Recent Retrotransposon Insertions Are Methylated and Phylogenetically Clustered in Japonica Rice (Oryza sativa spp. japonica)

In plants, the genome of the host responds to the amplification of transposable elements (TEs) with DNA methylation. However, neither the factors involved in TE methylation nor the dynamics of the host-TE interaction are well resolved. Here, we identify 5,522 long terminal repeat retrotransposons (LTR-RT) in the genome of Oryza sativa ssp. japonica and then assess methylation for individual elements. Our analyses uncover three strong trends: long LTR-RTs are more highly methylated, the insertion times of LTR-RTs are negatively correlated with methylation, and young LTR-RTs tend to be closer to genes than older insertions. Additionally, a phylogenetic examination of the gypsy-like LTR-RT superfamily revealed that methylation is phylogenetically correlated. Given these observations, we present a model suggesting that the phylogenetic correlation among related LTR-RTs is a primary mechanism driving methylation. In this model, bursts of transposition produce new elements with high sequence similarity. The host machinery identifies proliferating elements as well as closely related LTR-RTs through cross-homology. In addition, our data are consistent with previous hypotheses that methylated LTR-RT elements are removed preferentially from regions near genes, explaining some of the observed age distribution.     

Transposable elements in plants: Recent advancements,tools and prospects

Transposable elements (TEs) have long been considered junk DNA; however, the availability of genome sequences and the growth of omics databases have accelerated the study of TEs, and they are now considered evolutionary signatures. TEs, essential genetic elements in plant genomes, can move around the genome by either “cut-paste” (DNA transposons) or “copypaste” mechanisms (RNA transposons). TEs often affect host genome size and interact with host genes, resulting in altered gene expression and regulatory networks. Several genes have been identified to be influenced/modified by the action of TEs. TEs have diverse structures and functions. Plants are capable of using TEs as promoters and enhancers to drive epigenetic mechanisms in a tissue-specific manner. However, our knowledge about TEs remains poor despite extensive research in plants. Plant physiological functions associated with TEs have been challenging to analyse due to a lack of focused research. Another limitation is the lack of sufficient genetic information. The different functions displayed by plant genomes are genetically regulated, which opens up opportunities in areas such as genomic evolution and epigenetic modification. Indeed, understanding the contribution of TEs in the plant genome is indispensable to assess the diversity of evolutionary adaptability in plant taxa. In this study, we review the applications of TEs and discuss the value of genetic information in the plant genome. Genomic information about TEs has a significant value in high throughput research, including forward and reverse genetics. We discuss current strategies in using TEs for the genetic dissection of plant genomes. This review covers opportunities to use different TEs databases to increase the productivity of economically important plants for sustainable development

     

Transposable element recruitments in the mammalian placenta: impacts and mechanisms

Transposable elements (TEs) are mobile DNA elements found at high frequency in mammalian genomes. Although these elements are generally perceived as genomic parasites, they have the potential to influence host genome function in many beneficial ways. This article discusses the role TEs have played in the evolution of the placenta and pregnancy in viviparous mammals. Using examples from our own research and the literature, we argue that frequent recruitment of TEs, in particular of retroelements, has facilitated the extreme diversification of tissues at the maternal-fetal interface. We also discuss the mechanisms by which TEs have been recruited for functions during pregnancy. We argue that retroelements are pre-adapted to becoming cis-regulatory elements for host genomes because they need to utilize host regulatory signals for their own life cycle. However, although TEs contain some of the signals necessary for host functions upon insertion, they often require modification before acquiring a biological role in a host tissue. We discuss the process by which one TE was transformed into a promoter for prolactin expression in the endometrium, describing a model for TE domestication called 'epistatic capture'.     

小RNAs在沉默转座因子中的作用

在很多生物基因组中都存在DNA成分的转座序列,它们能够转座到基因组的很多位点,对基因组造成很大的危害,如破坏编码基因、改变基因表达的调节网络、使染色体断裂或造成大范围基因重排等。真核生物已经进化出了多种机制来控制这些寄生核酸序列造成的损伤,以维持基因组完整性。虽然这些机制在不同生物中有些差异,但其中一种主要的机制是通过小RNAs介导的,这些小RNAs包括小干扰RNAs、piwi相互作用的小RNAs、微小RNAs、扫描RNAs和21U-RNAs等。这些小RNAs可以通过DNA水平剪切转座序列,或在转录和(或)转录后水平沉默转座成分。该文就这些小RNAs沉默转座成分的机制和功能做一论述。     

Transposable element discovery and characterization of LTR-retrotransposon evolutionary lineages in the tropical fruit species Passiflora edulis

Molecular Biology Reports - A significant proportion of plant genomes is consists of transposable elements (TEs), especially LTR retrotransposons (LTR-RTs) which are known to drive genome...     

