypium bickii), by amplified fragment length polymorphism (AFLP) and methylation-sensitive amplified polymorphism (MSAP). The results demonstrate that an average of 0.5% of exotic DNA segments from wild cotton is transmitted into the genome of each introgression line, with the addition of other forms of genetic variation. In total, an average of 0.7% of genetic variation sites is identified in introgression lines. Simultaneously, the overall cytosine methylation level in each introgression line is very close to that of the upland cotton parent (an average of 22.6%). Further dividing patterns reveal that both hypomethylation and hypermethylation occurred in introgression lines in comparison with the upland cotton parent. Sequencing of nine methylation polymorphism fragments showed that most (7 of 9) of the methylation alternations occurred in the noncoding sequences. The molecular evidence of introgression from wild cotton into introgression lines in our study is identified by AFLP. Moreover, the causes of petal variation in introgression lines are discussed.     

Genetic and epigenetic consequences of recent hybridization and polyploidy in Spartina (Poaceae)

To study the consequences of hybridization and genome duplication on polyploid genome evolution and adaptation, we used independently formed hybrids (Spartina x townsendii and Spartina x neyrautii) that originated from natural crosses between Spartina alterniflora, an American introduced species, and the European native Spartina maritima. The hybrid from England, S. x townsendii, gave rise to the invasive allopolyploid, salt-marsh species, Spartina anglica. Recent studies indicated that allopolyploid speciation may be associated with rapid genetic and epigenetic changes. To assess this in Spartina, we performed AFLP (amplified fragment length polymorphism) and MSAP (methylation sensitive amplification polymorphism) on young hybrids and the allopolyploid. By comparing the subgenomes in the hybrids and the allopolyploid to the parental species, we inferred structural changes that arose repeatedly in the two independently formed hybrids. Surprisingly, 30% of the parental methylation patterns are altered in the hybrids and the allopolyploid. This high level of epigenetic regulation might explain the morphological plasticity of Spartina anglica and its larger ecological amplitude. Hybridization rather than genome doubling seems to have triggered most of the methylation changes observed in Spartina anglica.     

Genomic Change,Retrotransposon Mobilization and Extensive Cytosine Methylation Alteration in Brassica napus Introgressions from Two Intertribal Hybridizations

Hybridization and introgression represent important means for the transfer and/or de novo origination of traits and play an important role in facilitating speciation and plant breeding. Two sets of introgression lines in Brassica napus L. were previously established by its intertribal hybridizations with two wild species and long-term selection. In this study, the methods of amplified fragment length polymorphisms (AFLP), sequence-specific amplification polymorphism (SSAP) and methylation-sensitive amplified polymorphism (MSAP) were used to determine their genomic change, retrotransposon mobilization and cytosine methylation alteration in these lines. The genomic change revealed by the loss or gain of AFLP bands occurred for ∼10% of the total bands amplified in the two sets of introgressions, while no bands specific for wild species were detected. The new and absent SSAP bands appeared for 9 out of 11 retrotransposons analyzed, with low frequency of new bands and their total percentage of about 5% in both sets. MSAP analysis indicated that methylation changes were common in these lines (33.4–39.8%) and the hypermethylation was more frequent than hypomethylation. Our results suggested that certain extents of genetic and epigenetic alterations were induced by hybridization and alien DNA introgression. The cryptic mechanism of these changes and potential application of these lines in breeding were also discussed.     

Epigenetic instability in genetically stable micropropagated plants of <Emphasis Type="Italic">Gardenia jasminoides</Emphasis> Ellis

Gardenia jasminoides Ellis is an evergreen tropical plant and favorite to gardeners throughout the world. Several studies have documented that in vitro micropropagation can be used for clonal propagation of G. jasminoides Ellis, the efficiency remained low. In addition, no information is available on the genetic and epigenetic fidelity of the micropropagated plants. Here, we report on a simplified protocol for high efficient micropropagation of G. jasminoides Ellis cv. “Kinberly” based on enhanced branching of shoot-tips as explants. The protocol consisted of sequential use of three media, namely, bud-induction, elongation and root-induction. By using two molecular markers, amplified fragment length polymorphism (AFLP) and methylation sensitive amplified polymorphism (MSAP), we analyzed the genetic and DNA methylation pattern stability of 23 morphologically normal plants randomly taken from a sub-population (>100) of micropropagated plants originated from a single shoot-tip. We found that of >1,000 scored AFLP bands across the 23 micropropagated plants, no incident of genetic variation was detected. In contrast, of 750 scored MSAP bands, moderate but clear alteration in several DNA methylation patterns occurred in the majority of the 23 micropropagated plants. The changed methylation patterns involved both CG and CHG sites representing either hyper- or hypo-methylation, which occurred without altering the total methylation levels partly due to concomitant hyper- and hypo-methylation alterations. Our results indicated that epigenetic instability in the form of DNA methylation patterns can be susceptible to the in vitro micropropagation process for G. jasminoides Ellis, and needs to be taken into account in the process of large-scale commercial propagation of this plant.     

