Ty1-copia retrotransposon-based SSAP marker development and its potential in the genetic study of cucurbits.

Three long terminal repeat (LTR) sequences of Ty1-copia retrotransposons were identified in cucumber (Cucumis sativus L.) and named Tcs 1, Tcs 2, and Tcs 3. A sequence-specific amplification polymorphism (SSAP) marker system based on these LTR sequences displayed a higher level of polymorphism than AFLPs in cucumber. This marker system could also detect loci in other Cucumis species for genetic diversity analysis. The three Tcs LTRs existed within the exons of genes because of the effective amplification band patterns from the cDNA templates. The potential usefulness of the SSAP marker system in studies of the evolution of genes or genomes was verified after exploring loci changes in first and second generations of a synthetic allotetraploid in Cucumis. This study is the first report of the development of a retrotransposon-based marker system and the SSAP technique in cucurbits.     

Development of retrotransposon primers and their utilization for germplasm identification in Diospyros spp. (Ebenaceae)

Retrotransposons play an important role in plant genetic instability and genome evolution. Retrotransposon-based molecular markers are valuable tools to reveal the behavior of retrotransposons in their host genome. In this study, suppression polymerase chain reaction was used, for the first time, to develop retrotransposon long terminal repeat (LTR) and polypurine tract (PPT) primers in Japanese persimmon (Diospyros kaki Thunb.), which were then employed for germplasm identification by means of interretrotransposon-amplified polymorphism (IRAP), sequence-specific amplified polymorphism (SSAP) and retrotransposon-microsatellite-amplified polymorphism (REMAP) molecular markers. The results showed that 16 out of 26 primers produced expected amplifications and abundant polymorphisms by IRAP in 28 genotypes of Diospyros. Moreover, some of these primers were further successfully used in REMAP and SSAP analysis. Each type of molecular markers produced unique fingerprint in 28 genotypes analyzed. Among the primers/primer combinations, two IRAP primers and four SSAP primer combinations could discriminate all of the germplasm solely. Further comparative analysis indicated that IRAP was the most sensitive marker system for detecting variability. High level of retrotransposon insertion polymorphisms between bud sports were detected by IRAP and SSAP, and the primers/primer combinations with powerful discrimination capacity for two pairs of bud sports lines were further obtained. Additionally, possible genetic relationships between several Japanese persimmon were discussed. To our knowledge, this is the first report on the development of retrotransposon LTR and PPT primers in Diospyros, and the retrotransposon primers developed herein might open new avenue for research in the future.     

植物LTR反转录转座子的研究进展

反转录转座子是真核生物基因组中普遍存在的一类可移动的遗传因子,它们以RNA为媒介,在基因组中不断自我复制。在高等植物中,反转录转座子是基因组的重要成分之一。反转录转座子可以分为5大类型,其中以长末端重复（LTR）类型报道较多。LTR类型由于其首尾具有长末端重复序列,内部含有PBS、PPT、GAG和POL开放阅读框、TSD等结构,可以采用生物信息学软件进行预测。LTR反转录转座子的活性受到自身甲基化和环境因素的影响,DNA甲基化抑制反转录转座子转座,而外界环境的刺激能够激活转座子,从而影响插入位点周边基因的表达。同时由于LTR反转录转座子在植物中普遍存在,丰富的拷贝数以及多态性为新型分子标记（RBIP、SSAP、IRAP、REMAP）的开发提供了良好的素材。该文对近年来国内外有关植物反转录转座子的类型、结构特征、 LTR反转录转座子的活性及其影响因素、 LTR反转录转座子的预测以及标记开发等方面的研究进展进行综述。     

Comparative analyses of genetic diversities within tomato and pepper collections detected by retrotransposon-based SSAP, AFLP and SSR

The retrotransposon-based sequence-specific amplification polymorphism (SSAP) marker system was used to assess the genetic diversities of collections of tomato and pepper industrial lines. The utility of SSAP markers was compared to that of amplified fragment length polymorphism (AFLP) and simple sequence repeat (SSR) markers. On the basis of our results, SSAP is most informative of the three systems for studying genetic diversity in tomato and pepper, with a significant correlation of genetic relationships between different SSAP datasets and between SSAP, AFLP and SSR markers. SSAP showed about four- to ninefold more diversity than AFLP and had the highest number of polymorphic bands per assay ratio and the highest marker index. For tomato, SSAP is more suitable for inferring overall genetic variation and relationships, while SSR has the ability to detect specific genetic relationships. All three marker results for pepper showed general agreement with pepper types. Additionally, retrotransposon sequences isolated from one species can be used in related Solanaceae genera. These results suggest that different marker systems are suited for studying genetic diversity in different contexts depending on the group studied, where discordance between different marker systems can be very informative for understanding genetic relationships within the study group.     