The widespread nature of Pack-TYPE transposons reveals their importance for plant genome evolution

Pack-TYPE transposable elements (TEs) are a group of non-autonomous DNA transposons found in plants. These elements can efficiently capture and shuffle coding DNA across the host genome, accelerating the evolution of genes. Despite their relevance for plant genome plasticity, the detection and study of Pack-TYPE TEs are challenging due to the high similarity these elements have with genes. Here, we produced an automated annotation pipeline designed to study Pack-TYPE elements and used it to successfully annotate and analyse more than 10,000 new Pack-TYPE TEs in the rice and maize genomes. Our analysis indicates that Pack-TYPE TEs are an abundant and heterogeneous group of elements. We found that these elements are associated with all main superfamilies of Class II DNA transposons in plants and likely share a similar mechanism to capture new chromosomal DNA sequences. Furthermore, we report examples of the direct contribution of these TEs to coding genes, suggesting a generalised and extensive role of Pack-TYPE TEs in plant genome evolution.     

How selfish retrotransposons are silenced in Drosophila germline and somatic cells

Transposable elements (TEs) are DNA elements found in the genomes of various organisms. TEs have been highly conserved during evolution, suggesting that they confer advantageous effects to their hosts. However, due to their ability to transpose into virtually any locus, TEs have the ability to generate deleterious mutations in the host genome. In response, a variety of different mechanisms have evolved to mitigate their activities. A main defense mechanism is RNA silencing, which is a gene silencing mechanism triggered by small RNAs. In this review, we address RNA silencing mechanisms that silence retrotransposons, a subset of TEs, and discuss how germline and somatic cells are equipped with different retrotransposon silencing mechanisms.     

What transposable elements tell us about genome organization and evolution: the case of Drosophila

Transposable elements (TEs) have been identified in every organism in which they have been looked for. The sequencing of large genomes, such as the human genome and those of Drosophila, Arabidopsis, Caenorhabditis, has also shown that they are a major constituent of these genomes, accounting for 15% of the genome of Drosophila, 45% of the human genome, and more than 70% in some plants and amphibians. Compared with the 1% of genomic DNA dedicated to protein-coding sequences in the human genome, this has prompted various researchers to suggest that the TEs and the other repetitive sequences that constitute the so-called "noncoding DNA", are where the most stimulating discoveries will be made in the future (Bromham, 2002). We are therefore getting further and further from the original idea that this DNA was simply "junk DNA", that owed its presence in the genome entirely to its capacity for selfish transposition. Our understanding of the structures of TEs, their distribution along the genomes, their sequence and insertion polymorphisms within genomes, and within and between populations and species, their impact on genes and on the regulatory mechanisms of genetic expression, their effects on exon shuffling and other phenomena that reshape the genome, and their impact on genome size has increased dramatically in recent years. This leads to a more general picture of the impact of TEs on genomes, though many copies are still mainly selfish or junk DNA. In this review we focus mainly on discoveries made in Drosophila, but we also use information about other genomes when this helps to elucidate the general processes involved in the organization, plasticity, and evolution of genomes.     

Give-and-take: interactions between DNA transposons and their host plant genomes

Recent genome sequencing efforts have revealed how extensively transposable elements (TEs) have contributed to the shaping of present day plant genomes. DNA transposons associate preferentially with the euchromatic or genic component of plant genomes and have had the opportunity to interact intimately with the genes of the plant host. These interactions have resulted in TEs acquiring host sequences, forming chimeric genes through exon shuffling, replacing regulatory sequences, mobilizing genes around the genome, and contributing genes to the host. The close interaction of transposons with genes has also led to the evolution of intricate cellular mechanisms for silencing transposon activity. Transposons have thus become important subjects of study in understanding epigenetic regulation and, in cases where transposons have amplified to high numbers, how to escape that regulation.     

The evolution of retrotransposon regulatory regions and its consequences on the Drosophila melanogaster and Homo sapiens host genomes

It has now been established that transposable elements (TEs) make up a variable, but significant proportion of the genomes of all organisms, from Bacteria to Vertebrates. However, in addition to their quantitative importance, there is increasing evidence that TEs also play a functional role within the genome. In particular, TE regulatory regions can be viewed as a large pool of potential promoter sequences for host genes. Studying the evolution of regulatory region of TEs in different genomic contexts is therefore a fundamental aspect of understanding how a genome works. In this paper, we first briefly describe what is currently known about the regulation of TE copy number and activity in genomes, and then focus on TE regulatory regions and their evolution. We restrict ourselves to retrotransposons, which are the most abundant class of eukaryotic TEs, and analyze their evolution and the subsequent consequences for host genomes. Particular attention is paid to much-studied representatives of the Vertebrates and Invertebrates, Homo sapiens and Drosophila melanogaster, respectively, for which high quality sequenced genomes are available.     

A "mille-feuille" of silencing: epigenetic control of transposable elements

Despite their abundance in the genome, transposable elements (TEs) and their derivatives are major targets of epigenetic silencing mechanisms, which restrain TE mobility at different stages of the life cycle. DNA methylation, post-translational modification of histone tails and small RNA-based pathways contribute to maintain TE silencing; however, some of these epigenetic marks are tightly interwoven and this complicates the delineation of the exact contribution of each in TE silencing. Recent studies have confirmed that host genomes have evolved versatility in the use of these mechanisms to individualize silencing of particular TEs. These studies also revealed that silencing of TEs is much more dynamic than had been previously thought and can be reversed on the genomic scale in particular cell types or under special environmental conditions. This article is part of a Special Issue entitled "Epigenetic control of cellular and developmental processes in plants".     

