Alterations in DNA methylation and genome structure in two rice mutant lines induced by high pressure

By using high-pressure treatment, two mutant lines were obtained from a genetically stable japonica rice cultivar Bijing38. Genomic DNA of the mutant lines, together with the original line (Bijing38), was either undigested or digested by Hpa II/Msp I, and then subjected to molecular analysis using two markers, ISSR and RAPD. Results indicated that changes in the PCR amplification profiles of both markers are apparent in the two mutant lines compared with the original rice cultivar, suggesting that there had been both sequence changes and DNA methylation modifications in the mutant lines. Southern blot analysis using diverse sequences, including two cellular genes (S2 and S3), a set of retrotransposons (Osr7, Osr36, Tos19 and more), and a MITE transposon family (mPing and Pong), confirmed the results, and indicated that changes in DNA methylation pattern, genomic structure, and possible activation of some transposons indeed occurred in the mutant lines. Moreover, these changes are stably maintained through selfed generations and in different organs. Thus, our results indicate that it is possible to obtain stable mutants in rice by high pressure treatments, and the molecular basis of the mutants may include both genetic and epigenetic changes. Therefore, high hydrostatic pressure seems a promising approach for plant mutagenesis.     

Changes in DNA methylation and transgenerational mobilization of a transposable element (mPing) by the topoisomerase II inhibitor, etoposide, in rice

ABSTRACT: BACKGROUND: Etoposide (epipodophyllotoxin) is a chemical commonly used as an anti-cancer drug which inhibits DNA synthesis by blocking topoisomerase II activity. Previous studies in animal cells have demonstrated that etoposide constitutes a genotoxic stress which may induce genomic instability including mobilization of normally quiescent transposable elements (TEs). However, it remained unknown whether similar genetically mutagenic effects could be imposed by etoposide in plant cells. Also, no information is available with regard to whether the drug may cause a perturbation of epigenetic stability in any organism. RESULTS: To investigate whether etoposide could generate genetic and/or epigenetic instability in plant cells, we applied etoposide to germinating seeds of six cultivated rice (Oryza sativa L.) genotypes including both subspecies, japonica and indica. Based on the methylation-sensitive gel-blotting results, epigenetic changes in DNA methylation of three TEs (Tos17, Osr23 and Osr36) and two protein-encoding genes (Homeobox and CDPK-related genes) were detected in the etoposide-treated plants (S0 generation) in four of the six studied japonica cultivars, Nipponbare, RZ1, RZ2, and RZ35, but not in the rest japonica cultivar (Matsumae) and the indica cultivar (93-11). DNA methylation changes in the etoposide-treated S0 rice plants were validated by bisulfite sequencing at both of two analyzed loci (Tos17 and Osr36). Transpositional activity was tested for eight TEs endogenous to the rice genome in both the S0 plants and their selfed progenies (S1 and S2) of one of the cultivars, RZ1, which manifested heritable phenotypic variations. Results indicated that no transposition occurred in the etoposide-treated S0 plants for any of the TEs. Nonetheless, a MITE transposon, mPing, showed rampant mobilization in the S1 and S2 progenies descended from the drug-treated S0 plants. CONCLUSIONS: Our results demonstrate that etoposide imposes a similar genotoxic stress on plant cells as it does on animal and human cells, which may induce transgenerational genomic instability by instigating transpositional activation of otherwise dormant TEs. In addition, we show for the first time that etoposide may induce epigenetic instability in the form of altered DNA methylation patterns in eukaryotes. However, penetration of the genotoxic effects of etoposide on plant cells, as being reflected as genetic and epigenetic instability, appears to be in a strictly genotype- and/or generation-dependent manner.     

高静水压诱导水稻变异的初步研究

以高静水压处理水稻粤香占、粤丰占、998、999和毕粳38种子后的当代群体(M1),以及从中筛选到的突变株粤变长、巨无霸、粤丰压变1号-5号、毕籼为材料,研究了静水高压对水稻生长发育及其农艺性状的影响,结果发现：(1)与对照相比,粤香占和998处理当代群体的株高和有效穗数明显增加,但株叶形态没有明显变化;粤丰占、999和毕粳38的处理群体没有明显变化;(2)粤变长和巨无霸从第二代(M2)到第四代(M4)性状稳定,未发现明显分离,但在株高、有效穗数、穗粒数、粒长和千粒重等方面,与对照相比明显不同;(3)在M,代,粤丰压变1号一5号中除粤丰压变2号外的株高都发生了分离,而且粤丰压变4号分离出了大粒型和长芒型的植株;(4)毕籼从Mz代到lVt,代,性状稳定,但其株高、穗长、粒长和穗粒数均比对照显著增加,结实率和千粒重则明显降低;(5)经静水高压处理后的粤丰占种子发芽试验中,出现了双苗和3苗现象。这些结果表明静水高压能够影响水稻的生长发育,并能诱导水稻产生变异。     

