Cloning and sequencing of an envelope-like gene in Gossypium

Eukaryotic genomes harbor mobile genetic elements known as long terminal repeat (LTR) retrotransposons. LTR retrotransposons are closely related to the infectious and endogenous retroviruses. The viral envelope (env) gene of the retroviruses, which is responsible for their infective properties, distinguishes them from the LTR retrotransposons. Here, we report the cloning and sequencing of an envelope-like gene in Gossypium, implying that enveloped retroviruses are not limited to animals.     

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。     

Young but not relatively old retrotransposons are preferentially located in gene‐rich euchromatic regions in tomato (Solanum lycopersicum) plants

Long terminal repeat (LTR) retrotransposons are the major DNA components of flowering plants. They are generally enriched in pericentromeric heterochromatin regions of their host genomes, which could result from the preferential insertion of LTR retrotransposons and the low effectiveness of purifying selection in these regions. To estimate the relative importance of the actions of these two factors on their distribution pattern, the LTR retrotransposons in Solanum lycopersicum (tomato) plants were characterized at the genome level, and then the distribution of young elements was compared with that of relatively old elements. The current data show that old elements are mainly located in recombination‐suppressed heterochromatin regions, and that young elements are preferentially located in the gene‐rich euchromatic regions. Further analysis showed a negative correlation between the insertion time of LTR retrotransposons and the recombination rate. The data also showed there to be more solo LTRs in genic regions than in intergenic regions or in regions close to genes. These observations indicate that, unlike in many other plant genomes, the current LTR retrotransposons in tomatoes have a tendency to be preferentially located into euchromatic regions, probably caused by their severe suppression of activities in heterochromatic regions. These elements are apt to be maintained in heterochromatin regions, probably as a consequence of the pericentromeric effect in tomatoes. These results also indicate that local recombination rates and intensities of purifying selection in different genomic regions are largely responsible for structural variation and non‐random distribution of LTR retrotransposons in tomato plants.     

Novel clades of chromodomain-containing Gypsy LTR retrotransposons from mosses (Bryophyta)

Retrotransposons are the major component of plant genomes. Chromodomain-containing Gypsy long terminal repeat (LTR) retrotransposons are widely distributed in eukaryotes. Four distinct clades of chromodomain-containing Gypsy retroelements are known from the vascular plants: Reina, CRM, Galadriel and Tekay. At the same time, almost nothing is known about the repertoire of LTR retrotransposons in bryophyte genomes. We have combined a search of chromodomain-containing Gypsy retroelements in Physcomitrella genomic sequences and an experimental investigation of diverse moss species. The computer-based mining of the chromodomain-containing LTR retrotransposons allowed us to describe four different elements from Physcomitrella. Four novel clades were identified that are evolutionarily distinct from the chromodomain-containing Gypsy LTR retrotransposons of other plants.     

LTR retrotransposons and flowering plant genome size: emergence of the increase/decrease model

Long Terminal Repeat (LTR) retrotransposons are ubiquitous components of plant genomes. Because of their copy-and-paste mode of transposition, these elements tend to increase their copy number while they are active. In addition, it is now well established that the differences in genome size observed in the plant kingdom are accompanied by variations in LTR retrotransposon content, suggesting that LTR retrotransposons might be important players in the evolution of plant genome size, along with polyploidy. The recent availability of large genomic sequences for many crop species has made it possible to examine in detail how LTR retrotransposons actually drive genomic changes in plants. In the present paper, we provide a review of the recent publications that have contributed to the knowledge of plant LTR retrotransposons, as structural components of the genomes, as well as from an evolutionary genomic perspective. These studies have shown that plant genomes undergo genome size increases through bursts of retrotransposition, while there is a counteracting process that tends to eliminate the transposed copies from the genomes. This process involves recombination mechanisms that occur either between the LTRs of the elements, leading to the formation of solo-LTRs, or between direct repeats anywhere in the sequence of the element, leading to internal deletions. All these studies have led to the emergence of a new model for plant genome evolution that takes into account both genome size increases (through retrotransposition) and decreases (through solo-LTR and deletion formation). In the conclusion, we discuss this new model and present the future prospects in the study of plant genome evolution in relation to the activity of transposable elements.     

