Evidence that a family of miniature inverted-repeat transposable elements (MITEs) from the Arabidopsis thaliana genome has arisen from a pogo-like DNA transposon

Sequence similarities exist between terminal inverted repeats (TIRs) of some miniature inverted-repeat transposable element (MITE) families isolated from a wide range of organisms, including plants, insects, and humans, and TIRs of DNA transposons from the pogo family. We present here evidence that one of these MITE families, previously described for Arabidopsis thaliana, is derived from a larger element encoding a putative transposase. We have named this novel class II transposon Lemi1. We show that its putative product is related to transposases of the Tc1/mariner superfamily, being closer to the pogo family. A similar truncated element was found in a tomato DNA sequence, indicating an ancient origin and/or horizontal transfer for this family of elements. These results are reminiscent of those recently reported for the human genome, where other members of the pogo family, named Tiggers, are believed to be responsible for the generation of abundant MITE-like elements in an early primate ancestor. These results further suggest that some MITE families, which are highly reiterated in plant, insect, and human genomes, could have arisen from a similar mechanism, implicating pogo-like elements.     

Identification and characterisation of five novel miniature inverted-repeat transposable elements (MITEs) in amphioxus (Branchiostoma floridae)

As the sister group to vertebrates, amphioxus is consistently used as a model of genome evolution for understanding the invertebrate/vertebrate transition. The amphioxus genome has not undergone massive duplications like those in the vertebrates or disruptive rearrangements like in the genome of Ciona, a urochordate, making it an ideal evolutionary model. Transposable elements have been linked to many genomic evolutionary changes including increased genome size, modified gene expression, massive gene rearrangements, and possibly intron evolution. Despite their importance in genome evolution, few previous examples of transposable elements have been identified in amphioxus. We report five novel Miniature Inverted-repeat Transposable Elements (MITEs) identified by an analysis of amphioxus DNA sequence, which we have named LanceleTn-1, LanceleTn-2, LanceleTn-3a, LanceleTn-3b and LanceleTn-4. Several of the LanceleTn elements were identified in the amphioxus ParaHox cluster, and we suggest these have had important implications for the evolution of this highly conserved gene cluster. The estimated high copy numbers of these elements implies that MITEs are probably the most abundant type of mobile element in amphioxus, and are thus likely to have been of fundamental importance in shaping the evolution of the amphioxus genome.     

Population dynamics of miniature inverted-repeat transposable elements (MITEs) in Medicago truncatula

Miniature inverted-repeat transposable elements (MITEs) are small and high copy number transposons, related to and mobilized by some class II autonomous elements. New MITE families can be identified by computer-based mining of sequenced genomes. We describe four MITE families related to MtPH transposons mined de novo in the genome of Medicago truncatula, together with one previously described family MITRAV. Different levels of their intra-family sequence diversity and insertion polymorphism indicate that they were active at different evolutionary periods. MetMIT1 and MITRAV families were uniform in sequence and produced highly polymorphic insertion sites in 26 ecotypes representing a M. truncatula core collection. A subset of insertions was present only in the reference genome of A17 ‘Jemalong’, suggesting that the two families might have been active in the course of domestication. In contrast, all investigated insertions of the MetMIT2 family were fixed, showing that it was not active after M. truncatula speciation. MetMIT1 elements were divided into three clusters, i.e. (I) relatively heterogenous copies fixed in the genome of M. truncatula, (II) uniform but also mostly fixed, and (III) uniform and polymorphic among the investigated accessions. It might reflect the evolutionary history of the MetMIT1 family, showing multiple bursts of activity. A number of MetMIT1 and MITRAV insertions were present within 1 kb upstream or downstream the ORF. A high proportion of insertions proximal to coding regions was unique to A17 ‘Jemalong’.     

Genome-wide analysis of the Emigrant family of MITEs of Arabidopsis thaliana

Miniature inverted-repeat transposable elements (MITEs) are structurally similar to defective class II elements, but their high copy number and the size and sequence conservation of most MITE families suggest that they can be amplified by a replicative mechanism. Here we present a genome-wide analysis of the Emigrant family of MITEs from Arabidopsis thaliana. In order to be able to detect divergent ancient copies, and low copy number subfamilies with a different internal sequence we have developed a computer program to look for Emigrant elements based solely on the terminal inverted-repeat sequence. We have detected 151 Emigrant elements of different subfamilies. Our results show that different bursts of amplification, probably of few active, or master, elements, have occurred at different times during Arabidopsis evolution. The analysis of the insertion sites of the Emigrant elements shows that recently inserted Emigrant elements tend to be located far from open reading frames, whereas more ancient Emigrant subfamilies are preferentially found associated to genes.     