MSAP技术及其在植物上的应用

DNA甲基化在植物的很多生命过程中具有重要作用,检测DNA甲基化的技术应运而生。依据对DNA甲基化敏感程度不同的同裂酶,在AFLP技术的基础上发展而来的MSAP技术可以方便的检测全基因组范围内胞嘧啶甲基化模式及程度。该文对MSAP技术的原理、特点、基本程序及应用进行了阐述。     

Stability of potato (<Emphasis Type="Italic">Solanum tuberosum</Emphasis> L.) plants regenerated via somatic embryos,axillary bud proliferated shoots,microtubers and true potato seeds: a comparative phenotypic,cytogenetic and molecular assessment

The stability, both genetic and phenotypic, of potato (Solanum tuberosum L.) cultivar Desiree plants derived from alternative propagation methodologies has been compared. Plants obtained through three clonal propagation routes—axillary-bud-proliferation, microtuberisation and a novel somatic embryogenesis system, and through true potato seeds (TPS) produced by selfing were evaluated at three levels: gross phenotype and minituber yield, changes in ploidy (measured by flow cytometry) and by molecular marker analysis [measured using AFLP (amplified fragment length polymorphism)]. The clonally propagated plants exhibited no phenotypic variation while the TPS-derived plants showed obvious phenotypic segregation. Significant differences were observed with respect to minituber yield while average plant height, at the time of harvesting, was not significantly different among plants propagated through four different routes. None of the plant types varied with respect to gross genome constitution as assessed by flow cytometry. However, a very low level of AFLP marker profile variation was seen amongst the somatic embryo (3 out of 451 bands) and microtuber (2 out of 451 bands) derived plants. Intriguingly, only AFLP markers generated using methylation sensitive restriction enzymes were found to show polymorphism. No polymorphism was observed in plants regenerated through axillary-bud-proliferation. The low level of molecular variation observed could be significant on a genome-wide scale, and is discussed in the context of possible methylation changes occurring during the process of somatic embryogenesis.     

Genetic and epigenetic status of triple exotic consanguinity cotton introgression lines

Introgression lines are some of the most important germplasm for breeding applications and other research conducted on cotton crops. The DNA methylation level among 10 introgression lines of cotton (Gossypium hirsutum) and three exotic parental species (G. arboreum, G. thurberi and G. barbadense) were assessed by methylation-sensitive amplified polymorphism (MSAP) technology. The methylation level in the introgression lines ranged from 33.3 to 51.5%. However, the lines PD0111 and PD0113 had the lowest methylation level (34.6 and 33.3%, respectively) due to demethylation of most non-coding sequences. Amplified fragment length polymorphism (AFLP) was used to evaluate the genetic polymorphism in the cotton introgression lines. A high degree of polymorphism was observed in all introgression lines (mean 47.2%) based on AFLP and MSAP analyses. This confirmed the effects of genetic improvement on cotton introgression lines. The low methylation varieties, PD0111 and PD0113 (introgression lines), clustered outside of the introgression lines based on MSAP data, which was incongruent with an AFLP-based dendrogram. This phenomenon could be caused by environmental changes or introgression of exotic DNA fragments.     

GFP expression as an indicator of somatic hybrids between transgenic Satsuma mandarin and calamondin at embryoid stage

Somatic hybridization was performed via electrofusion between embryogenic suspension-derived protoplasts of transgenic green fluorescent protein (GFP) Satsuma mandarin (Citrus unshiu Marc. cv. Guoqing No. 1) (G1) callus and mesophyll protoplasts of calamondin (Citrus microcarpa Bunge), and three embryoids expressing GFP under UV light were obtained after 60 days of culture. The three embryoids were considered not as diploid cybrids but true allotetraploid somatic hybrids, as it was based on: (1) citrus heterokaryons are generally more vigorous and have higher capacity for embryogenesis as compared with unfused and homo-fused embryogenic callus protoplasts; (2) the callus line of G1 Satsuma mandarin has lost the embryogenesis capacity; and (3) citrus diploid cybrids produced by symmetric fusion always possess nuclear genome of mesophyll parent, and calamondin without GFP gene was used as leaf parent in this study. Subsequent flow cytometry, simple sequence repeat and cleaved amplified polymorphic sequence analysis of one regenerated callus mass and three resulting plants validated this supposition, i.e., the callus was derived from transgenic G1 callus protoplasts, and the three plants were true allotetraploid somatic hybrids possessing nuclear genomic DNA of both parents and cytoplasmic DNA from callus parent. The potential of transgenic GFP citrus callus as suspension parent in citrus somatic fusion to study the mechanism of cybrid formation, create new citrus cybrids, and transfer organelle-encoded agronomic traits was also discussed.     

MSAP markers and global cytosine methylation in plants: a literature survey and comparative analysis for a wild‐growing species

Methylation of DNA cytosines affects whether transposons are silenced and genes are expressed, and is a major epigenetic mechanism whereby plants respond to environmental change. Analyses of methylation‐sensitive amplification polymorphism (MS‐AFLP or MSAP) have been often used to assess methyl‐cytosine changes in response to stress treatments and, more recently, in ecological studies of wild plant populations. MSAP technique does not require a sequenced reference genome and provides many anonymous loci randomly distributed over the genome for which the methylation status can be ascertained. Scoring of MSAP data, however, is not straightforward, and efforts are still required to standardize this step to make use of the potential to distinguish between methylation at different nucleotide contexts. Furthermore, it is not known how accurately MSAP infers genome‐wide cytosine methylation levels in plants. Here, we analyse the relationship between MSAP results and the percentage of global cytosine methylation in genomic DNA obtained by HPLC analysis. A screening of literature revealed that methylation of cytosines at cleavage sites assayed by MSAP was greater than genome‐wide estimates obtained by HPLC, and percentages of methylation at different nucleotide contexts varied within and across species. Concurrent HPLC and MSAP analyses of DNA from 200 individuals of the perennial herb Helleborus foetidus confirmed that methyl‐cytosine was more frequent in CCGG contexts than in the genome as a whole. In this species, global methylation was unrelated to methylation at the inner CG site. We suggest that global HPLC and context‐specific MSAP methylation estimates provide complementary information whose combination can improve our current understanding of methylation‐based epigenetic processes in nonmodel plants.