Characterization of genome-wide long terminal repeat retrotransposons provide insights into trait evolution of four grapevine species

Grapevine is one of the most economically important crops in the world. Although long terminal repeat (LTR) retrotransposons are thought to have played an important role in plants, its distribution in grapevine is not clear. Here, we identified genome-wide intact LTR retrotransposons in a total of six high-quality grapevine genomes from Vitis vinifera L., Vitis sylvestris C.C. Gmel., Vitis riparia Michx. and Vitis amurensis Rupr. with an average of 2938 per genome. Among them, the Copia superfamily (particularly for Ale) is a major component of the LTR retrotransposon in grapevine. Insertion time and copy number analysis revealed that the expansion of 70% LTR retrotransposons concentrating on approximately 2.5 Ma was able to drive genome size variation. Phylogenetic tree and syntenic analyses showed that most LTR retrotransposons in these genomes formed and evolved after species divergence. Furthermore, the function and expression of genes inserted by LTR retrotransposons in V. vinifera (Pinot noir) and V. riparia were explored. The length and expression of genes related to starch metabolism and quinone synthesis pathway in Pinot noir and environmental adaptation pathway in V. riparia were significantly affected by LTR retrotransposon insertion. The results improve the understanding of LTR retrotransposons in grapevine genomes and provide insights for its potential contribution to grapevine trait evolution.     

Long terminal repeat retrotransposons of Oryza sativa

Background  

Long terminal repeat (LTR) retrotransposons constitute a major fraction of the genomes of higher plants. For example, retrotransposons comprise more than 50% of the maize genome and more than 90% of the wheat genome. LTR retrotransposons are believed to have contributed significantly to the evolution of genome structure and function. The genome sequencing of selected experimental and agriculturally important species is providing an unprecedented opportunity to view the patterns of variation existing among the entire complement of retrotransposons in complete genomes.     

Development of retrotransposon-based molecular markers and their application in genetic mapping in chokecherry (<Emphasis Type="Italic">Prunus virginiana</Emphasis> L.)

Retrotransposons are the largest group of transposable elements (TEs) that are ubiquitous and well dispersed in plant genomes. Transposition/insertion of TEs on chromosomes often generates unique repeat junctions (RJs) between TEs and their flanking sequences. Long terminal repeats (LTR) are well conserved and abundant in plant genomes, making LTR retrotransposons valuable for development of TE junction-based markers. In this study, LTR retrotransposons and their RJs were detected from chokecherry genome sequences generated by Roche 454 sequencing. A total of 1246 LTR retrotransposons were identified, and 338 polymerase chain reaction primer pairs were designed. Of those, 336 were used to amplify DNA from chokecherry and other rosaceous species. An average of 283 of 336 (84.2 %) LTR primer pairs effectively amplified DNA from chokecherries. One hundred and seventeen chokecherry LTR primers also produced amplification in other Prunus (99) or rosaceous species (19). A total of 59 of 78 polymorphic LTR markers were qualified for linkage map construction according to the segregation distortion Chi-square (χ ²) test. Forty-eight LTR markers were successfully located on a previously constructed chokecherry map. The majority of the LTR markers were mapped on LG XI of the chokecherry map. Our results suggest that LTR marker development using random genome sequences is rapid and cost-efficient. Confirmed applicability of LTR markers in map construction and genetic mapping will facilitate genetic research in chokecherry and other rosaceous species.     