Characterization of active miniature inverted-repeat transposable elements in the peanut genome

Miniature inverted-repeat transposable elements (MITEs), some of which are known as active non-autonomous DNA transposons, are found in the genomes of plants and animals. In peanut (Arachis hypogaea), AhMITE1 has been identified in a gene for fatty-acid desaturase, and possessed excision activity. However, the AhMITE1 distribution and frequency of excision have not been determined for the peanut genome. In order to characterize AhMITE1s, their genomic diversity and transposition ability was investigated. Southern blot analysis indicated high AhMITE1 copy number in the genomes of A. hypogaea, A. magna and A. monticola, but not in A. duranensis. A total of 504 AhMITE1s were identified from the MITE-enriched genomic libraries of A. hypogaea. The representative AhMITE1s exhibited a mean length of 205.5 bp and a GC content of 30.1%, with AT-rich, 9 bp target site duplications and 25 bp terminal inverted repeats. PCR analyses were performed using primer pairs designed against both flanking sequences of each AhMITE1. These analyses detected polymorphisms at 169 out of 411 insertional loci in the four peanut lines. In subsequent analyses of 60 gamma-irradiated mutant lines, four AhMITE1 excisions showed footprint mutations at the 109 loci tested. This study characterizes AhMITE1s in peanut and discusses their use as DNA markers and mutagens for the genetics, genomics and breeding of peanut and its relatives.     

A family of human microRNA genes from miniature inverted-repeat transposable elements

While hundreds of novel microRNA (miRNA) genes have been discovered in the last few years alone, the origin and evolution of these non-coding regulatory sequences remain largely obscure. In this report, we demonstrate that members of a recently discovered family of human miRNA genes, hsa-mir-548, are derived from Made1 transposable elements. Made1 elements are short miniature inverted-repeat transposable elements (MITEs), which consist of two 37 base pair (bp) terminal inverted repeats that flank 6 bp of internal sequence. Thus, Made1 elements are nearly perfect palindromes, and when expressed as RNA they form highly stable hairpin loops. Apparently, these Made1-related structures are recognized by the RNA interference enzymatic machinery and processed to form 22 bp mature miRNA sequences. Consistent with their origin from MITEs, hsa-mir-548 genes are primate-specific and have many potential paralogs in the human genome. There are more than 3,500 putative hsa-mir-548 target genes; analysis of their expression profiles and functional affinities suggests cancer-related regulatory roles for hsa-mir-548. Taken together, the characteristics of Made1 elements, and MITEs in general, point to a specific mechanism for the generation of numerous small regulatory RNAs and target sites throughout the genome. The evolutionary lineage-specific nature of MITEs could also provide for the generation of novel regulatory phenotypes related to species diversification. Finally, we propose that MITEs may represent an evolutionary link between siRNAs and miRNAs.     

A systematic search and classification of T2 family miniature inverted-repeat transposable elements (MITEs) in Xenopus tropicalis suggests the existence of recently active MITE subfamilies

To reveal the genome-wide aspects of Xenopus T2 family miniature inverted-repeat transposable elements (MITEs), we performed a systematic search and classification of MITEs by a newly developed procedure. A terminal sequence motif (T2-motif: TTAAAGGRR) was retrieved from the Xenopus tropicalis genome database. We then selected 51- to 1,000-bp MITE candidates framed by an inverted pair of 2 T2-motifs. The 34,398 candidates were classified into possible clusters by a novel terminal sequence (TS)-clustering method on the basis of differences in their short terminal sequences. Finally, 19,242 MITEs were classified into 16 major MITE subfamilies (TS subfamilies), 10 of which showed apparent homologies to known T2 MITE subfamilies, and the rest were novel TS subfamilies. Intra- and inter-subfamily similarities or differences were investigated by analyses of diversity in GC content, total length, and sequence alignments. Furthermore, genome-wide conservation of the inverted pair structure of subfamily-specific TS stretches and their target site sequence (TTAA) were analyzed. The results suggested that some TS subfamilies might include active or at least recently active MITEs for transposition and/or amplification, but some others might have lost such activities a long time ago. The present methodology was efficient in identifying and classifying MITEs, thereby providing information on the evolutionary dynamics of MITEs.     