Mutants having a low content of 16-kDa allergenic protein in rice (Oryza sativa L.)

Summary Rice mutants containing low levels of the 16-kDa allergenic protein, which is the main allergen in the rice grain for patients of atopic dermatitis due to the intake of rice, were screened, and 4 independent mutant lines with small amounts of this protein were found by SDS gel electrophoresis and immunoblot analysis. These mutants were grouped into two types. Two mutant lines, 85KG-4 and 86RG-18, contained low levels of the 16k-Da and 26-kDa polypeptides and a high level of the 57-kDa polypeptide. The 16-kDa polypeptide content of these mutants was about half that of the original cultivars. Homozygous lines were developed, and these showed normal growth and seed set. The other 2 mutant lines, 87KG-970 and 89WPKE-149, showed traces of the 16-kDa and 26 kDa polypeptides and contained a high level of the 13 kDa polypeptide. The homozygous plants of this type were sterile. All of the mutant lines had floury endosperms. Genetic analysis suggested that low 16-kDa polypeptide content is controlled by a single recessive gene. Attempts to separate of the genes for low 16-kDa polypeptide content and floury endosperm by crossing with the original cultivar were unsuccessful, suggesting the tight linkage of these two genes or pleiotropism of a single mutated gene. The relationship between low 16-kDa polypeptide content and the floury character and the possible use of the mutant as a low allergen rice are discussed.     

A multifaceted genomics approach allows the isolation of the rice Pia-blast resistance gene consisting of two adjacent NBS-LRR protein genes

The Oryza sativa (rice) resistance gene Pia confers resistance to the blast fungus Magnaporthe oryzae carrying the AVR-Pia avirulence gene. To clone Pia, we employed a multifaceted genomics approach. First, we selected 12 R-gene analog (RGA) genes encoding nucleotide binding site-leucine rich repeats (NBS-LRRs) proteins from a region on chromosome 11 that shows linkage to Pia. By using seven rice accessions, we examined the association between Pia phenotypes and DNA polymorphisms in the 10 genes, which revealed three genes (Os11gRGA3-Os11gRGA5) exhibiting a perfect association with the Pia phenotypes. We also screened ethyl methane sulfonate (EMS)-treated mutant lines of the rice cultivar 'Sasanishiki' harboring Pia, and isolated two mutants that lost the Pia phenotype. DNA sequencing of Os11gRGA3-Os11gRGA5 from the two mutant lines identified independent mutations of major effects in Os11gRGA4. The wild-type 'Sasanishiki' allele of Os11gRGA4 (SasRGA4) complemented Pia function in both mutants, suggesting that SasRGA4 is necessary for Pia function. However, when the rice cultivar 'Himenomochi' lacking Pia was transfected with SasRGA4, the Pia phenotype was not recovered. An additional complementation study revealed that the two NBS-LRR-type R genes, SasRGA4 and SasRGA5, that are located next to each other and oriented in the opposite direction are necessary for Pia function. A population genetics analysis of SasRGA4 and SasRGA5 suggests that the two genes are under long-term balancing selection.     