Genome evolution in filamentous plant pathogens: why bigger can be better

Many species of fungi and oomycetes are plant pathogens of great economic importance. Over the past 7 years, the genomes of more than 30 of these filamentous plant pathogens have been sequenced, revealing remarkable diversity in genome size and architecture. Whereas the genomes of many parasites and bacterial symbionts have been reduced over time, the genomes of several lineages of filamentous plant pathogens have been shaped by repeat-driven expansions. In these lineages, the genes encoding proteins involved in host interactions are frequently polymorphic and reside within repeat-rich regions of the genome. Here, we review the properties of these adaptable genome regions and the mechanisms underlying their plasticity, and we illustrate cases in which genome plasticity has contributed to the emergence of new virulence traits. We also discuss how genome expansions may have had an impact on the co-evolutionary conflict between these filamentous plant pathogens and their hosts.     

New regulatory regions of Drosophila 412 retrotransposable element generated by recombination

There are no doubts that transposable elements (TEs) have greatly influenced genomes evolution. They have, however, evolved in different ways throughout mammals, plants, and invertebrates. In mammals they have been shown to be widely present but with low transposition activity; in plants they are responsible for large increases in genome size. In Drosophila, despite their low amount, transposition seems to be higher. Therefore, to understand how these elements have evolved in different genomes and how host genomes have proposed to go around them, are major questions on genome evolution. We analyzed sequences of the retrotransposable elements 412 in natural populations of the Drosophila simulans and D. melanogaster species that greatly differ in their amount of TEs. We identified new subfamilies of this element that were the result of mutation or insertion-deletion process, but also of interfamily recombinations. These new elements were well conserved in the D. simulans natural populations. The new regulatory regions produced by recombination could give rise to new elements able to overcome host control of transposition and, thus, become potential genome invaders.     

果蝇转座因子对基因组进化的影响

真核生物基因组织有很多可移动ＤＮＡ片段为称转座因子,果蝇是大量系统研究的最好实验材料之一,其基因组的１０％－１２％是由转座因子组成,在宿主中,ＴＥs也许改变基因表达模型,也许改变ＯＲＦs编码序列,也许对细胞功能产生影响,这此因子遗传的可动性也可能使它们适于建造载体产生转基因生物。因此,对ＴＥs进化的动态研究以及对宿主基因组进化影响的探索将有助于TEs作为载体的细胞工程研究。     

Transposable elements and host genome evolution

Several recent reports have challenged the idea that transposable elements (TEs) are mainly 'selfish' or 'junk' DNA with little importance for host evolution. It has been proposed that TEs have the potential to provide host genomes with the ability to enhance their own evolution. They might also be a major source of genetic diversity, allowing response to environmental changes. Because the relationships between TEs and host genomes are highly variable, and because the selfish, junk and beneficial DNA hypotheses are by no means mutually exclusive, a single label for these relationships appears to be inappropriate and potentially misleading.     

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.     

The evolution of retrotransposon regulatory regions and its consequences on the Drosophila melanogaster and Homo sapiens host genomes

It has now been established that transposable elements (TEs) make up a variable, but significant proportion of the genomes of all organisms, from Bacteria to Vertebrates. However, in addition to their quantitative importance, there is increasing evidence that TEs also play a functional role within the genome. In particular, TE regulatory regions can be viewed as a large pool of potential promoter sequences for host genes. Studying the evolution of regulatory region of TEs in different genomic contexts is therefore a fundamental aspect of understanding how a genome works. In this paper, we first briefly describe what is currently known about the regulation of TE copy number and activity in genomes, and then focus on TE regulatory regions and their evolution. We restrict ourselves to retrotransposons, which are the most abundant class of eukaryotic TEs, and analyze their evolution and the subsequent consequences for host genomes. Particular attention is paid to much-studied representatives of the Vertebrates and Invertebrates, Homo sapiens and Drosophila melanogaster, respectively, for which high quality sequenced genomes are available.     

综述: 高等植物转座元件功能研究进展

转座元件是指在基因组中能够移动、复制并重新整合到基因组新位点的DNA片段．转座元件一度被视为基因组内的“垃圾”或“自私DNA”,长期以来,转座元件的研究主要集中于阐释转座元件在宿主中的复制或表观沉默机制,而转座元件的调控功能并未得到全面探讨．已有研究表明,转座元件的比例与物种基因组大小存在正相关性,从而为C值悖论的解释提供了依据．近年来,越来越多的证据表明转座元件可以作为宿主基因组的“控制元件”发挥重要的调控作用．在作物中研究发现,转座元件既可以通过顺式或反式作用方式调控基因表达,也可以诱导表观等位基因的产生,从而促使固着生长的植物更好地适应外界环境的变化．本文拟就高等植物转座元件的作用及其对未来作物育种的意义进行总结．