植物中活性MITEs转座子研究进展

MITEs(Miniature inverted-repeat transposable elements)转座子是一种特殊的转座子,其既有DNA转座子的转座特性——"剪切-粘贴"转座方式,又有RNA转座子的高拷贝特性。目前已被报道的MITEs种类和数量虽然很多,但是关于有转座活性的MITEs的报道却甚少。本文总结了近几年来有关活性MITEs的相关报道,发现具有转座活性的MITEs种类大都分布在Tourist家族,分别是m Ping、m Ging、Ph Tourist1、Tmi1和Ph Tst-3,另外还有Stowaway-like家族的d Tstu1和MITE-39以及Mutator家族的Ah MITE1。文中还分析了这些活性MITEs的结构(TIR和TSD)、拷贝数、进化模式以及转座特性等,为鉴定其他活性MITEs以及MITEs转座和扩增机制的研究奠定了基础。     

The rice R gene family: two distinct subfamilies containing several miniature inverted-repeat transposable elements

The R and B genes of maize regulate the anthocyanin biosynthetic pathway and constitute a small gene family whose evolution has been shaped by polyploidization and transposable element activity. To compare the evolution of regulatory genes in the distinct but related genomes of rice and maize, we previously isolated two R homologues from rice (Oryza sativa). The Ra1 gene on chromosome 4 can activate the anthocyanin pathway, whereas the Rb gene, of undetermined function, maps to chromosome 1. In this study, rice R genes have been further characterized. First, we found that an Rb cDNA can induce pigmentation in maize suspension cells. Second, another rice R homologue (Ra2) was identified that is more closely related to Ra1 than to Rb. Domesticated rice and its wild relatives harbor multiple Ra-like and Rb-like genes despite the fact that rice is a true diploid with the smallest genome of all the grass species analyzed to date. Finally, several miniature inverted-repeat transposable elements (MITEs) were found in R family members. Their possible role in hastening the divergence of R genes is discussed.     

Spring: a novel family of miniature inverted-repeat transposable elements is associated with genes in apple

The apple, Malusxdomestica Borkh., belongs to the family Rosaceae and subfamily Maloideae and has a genome size of approximately 750 Mb. In this study, a novel family of transposable elements, designated Spring, has been identified in the apple genome. The four Spring elements, Spring-1 to Spring-4, share all the classic features of miniature inverted-repeat transposable elements (MITEs), including small size (approximately 148 bp), no coding potential, A/T richness, insertion bias toward noncoding regions, terminal inverted repeats (TIRs), target site duplications, and potential for forming secondary structures. Evidence of previous mobility of Spring-4 is demonstrated by sequence alignment of genes encoding 1-aminocyclopropane-1-carboxylic acid synthase from both apple and a related member of the Maloideae subfamily, pear. The Spring elements are flanked by either 8- or 9-bp direct repeats, and they differ significantly in size compared to other previously reported MITEs in plants. The TIRs of these Spring elements are not found in any other previously reported plant genes or transposons, except for apple. The possible role of Spring elements in the apple genome is discussed.     

Genome-wide analysis of mariner-like transposable elements in rice reveals complex relationships with stowaway miniature inverted repeat transposable elements (MITEs)

Stowaway is a superfamily of miniature inverted repeat transposable elements (MITEs) that is widespread and abundant in plant genomes. Like other MITEs, however, its origin and mode of amplification are poorly understood. Several lines of evidence point to plant mariner-like elements (MLEs) as the autonomous partners of the nonautonomous Stowaway MITEs. To better understand this relationship, we have taken advantage of the nearly complete genome sequences of two rice subspecies to generate the first inventory of virtually all MLEs and Stowaway families coexisting in a single plant species. Thirty-four different MLEs were found to group into three major clades and 25 families. More than 22,000 Stowaway MITEs were identified and classified into 36 families. On the basis of detailed sequence comparisons, MLEs were confirmed to be the best candidate autonomous elements for Stowaway MITEs. Surprisingly, however, sequence similarity between MLE and Stowaway families was restricted to the terminal inverted repeats (TIRs) and, in a few cases, to adjacent subterminal sequences. These data suggest a model whereby most of the Stowaway MITEs in rice were cross-mobilized by MLE transposases encoded by distantly related elements.     