Study on the evolution of the grande retrotransposon in the zea genus

The study of Grande retrotransposon (RTN) variation reported here comprises the intrinsic element variability and the changes that element insertion provokes in the Zea genome, including its abundance among species. Sequence analysis of a defined long-terminal repeat (LTR) region from Grande RTN revealed a high level of sequence divergence since no identical sequences were found among the 65 clones examined that belong to different Zea species or maize inbred lines. Average diversity values within accessions ranged from 0.17 to 0.37 substitutions per nucleotide. Phylogenetic analysis revealed a lack of concordance between the phylogenetic tree obtained from LTR sequences and the conventional taxonomic tree, suggesting that different subfamilies of Grande elements existed before Zea speciation. When sequence-specific amplification polymorphism (SSAP) marker data, which combines genomic and RTN variation, are used, the derived trees reflect the established species phylogeny and allow, as well, differentiating among some maize lines. Finally, the evaluation of Grande abundance, using different element probes in all the Zea species but Z. luxurians, revealed around 5,700 copies per haploid genome in all the diploid species examined, indicating a similar expansion process of Grande in all the Zea genomes. This number of copies represents in all cases around a 3% of the genome, which implies that Grande RTN is an important component of the maize genome. The copy number ratio LTR/gag is around 2 in all the species analyzed, indicating that overwhelming majority of elements have internal region. Thus, mechanisms such as homologous recombination between LTRs of a single RTN, which would remove the internal region and one LTR, leaving behind a single recombinant LTR, seems not to be active in maize for Grande RTN.     

LTR retrotransposons from the <Emphasis Type="Italic">Citrus x clementina</Emphasis> genome: characterization and application

Long terminal repeat retrotransposons (LTR-RTs) are a large portion of most plant genomes, and can be used as a powerful molecular marker system. The first citrus reference genome (Citrus x clementina) has been publicly available since 2011; however, previous studies in citrus have not utilized the whole genome for LTR-RT marker development. In this study, 3959 full-length LTR-RTs were identified in the C. x clementina genome using structure-based (LTR_FINDER) and homology-based (RepeatMasker) methods. LTR-RTs were first classified by protein domain into Gypsy and Copia superfamilies, and then clustered into 1074 families based on LTR sequence similarity. Three hundred fifty Copia families were grouped into four lineages: Retrofit, Tork, Sire, and Oryco. One hundred seventy-eight Gypsy families were sorted into six lineages: Athila, Tat, Renia, CRM, Galadriel, and Del. Most LTR-RTs (3218 or 81.3%) were anchored to the nine Clementine mandarin linkage groups, accounting for 9.74% of chromosomes currently assembled. Accessions of 25 Rutaceae species were genotyped using 17 inter-retrotransposon amplified polymorphism (IRAP) markers developed from conserved LTR regions. Sequence-specific amplified polymorphism (SSAP) makers were used to distinguish ‘Valencia’ and ‘Pineapple’ sweet oranges (C. x sinensis), and 24 sweet orange clones. LTR-RT markers developed from the Clementine genome can be transferred within the Rutaceae family demonstrating that they are an excellent tool for citrus and Rutaceae genetic analysis.     

Retrotransposon-based insertion polymorphism markers in mango

Retrotransposons are major components of eukaryotic genomes and are present in high copy numbers. We developed retrotransposon-based insertion polymorphism (RBIP) markers based on long terminal repeat (LTR) sequences and flanking genome regions by using shotgun genome sequence data of mango (Mangifera indica L.). Three novel LTR sequences were identified based on two LTR retrotransposon structural features; a 5′ LTR located upstream of the primer binding site and a 3′ LTR showing high sequence similarity to the 5′ LTR. Starting with 377 unique sequences containing both 3′ LTR and downstream genome region sequences, we developed 82 RBIP markers that were applied to DNA fingerprinting of 16 mango accession. Five RBIP markers were enough to distinguish all 16 accessions. Our result showed that LTR identification from shotgun genome sequences was effective for development of retrotransposon-based DNA markers without whole-genome sequence information. We discuss application of the developed RBIP markers for identification of genetic diversity and construction of a genetic linkage map.     