Genome-Wide Survey and Comparative Analysis of LTR Retrotransposons and Their Captured Genes in Rice and Sorghum

Long terminal repeat (LTR) retrotransposons are the major class I mobile elements in plants. They play crucial roles in gene expansion, diversification and evolution. However, their captured genes are yet to be genome-widely identified and characterized in most of plants although many genomes have been completely sequenced. In this study, we have identified 7,043 and 23,915 full-length LTR retrotransposons in the rice and sorghum genomes, respectively. High percentages of rice full-length LTR retrotransposons were distributed near centromeric region in each of the chromosomes. In contrast, sorghum full-length LTR retrotransposons were not enriched in centromere regions. This dissimilarity could be due to the discrepant retrotransposition during and after divergence from their common ancestor thus might be contributing to species divergence. A total of 672 and 1,343 genes have been captured by these elements in rice and sorghum, respectively. Gene Ontology (GO) and gene set enrichment analysis (GSEA) showed that no over-represented GO term was identified in LTR captured rice genes. For LTR captured sorghum genes, GO terms with functions in DNA/RNA metabolism and chromatin organization were over-represented. Only 36% of LTR captured rice genes were expressed and expression divergence was estimated as 11.9%. Higher percentage of LTR captured rice genes have evolved into pseudogenes under neutral selection. On the contrary, higher percentage of LTR captured sorghum genes were under purifying selection and 72.4% of them were expressed. Thus, higher percentage of LTR captured sorghum genes was functional. Small RNA analysis suggested that some of LTR captured genes in rice and sorghum might have been involved in negative regulation. On the other hand, positive selection has been observed in both rice and sorghum LTR captured genes and some of them were still expressed and functional. The data suggest that some of these LTR captured genes might have evolved into new gene functions.     

Ribonuclease H evolution in retrotransposable elements

Eukaryotic and prokaryotic genomes encode either Type I or Type II Ribonuclease H (RNH) which is important for processing RNA primers that prime DNA replication in almost all organisms. This review highlights the important role that Type I RNH plays in the life cycle of many retroelements, and its utility in tracing early events in retroelement evolution. Many retroelements utilize host genome-encoded RNH, but several lineages of retroelements, including some non-LTR retroposons and all LTR retrotransposons, encode their own RNH domains. Examination of these RNH domains suggests that all LTR retrotransposons acquired an enzymatically weak RNH domain that is missing an important catalytic residue found in all other RNH enzymes. We propose that this reduced activity is essential to ensure correct processing of the polypurine tract (PPT), which is an important step in the life cycle of these retrotransposons. Vertebrate retroviruses appear to have reacquired their RNH domains, which are catalytically more active, but their ancestral RNH domains (found in other LTR retrotransposons) have degenerated to give rise to the tether domains unique to vertebrate retroviruses. The tether domain may serve to control the more active RNH domain of vertebrate retroviruses. Phylogenetic analysis of the RNH domains is also useful to "date" the relative ages of LTR and non-LTR retroelements. It appears that all LTR retrotransposons are as old as, or younger than, the "youngest" lineages of non-LTR retroelements, suggesting that LTR retrotransposons arose late in eukaryotes.     

A highly conserved, small LTR retrotransposon that preferentially targets genes in grass genomes

LTR retrotransposons are often the most abundant components of plant genomes and can impact gene and genome evolution. Most reported LTR retrotransposons are large elements (>4 kb) and are most often found in heterochromatic (gene poor) regions. We report the smallest LTR retrotransposon found to date, only 292 bp. The element is found in rice, maize, sorghum and other grass genomes, which indicates that it was present in the ancestor of grass species, at least 50-80 MYA. Estimated insertion times, comparisons between sequenced rice lines, and mRNA data indicate that this element may still be active in some genomes. Unlike other LTR retrotransposons, the small LTR retrotransposons (SMARTs) are distributed throughout the genomes and are often located within or near genes with insertion patterns similar to MITEs (miniature inverted repeat transposable elements). Our data suggests that insertions of SMARTs into or near genes can, in a few instances, alter both gene structures and gene expression. Further evidence for a role in regulating gene expression, SMART-specific small RNAs (sRNAs) were identified that may be involved in gene regulation. Thus, SMARTs may have played an important role in genome evolution and genic innovation and may provide a valuable tool for gene tagging systems in grass.     