Phylogenetic evidence for excision of Stowaway miniature inverted-repeat transposable elements in triticeae (Poaceae)

The mode of transposition of miniature inverted-repeat transposable elements (MITEs) is unknown, but it has been suggested that they are duplicated rather than excised at transposition. However, the present investigation demonstrates that a particular family of MITEs, Stowaway:, is excised. Mapped onto a gene tree based on partial sequences of disrupted meiotic cDNA1 (DMC1) from 30 species of the Triticeae grasses, it is evident that at least two excisions have occurred, leaving short footprints. These footprints may subsequently be reduced in length or deleted. Excision of Stowaway: elements lends strong support to the suggestion that MITEs are DNA transposons and should be classified as class II elements. The evolution of Stowaway: elements can also be traced by scrutiny of the gene tree. It appears that base substitutions are as frequent in the conserved terminal inverted repeats (TIRs) as in the core of the element. Neither substitutions nor deletions lead to compensatory changes; hence, the highly stable secondary structure of the elements may gradually be reduced.     

PIF- and Pong-like transposable elements: distribution, evolution and relationship with Tourist-like miniature inverted-repeat transposable elements

Miniature inverted-repeat transposable elements (MITEs) are short, nonautonomous DNA elements that are widespread and abundant in plant genomes. Most of the hundreds of thousands of MITEs identified to date have been divided into two major groups on the basis of shared structural and sequence characteristics: Tourist-like and Stowaway-like. Since MITEs have no coding capacity, they must rely on transposases encoded by other elements. Two active transposons, the maize P Instability Factor (PIF) and the rice Pong element, have recently been implicated as sources of transposase for Tourist-like MITEs. Here we report that PIF- and Pong-like elements are widespread, diverse, and abundant in eukaryotes with hundreds of element-associated transposases found in a variety of plant, animal, and fungal genomes. The availability of virtually the entire rice genome sequence facilitated the identification of all the PIF/Pong-like elements in this organism and permitted a comprehensive analysis of their relationship with Tourist-like MITEs. Taken together, our results indicate that PIF and Pong are founding members of a large eukaryotic transposon superfamily and that members of this superfamily are responsible for the origin and amplification of Tourist-like MITEs.     

Using rice to understand the origin and amplification of miniature inverted repeat transposable elements (MITEs)

Recent studies of rice miniature inverted repeat transposable elements (MITEs), largely fueled by the availability of genomic sequence, have provided answers to many of the outstanding questions regarding the existence of active MITEs, their source of transposases (TPases) and their chromosomal distribution. Although many questions remain about MITE origins and mode of amplification, data accumulated over the past two years have led to the formulation of testable models.     

MITE-Hunter: a program for discovering miniature inverted-repeat transposable elements from genomic sequences

Miniature inverted-repeat transposable elements (MITEs) are a special type of Class 2 non-autonomous transposable element (TE) that are abundant in the non-coding regions of the genes of many plant and animal species. The accurate identification of MITEs has been a challenge for existing programs because they lack coding sequences and, as such, evolve very rapidly. Because of their importance to gene and genome evolution, we developed MITE-Hunter, a program pipeline that can identify MITEs as well as other small Class 2 non-autonomous TEs from genomic DNA data sets. The output of MITE-Hunter is composed of consensus TE sequences grouped into families that can be used as a library file for homology-based TE detection programs such as RepeatMasker. MITE-Hunter was evaluated by searching the rice genomic database and comparing the output with known rice TEs. It discovered most of the previously reported rice MITEs (97.6%), and found sixteen new elements. MITE-Hunter was also compared with two other MITE discovery programs, FINDMITE and MUST. Unlike MITE-Hunter, neither of these programs can search large genomic data sets including whole genome sequences. More importantly, MITE-Hunter is significantly more accurate than either FINDMITE or MUST as the vast majority of their outputs are false-positives.