Identification of a deletion in <Emphasis Type="Italic">tms2</Emphasis> and development of gene-based markers for selection

Rice is one of the most important food crops. The temperature-sensitive genic male sterility (TGMS) system provides a great potential for improving food production by hybrids. The use of TGMS system is simple, inexpensive, effective, and eliminates the limitations of the conventional three-line system. A rice gene, tms2, generated by irradiation of a japonica variety has been reported to control TGMS in several rice lines. Previous studies reported genetic markers linked to this gene, and the gene was transferred to an aromatic Thai cultivar. Using information obtained from published databases, we located positions of the reported genetic markers flanking the gene in rice genomic sequences, and developed gene-based markers located inside the flanking markers for polymorphism detection. We found that inbred indica tms2 mutant plants contain about 1 Mb of japonica DNA, in which at least 70 kb was deleted. Using RT-PCR for expression analysis, four genes out of seven genes annotated as expressed proteins located inside the deletion showed expression in panicles. These genes could be responsible for TGMS phenotypes of tms2. In addition, we developed gene-based markers flanking and inside the deletion for selecting the tms2 gene in breeding populations. By genotyping 102 diverse rice lines including 38 Thai rice lines, 5 species of wild rice, and 59 exotic rice lines including TGMS lines and cultivars with desirable traits, a gene-based marker located inside the deletion and one flanking marker were shown to be highly specific for the tms2 mutant.     

异源DNA导入水稻诱发活跃反转子Tos17发生可遗传DNA甲基化变异

用水稻(Oryza sativa L.)内源反转座子Tos17为探针,经Southern杂交在5种含有野生稻(Zizania latifolia Griseb)(菰)DNA片段的水稻渐渗杂交系中检测到了可遗传DNA甲基化变异.在分析的4种甲基化敏感限制性内切酶中,每种酶切都发生了亲本杂交片段的消失和新片段的出现.发生甲基化变异的位点包括对称和不对称的胞嘧啶碱基,也包括腺嘌呤碱基.序列分析表明,与水稻亲本比较,所研究的5种渐渗杂交系在Tos17的2个重要区域(5'-LTR和RT)均未发生序列变异.但甲基化敏感-序列特异性PCR分析证实,每种渐渗杂交系在这2个区域内均发生了广泛的DNA甲基化变异.而且,在2种渐渗杂交系中发现5'-LTR和RT区域的甲基化变异存在协同性.甲基化变异可稳定遗传给后代.因为已有的研究表明,在这5种渐渗杂交系中异源DNA导入均导致了Tos17的激活和转座,因此可以推测DNA甲基化在调控Tos17活性中可能具有一定作用.但反转座子激活和甲基化变异之间的确切关系尚有待进一步研究.     

Aanlysis of short photo-periodic sensitive genic male sterility and molecular mapping of rpms3(t) gene in rice (Oryza sativa L.) using SSR markers

A research was conducted on the pollen fertility of rice sterile lines D52S and D38S responsive to photoperiod during the sensitive stage under natural and controlled conditions. Bulk segregant analysis (BSA) and recessive class approach were applied to identify DNA markers that co-segregate with gene conferring male-sterility in D52S mutant rice. The results showed that in day-light higher or equal to 14.00 h, D52S and D38S rice pollen were fertile; however, they were sterile when day-length was less than 14.00 h. They were therefore considered to be short photo-periodic sensitive genic male sterile lines(Short PGMS lines). Under short day-light conditions, the pollen fertility segregation of F₂ populations from crosses between D52S/Shuhui527 and D52S/Gui99showed 3:1 ratio of fertile to sterile plants suggestingthat male sterility in D52S was controlled by one recessive gene. Two markers RM244 and RM216 located on chromosome number 10 co-segregated completely with the rpms locus. The locus was mapped to the interval between SSR markers RM2571 (6.6 cM) and RM244 (4.6 cM).     

空间搭载诱导水稻种子突变的分子标记多态性分析

以卫星空间搭载广东水稻品种特籼占13干种子,返地种植后经5代选择、培育,获得一批形态及育性变异的突变体及品系（种）,如株高变矮,稻穗变大,雄性不育等。为了探索空间诱变的本质,对选出的6个突变体及2个优良品系,选用了130个10－mer随机扩增多态性DNA（RAPD经物和17对扩增片段长度多态性（AFLP）引物组合,分别对其基因组DNA进行多态性位点扫描分析,两种方法的结果均显示：不同的突变体与原种DNA之间存在不同程度的多态性差异,且由两法得到的结果较接近,为6％－12％。此结果从分子水平上进一步证明了空间环境确实对植物种子存在诱变作用。     