Development of Ty1-copia retrotransposon-based SSAP molecular markers for the study of genetic diversity in peach

Sequence-specific amplified polymorphism (SSAP) technology is a novel, anchored PCR approach derived from AFLP, which amplifies the region between a transposon insertion and an adjacent restriction site and have higher levels of polymorphism. In the current study, we developed 16 SSAP markers based on the long terminal repeat (LTR) sequences of Ty1-copia retrotransposons in the peach and used them for DNA profiling of 52 individual peaches: 44 peach cultivars and 8 ornamental peaches. These primer combinations produced a total of 1,553 fragments and 1,517 polymorphic bands with a polymorphism percentage of 97.7%. Furthermore, the Shannon's information index of each primer combination ranged from 0.1593 to 0.4456. Neighbor-joining analyses revealed two main genetic clusters, corresponding to the fruit flesh types: (A-1) MF (melting flesh) with clingstone and ornamental peaches; (A-2) MF with freestone and NMF (non-melting flesh) with clingstone. Finally, cluster analyses revealed that all ornamental peaches are closely related to the MF with clingstone peach cultivars. The application of these primer combinations identified using SSAP will facilitate future cultivar identification and germplasm management in peaches.     

利用iPBS技术克隆牡丹反转录转座子LTR序列

利用iPBS方法从西北牡丹(Paeonia suffruticosa)品种红绣球和中原牡丹品种洛阳红中扩增出相应片段,经回收、克隆及测序,获得了12条来自牡丹LTR类反转录转座子的LTR序列,并用相关生物信息学软件对序列进行分析。结果表明,这些核苷酸序列表现出较高的异质性,主要表现为缺失突变,序列长度变化范围为313–894 bp,同源性从31.1%–65.8%不等。将其氨基酸序列与已登录的不同植物LTR类反转录转座子LTR氨基酸序列进行聚类分析,结果显示与某些植物相应序列具有较高的同源性,表明可能存在LTR类反转录转座子的横向传递关系。根据克隆出的LTR序列设计SSAP引物,对牡丹29个品种进行了SSAP分子标记分析,结果显示具丰富的多态性。实验验证了用iPBS技术分离牡丹LTR序列的适用性,并为牡丹种质资源评价提供了新的技术手段。     

Comparison of four molecular markers for genetic analysis in Diospyros L. (Ebenaceae)

Four molecular markers, including inter-retrotransposon amplified polymorphism (IRAP), retrotransposon-microsatellite amplified polymorphism (REMAP), sequence-specific amplified polymorphism (SSAP), and amplified fragment length polymorphism (AFLP), were compared in terms of their informativeness and efficiency for analysis of genetic relationships among 28 genotypes in the genus Diospyros. The results were as follows: (1) the highest level of detected polymorphism were observed for IRAP; (2) AFLP was the most efficient marker system due to the simultaneous detection of abundant polymorphism markers per single reaction; (3) the marker index (MI) value was lower for SSAP than for AFLP, but SSAP had a higher level of detected polymorphism than AFLP; (4) the correlation coefficients of similarity were statistically significant for all four marker systems; (5) the four molecular markers yielded similar phylogenetic trees. To our knowledge, this was the first detailed report of a comparison of performance among three retrotransposon-based molecular markers (IRAP, REMAP, SSAP) and the AFLP technique (DNA-based molecular marker) on a set of samples of Diospyros. The results provide guidance for future efficient use of these molecular methods in the genetic analysis of Diospyros.     

Characterization of fusarium wilt-resistant and fusarium wilt-susceptible somaclones of banana cultivar rastali (Musa AAB) by random amplified polymorphic DNA and retrotransposon markers

Two DNA fingerprinting techniques, random amplified polymorphic DNA (RAPD) and inter-retrotransposon amplified polymorphism (IRAP), were used to characterize somaclonal variants of banana. IRAP primers were designed on the basis of repetitive and genome-wide dispersed long terminal repeat (LTR) retrotransposon families for assessing the somaclonal variation in 2Musa clones resistant and susceptible toFusarium oxysporum f. sp.cubense race 4. RAPD markers successfully detected genetic variation within and between individuals of the clones. IRAP makers amplified either by a single primer or a combination of primers based on LTR orientation successfully amplified different retrotransposons dispersed in theMusa genome and detected new events of insertions. RAPD markers proved more polymorphic than IRAP markers. Somaclonal variation seems to be the result of numerous indels occurring genome-wide accompanied by the activation of retroelements, as a result of stress caused by micropropagation. It is concluded that characterization of the somaclonal variants requires more than one DNA marker system to detect variation in diverse components of the genome.     