LINEs, SINEs and processed pseudogenes: parasitic strategies for genome modeling

Two major classes of retrotransposons have invaded eukaryotic genomes: the LTR retrotransposons closely resembling the proviral integrated form of infectious retroviruses, and the non-LTR retrotransposons including the widespread, autonomous LINE elements. Here, we review the modeling effects of the latter class of elements, which are the most active in humans, and whose enzymatic machinery is subverted to generate a large series of "secondary" retroelements. These include the processed pseudogenes, naturally present in all eukaryotic genomes possessing non-LTR retroelements, and the very successful SINE elements such as the human Alu sequences which have evolved refined parasitic strategies to efficiently bypass the original "protectionist" cis-preference of LINEs for their own retrotransposition.     

A deep-branching clade of retrovirus-like retrotransposons in bdelloid rotifers

Rotifers of class Bdelloidea, a group of aquatic invertebrates in which males and meiosis have never been documented, are also unusual in their lack of multicopy LINE-like and gypsy-like retrotransposons, groups inhabiting the genomes of nearly all other metazoans. Bdelloids do contain numerous DNA transposons, both intact and decayed, and domesticated Penelope-like retroelements Athena, concentrated at telomeric regions. Here we describe two LTR retrotransposons, each found at low copy number in a different bdelloid species, which define a clade different from previously known clades of LTR retrotransposons. Like bdelloid DNA transposons and Athena, these elements are found preferentially in telomeric regions. Unlike bdelloid DNA transposons, many of which are decayed, the newly described elements, named Vesta and Juno, inhabiting the genomes of Philodina roseola and Adineta vaga, respectively, appear to be intact and represent recent insertions, possibly from an exogenous source. We describe the retrovirus-like structure of the new elements, containing gag, pol, and env-like open reading frames, and discuss their possible origins, transmission, and behavior in bdelloid genomes.     

家蚕LTR逆转录转座子的鉴定、分类及系统发育分析

转座子是真核生物基因组的重要组成成分。为了研究家蚕Bombyx mori长末端重复序列 (long terminal repeat, LTR)逆转录转座子的分类及进化, 本研究采用de novo预测和同源性搜索相结合的方法, 在家蚕基因组中共鉴定出了38个LTR逆转录转座子家族, 序列长度占整个基因组的0.64%, 远小于先前预测的11.8%, 其中有6个家族为本研究的新发现。38个家族中, 26个家族有表达序列标签 (expression sequence tag, EST)证据, 表明这些家族具有潜在的活性。对有EST证据的6个家族和没有EST证据的5个家族用RT-PCR进行了组织表达谱实验, 结果表明这11个家族在一些组织中有表达, 这进一步证实了这些家族具有转录活性, 基于此我们推测家蚕中大部分的LTR逆转录转座子家族很可能具有潜在活性。对转座子的插入时间进行估计, 结果表明绝大部分元件都是最近1百万年内插入到家蚕基因组中的。我们还比较了黑腹果蝇Drosophila melanogaster、 冈比亚按蚊Anopheles gambiae和家蚕B. mori中Ty3/Gypsy超家族分支的差异, 结果表明不同枝在不同昆虫中有着不同的扩张。家蚕中LTR逆转录转座子的鉴定和系统分析有助于我们理解逆转录转座子在昆虫进化中的作用。     

Evidence of multiple horizontal transfers of the long terminal repeat retrotransposon RIRE1 within the genus Oryza

Horizontal gene transfer, defined as the transmission of genetic material between reproductively isolated species, has been considered for a long time to be a rare phenomenon. Most well-documented cases of horizontal gene transfer have been described in prokaryotes or in animals and they often involve transposable elements. The most abundant class of transposable elements in plant genomes are the long terminal repeat (LTR) retrotransposons. Because of their propensity to increase their copy number while active, LTR retrotransposons can have a significant impact on genomics changes during evolution. In a previous study, we showed that in the wild rice species Oryza australiensis , 60% of the genome is composed of only three families of LTR retrotransposons named RIRE1 , Wallabi and Kangourou . In the present study, using both in silico and experimental approaches, we show that one of these three families, RIRE1 , has been transferred horizontally between O. australiensis and seven other reproductively isolated Oryza species. This constitutes a new case of horizontal transfer in plants.     