一个水稻矮秆突变体的遗传分析及基因定位

水稻（Oryza sativa）是我国重要的粮食作物之一。水稻矮秆材料的引入掀起了第1次＂绿色革命＂。但近年来,在水稻育种中矮生基因遗传单一的问题越来越突出,已经严重影响到水稻产量的持续提高。利用60Co-γ射线辐照籼稻亲本材料M804获得了一个性状能够稳定遗传的矮秆突变体MU101。对该矮秆突变体和台粳16号杂交获得的F2代的遗传分析表明,该矮秆性状受1对隐性单基因控制,并暂命名为ds1。利用已有的SSR分子标记将DS1基因定位在水稻第5号染色体上,通过扩大群体和开发新的Indel标记,进一步将DS1基因定位在2个Indel标记之间,两者间的物理距离大约为384kb。该研究为DS1基因的克隆及其在生产中的应用奠定了基础。     

DNA methylation changes in photoperiod-thermo-sensitive male sterile rice PA64S under two different conditions

Epigenetic modification can occur at a high frequency in crop plants and might generate phenotypic variation without changes in DNA sequences. DNA methylation is an important epigenetic modification that may contribute to environmentally-induced phenotypic variations by regulating gene expression. Rice Photoperiod-Thermo-Sensitive Genic Male Sterile (PTGMS) lines can transform from sterility to fertility under lower temperatures and short-day (SD) conditions during anther development. So far, little is known about the DNA methylation variation of PTGMS throughout the genome in rice. In this study, we investigated DNA cytosine methylation alterations in the young panicles of PTGMS line PA64S under two different conditions using methylation sensitive amplified polymorphism (MSAP) method. Compared with the DNA methylation level of PA64S under lower temperatures and SD conditions (fertility), higher methylation was observed in PA64S (sterility). The sequences of 25 differentially amplified fragments were successfully obtained and annotated. Three methylated fragments, which are homologous to D2, NAD7 and psaA, were confirmed by bisulfite sequencing and their expression levels were also evaluated by qPCR. Real time quantitative PCR analysis revealed that five of the six selected methylated genes were downregulated in PA64S (sterility). These results suggested that DNA methylation may be involved in the sterility–fertility transition of PA64S under two different environmental conditions.     

Foreign DNA introgression caused heritable cytosine demethylation in ribosomal RNA genes of rice

Significant cytosine demethylation in ribosomal RNA genes (18S or 25S) were detected in all four studied rice lines containing introgressed DNA from wild rice, Zizania latifolia Griseb. In each line, the changed RFLP (restriction fragment length polymorphism) patterns produced with the methylation-sensitive enzyme (HpaII) were identical between two randomly selected individual plants both within and between generations. This indicates that the methylation changes are non-random and stably inherited. Cytosine demethylation in ribosomal RNA genes could be a major cause for the drastically altered phenotypic variations observed in the introgression lines.     

Identification of Kunitz trypsin inhibitor mutations using SNAP markers in soybean mutant lines

The Kunitz trypsin inhibitor (KTi) in soybean has several polymorphic types that are controlled by multiple alleles, which behave in a co-dominant fashion. Of these, Tia and Tib, which differ by nine amino acids, are the predominant types. In order to develop a single nucleotide amplified polymorphism (SNAP) marker for the classification of the predominant KTi types, Tia and Tib, and evaluate KTi activities by differing KTi type total 451 soybean mutant lines (M₁₂–M₁₆ generation) were incorporated in this study. Among 451 soybean mutants, 144 and 13 mutant lines showed decreased and increased trypsin inhibitor activity when compared with the original cultivars, respectively. To identify the KTi type, we designed a SNAP marker. Among 451 mutant lines from 12 soybean cultivars and landraces, 8 mutant lines derived from cvs. Baekwoon, Paldal and Suwon115 showed a change in KTi type when compared with the original cultivars using the SNAP marker. Five mutant lines in Suwon115 changed from Tib to Tia, while two mutant lines derived from cv. Baekwoon and one mutant line derived from cv. Paldal were changed from Tia to Tib. These changes of KTi types were confirmed by sequencing of the KTi genes and non-denaturing polyacrylamide gel electrophoresis of the KTi proteins. To identify the effect of KTi activity based on the change in KTi type, we measured the KTi activity using the three cultivars and eight mutant lines that showed changes in KTi type. Two mutant lines (BW-1 and 7-2) derived from cv. Baekwoon and one mutant line (PD-5-10) from cv. Paldal that changed from Tia to Tib showed lower activity than the original cultivar. In cv. Suwon115, five mutant lines that changed from Tib to Tia showed higher activity than the original cultivar. These results indicate that the designed SNAP marker was capable of identifying the KTi type and that Tia activity was higher than Tib activity in soybean.     