逆转座子Tos17的激活与水稻白叶枯病成株抗性的关系

为了研究水稻白叶枯病成株抗性是否与逆转子激活有关,运用SSAP (sequence-specific amplification polymorphism) 对成株抗性品种苗期和成株期接种白叶枯病原菌、清水接种及健康植株的基因组进行了逆转座子扫描。在筛选的约2000个逆转座子基因片段中,9个受苗期生长发育诱导激活,两个受成株期生长发育诱导激活,苗期和成株期各有3个受病原菌诱导激活。苗期生长发育诱导激活产生的逆转座子数目高于成株期,而病原菌诱导产生的逆转座子数目与成株期相当,表明水稻白叶枯病成株抗性可能与生长发育诱导的逆转座子激活相关。     

Pea Ty1-copia group retrotransposons: transpositional activity and use as markers to study genetic diversity in Pisum

The variation in transposition history of different Ty1-copia group LTR retrotransposons in the species lineages of the Pisum genus has been investigated. A heterogeneous population of Ty1-copia elements was isolated by degenerate PCR and two of these (Tps12 and Tps19) were selected on the basis of their copy number and sequence conservation between closely related species for further in-depth study of their transpositional history in Pisum species. The insertional polymorphism of these elements and the previously characterised PDR1 element was studied by sequence-specific amplification polymorphism (SSAP). Each of these elements reveals a unique transpositional history within 55 diverse Pisum accessions. Phylogenetic trees based on the SSAP data show that SSAP markers for individual elements are able to resolve different species lineages within the Pisum genus. Finally, the SSAP data from all of these retrotransposon markers were combined to reveal a detailed picture of the intra and inter-species relationships within Pisum. Received: 23 January 2000 / Accepted: 24 March 2000     

植物活性长末端重复序列反转录转座子研究进展

长末端重复序列(Long terminal repeat,LTR)反转录转座子是真核生物基因组中普遍存在的一类可移动的DNA序列,它们以RNA为媒介,通过"复制粘贴"机制在基因组中不断自我复制。在高等植物中,许多活性的LTR反转录转座子已被详尽研究并应用于分子标记技术、基因标签、插入型突变及基因功能等分析。本文对植物活性LTR反转录转座子进行全面的调查,并对其结构、拷贝数和分布以及转座特性进行系统的归纳,分析了植物活性LTR反转录转座子的gag(种属特异抗原)和pol(聚合酶)序列特征,以及LTR序列中顺式调控元件的分布。研究发现自主有活性的LTR反转录转座子必须具备LTR区域以及编码Gag、Pr、Int、Rt和Rh蛋白的基因区。其中两端LTR区域具有高度同源性且富含顺式调控元件;Rt蛋白必备RVT结构域;Rh蛋白必备RNase_H1_RT结构域。这些结果为后续植物活性LTR反转录转座子的鉴定和功能分析奠定了重要基础。     

Genetic distribution of Bare–1-like retrotransposable elements in the barley genome revealed by sequence-specific amplification polymorphisms (S-SAP)

Retrotransposons are present in high copy number in many plant genomes. They show a considerable degree of sequence heterogeneity and insertional polymorphism, both within and between species. We describe here a polymerase chain reaction (PCR)-based method which exploits this polymorphism for the generation of molecular markers in barley. The method produces amplified fragments containing a Bare–1-like retrotransposon long terminal repeat (LTR) sequence at one end and a flanking host restriction site at the other. The level of polymorphism is higher than that revealed by amplified fragment length polymorphism (AFLP) in barley. Segregation data for 55 fragments, which were polymorphic in a doubled haploid barley population, were analysed alongside an existing framework of some 400 other markers. The markers showed a widespread distribution over the seven linkage groups, which is consistent with the distribution of the Bare–1 class of retrotransposons in the barley genome based on in situ hybridisation data. The potential applicability of this method to the mapping of other multicopy sequences in plants is discussed.