LTR_STRUC: a novel search and identification program for LTR retrotransposons

MOTIVATION: Long terminal repeat (LTR) retrotransposons constitute a substantial fraction of most eukaryotic genomes and are believed to have a significant impact on genome structure and function. Conventional methods used to search for LTR retrotransposons in genome databases are labor intensive. We present an efficient, reliable and automated method to identify and analyze members of this important class of transposable elements. RESULTS: We have developed a new data-mining program, LTR_STRUC (LTR retrotransposon structure program) which identifies and automatically analyzes LTR retrotransposons in genome databases by searching for structural features characteristic of such elements. LTR_STRUC has significant advantages over conventional search methods in the case of LTR retrotransposon families having low sequence homology to known queries or families with atypical structure (e.g. non-autonomous elements lacking canonical retroviral ORFs) and is thus a discovery tool that complements established methods. LTR_STRUC finds LTR retrotransposons using an algorithm that encompasses a number of tasks that would otherwise have to be initiated individually by the user. For each LTR retrotransposon found, LTR_STRUC automatically generates an analysis of a variety of structural features of biological interest. AVAILABILITY: The LTR_STRUC program is currently available as a console application free of charge to academic users from the authors.     

A computational study of the dynamics of LTR retrotransposons in the Populus trichocarpa genome

Retrotransposons are an ubiquitous component of plant genomes, especially abundant in species with large genomes. Populus trichocarpa has a relatively small genome, which was entirely sequenced; however, studies focused on poplar retrotransposons dynamics are rare. With the aim to study the retrotransposon component of the poplar genome, we have scanned the complete genome sequence searching full-length long-terminal repeat (LTR) retrotransposons, i.e., characterised by two long terminal repeats at the 5′ and 3′ ends. A computational approach based on detection of conserved structural features, on building multiple alignments, and on similarity searches was used to identify 1,479 putative full-length LTR retrotransposons. Ty1-copia elements were more numerous than Ty3-gypsy. However, many LTR retroelements were not assigned to any superfamily because lacking of diagnostic features and non-autonomous. LTR retrotransposon remnants were by far more numerous than full-length elements, indicating that during the evolution of poplar, large amplification of these elements was followed by DNA loss. Within superfamilies, Ty3-gypsy families are made of more members than Ty1-copia ones. Retrotransposition occurred with increasing frequency following the separation of Populus sections, with different waves of retrotransposition activity between Ty3-gypsy and Ty1-copia elements. Recently inserted elements appear more frequently expressed than older ones. Finally, different levels of activity of retrotransposons were observed according to their position and their density in the linkage groups. On the whole, the results support the view of retrotransposons as a community of different organisms in the genome, whose activity (both retrotransposition and DNA loss) has heavily impacted and probably continues to impact poplar genome structure and size.     

DIRS1 -like retrotransposons are widely distributed among Decapoda and are particularly present in hydrothermal vent organisms

Background  

Transposable elements are major constituents of eukaryote genomes and have a great impact on genome structure and stability. Considering their mutational abilities, TEs can contribute to the genetic diversity and evolution of organisms. Knowledge of their distribution among several genomes is an essential condition to study their dynamics and to better understand their role in species evolution. DIRS1 -like retrotransposons are a particular group of retrotransposons according to their mode of transposition that implies a tyrosine recombinase. To date, they have been described in a restricted number of species in comparison with the LTR retrotransposons. In this paper, we determine the distribution of DIRS1 -like elements among 25 decapod species, 10 of them living in hydrothermal vents that correspond to particularly unstable environments.