Extent and pattern of DNA methylation alteration in rice lines derived from introgressive hybridization of rice and Zizania latifolia Griseb

We have reported previously that introgression by Zizania latifolia resulted in extensive DNA methylation changes in the recipient rice genome, as detected by a set of pre-selected DNA segments. In this study, using the methylation-sensitive amplified polymorphism (MSAP) method, we globally assessed the extent and pattern of cytosine methylation alterations in three typical introgression lines relative to their rice parent at ∼2,700 unbiased genomic loci each representing a recognition site cleaved by one or both of the isoschizomers, HpaII/MspI. Based on differential digestion by the isoschizomers, it is estimated that 15.9% of CCGG sites are either fully methylated at the internal Cs and/or hemi-methylated at the external Cs in the rice parental cultivar Matsumae. In comparison, a statistically significant increase in the overall level of both methylation types was detected in all three studied introgression lines (19.2, 18.6, 19.6%, respectively). Based on comparisons of MSAP profiles between the isoschizomers within the rice parent and between parent and the introgression lines, four major groups of MSAP banding patterns are recognized, which can be further divided into various subgroups as a result of inheritance of, or variation in, parental methylation patterns. The altered methylation patterns include hyper- and hypomethylation changes, as well as inter-conversion of hemi- to full-methylation, or vice versa, at the relevant CCGG site(s). Most alterations revealed by MSAP in low-copy loci can be validated by DNA gel blot analysis. The changed methylation patterns are uniform among randomly selected individuals for a given introgression line within or among selfed generations. Sequencing on 31 isolated fragments that showed different changing patterns in the introgression line(s) allowed their mapping onto variable regions on one or more of the 12 rice chromosomes. These segments include protein-coding genes, transposon/retrotransposons and sequences with no homology. Possible causes for the introgression-induced methylation changes and their implications for genome evolution and crop breeding are discussed.Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.Z. Y. Dong and Y. M. Wang have equally contributed to the work.     

Development of AFLP-derived STS markers for the selection of 5-methyltryptophan-resistant rice mutants

To increase the specific free amino acid content in the japonica rice (Oryza sativa L.) cultivar Donganbyeo, mutant cell lines resistant to growth inhibition by 5-methyltryptophan (5MT) were selected from embryo-cultured callus irradiated with 50 Gy gamma-rays. Four 5MT-resistant homozygous M₄ lines, MRI-40, MRI-116, MRII-8, and MRII-12, were obtained. The mean content of nine free essential amino acids were 70.1, 72.5, 31.7, and 35.4% greater than the original variety in these four mutant lines, respectively. For AFLP analysis, 8 EcoRI (+2) and 8 MseI (+3) primers used in 45 primer combinations generated a total of 3,684 bands with a mean of 82 bands, of which 361 (9.8%) were clearly polymorphic with the control cultivar, the four 5MT-resistant mutants, and five sensitive lines. The lines were grouped into three clusters through cluster analysis using unweighted pair grouping method of averages. The 36 polymorphic PCR products present only in the four homozygous 5MT-resistant lines were cloned and sequenced, and 10 of these sequenced products were converted into sequence tagged site (STS) markers. These STS primer sets were designated OSMR1–OSMR10. Six STS primer sets (OSMR1, OSMR2, OSMR3, OSMR4, OSMR5, and OSMR6) generated a single monomorphic PCR product identical in size to the original AFLP fragments. The broad applicability of these STS markers for the screening of 5MT resistance was evaluated with seven putative 5MT-resistant M₂ plants (PM-1 to PM-7). Four STS markers (OSMR1, OSMR2, OSMR4, and OSMR5) out of six STS primer sets were revealed as polymorphic products between the control cultivar and the seven M₂ plants. These markers can be utilized for the fine selection of 5MT resistance in rice, and this PCR-screening technique is less time-consuming, less labor-intensive, and more accurate and reliable than selection based solely on phenotypic evaluation involving soaking in 5MT solutions.Abbreviations AFLP Amplified fragment length polymorphism - MAS Marker-assisted selection - STS Sequence tagged site - UPGMA Unweighted pair grouping method of averages - 5MT 5-Methyltryptophan