Alu Repeats in the Human Genome

Highly repetitive DNA sequences account for more than 50% of the human genome. The L1 and Alu families harbor the most common mammalian long and short interspersed elements. An Alu element is a dimer of similar, but not identical, fragments of total size about 300 bp, and originates from the 7SL RNA gene. Each element contains a bipartite promoter for RNA polymerase III, a poly(A) tract located between the monomers, a 3"-terminal poly(A) tract, and numerous CpG islands, and is flanked by short direct repeats. Alu repeats constitute more than 10% of the human genome and are capable of retroposition. Possibly, these elements played an important part in genome evolution. Insertion of an Alu element into a functionally important genome region or other Alu-dependent alterations of gene functions cause various hereditary disorders and are probably associated with carcinogenesis. In total, 14 Alu families differing in diagnostic mutations are known. Some of these, which are present in the human genome, are polymorphic and relatively recently have been inserted into new loci. Alu copies transposed during ethnic divergence of the human population are useful markers for evolutionary genetic studies.     

Recent amplification of miniature inverted-repeat transposable elements in the vector mosquito Culex pipiens: characterization of the Mimo family

We describe a new family of repetitive elements, named Mimo, from the mosquito Culex pipiens. Structural characteristics of these elements fit well with those of miniature inverted-repeat transposable elements (MITEs), which are ubiquitous and highly abundant in plant genomes. The occurrence of Mimo in C. pipiens provides new evidence that MITEs are not restricted to plant genomes, but may be widespread in arthropods as well. The copy number of Mimo elements in C. pipiens (1000 copies in a 540 Mb genome) supports the hypothesis that there is a positive correlation between genome size and the magnitude of MITE proliferation. In contrast to most MITE families described so far, members of the Mimo family share a high sequence conservation, which may reflect a recent amplification history in this species. In addition, we found that Mimo elements are a frequent nest for other MITE-like elements, suggesting that multiple and successive MITE transposition events have occurred very recently in the C. pipiens genome. Despite evidence for recent mobility of these MITEs, no element has been found to encode a protein; therefore, we do not know how they have transposed and have spread in the genome. However, some sequence similarities in terminal inverted-repeats suggest a possible filiation of some of these mosquito MITEs with pogo-like DNA transposons.     

Polymorphism of the Mdg-1 and I mobile elements in Drosophila melanogaster

The polymorphism of the mobile elements Mdg-1 (a copia-like element) and I (an element involved in I-R hybrid dysgenesis) was analysed in a mass-mated population of Drosophila melanogaster by in situ hybridization, using biotinylated DNA probes, on polytene chromosomes. The Mdg-1 and I elements were inserted independently but were within the same bulk of DNA insertion points of the Drosophila genome, which contained on average about 30 insertion sites for each element. The X chromosome contained the lowest copy number of elements while 2R and 3R had the highest number: 3R had the highest variability. There was no correlation between the copy numbers of elements among the chromosome arms. The average expected per locus heterozygosity was equal to 0.17 for both the Mdg-1 and the I elements. Although these two elements differ in sequence, they appeared to behave similarly in the Drosophila melanogaster genome. This suggests that they may compete for target insertion sites and may be under the same control mechanisms.     

Presence of miniature inverted-repeat transposable elements (MITEs) in the genome of Arabidopsis thaliana : characterisation of the Emigrant family of elements

Although the genome of Arabidopsis thaliana has a small amount of repetitive DNA, it contains representatives of most classes of mobile elements. However, to date, no miniature inverted-repeat transposable element (MITE) has been described in this plant. Here, we describe a new family of repeated sequences that we have named Emigrant , which are dispersed in the genome of Arabidopsi s and fulfil all the requirements of MITEs. These sequences are short, AT-rich, have terminal inverted repeats (TIRs), and do not seem to have any coding capacity. Evidence for the mobility of Emigrant elements has been obtained from the absence of one of these elements in a specific Arabidopsis ecotype. Emigrant is also present in the genome of different Brassicae and its TIRs are 74% identical to those of Wujin elements, a recently described family of MITEs from the yellow fever mosquito Aedes aegypti.      

Characterisation of a short interspersed repeat (Mermaid) that has family members on human chromosome 21 and elsewhere in the human genome

To understand the architecture of the human genome, we need a complete definition of all the repeat sequence families, as these make up the majority of human DNA. We have isolated a small DNA fragment from human chromosome 21 and have used sequence analysis of this fragment to uncover a new low copy repeat element of approximately 300 bp that we term the Mermaid repeat. This repeat is related to, but is different from, the MER 12 repeat and is interspersed in the genome. Mermaid family members that we have studied are between 81%–87% identical to our preliminary consensus sequence. Therefore, we have added a new member to the large collection of human repetitive elements. In addition, we have mapped a Mermaid repeat to a telomeric position on the long arm of human chromosome 21, at 21q22.3     

Remobilization of <Emphasis Type="Italic">Tol2</Emphasis> transposons in <Emphasis Type="Italic">Xenopus tropicalis</Emphasis>

Background  

The Class II DNA transposons are mobile genetic elements that move DNA sequence from one position in the genome to another. We have previously demonstrated that the naturally occurring Tol2 element from Oryzias latipes efficiently integrates its corresponding non-autonomous transposable element into the genome of the diploid frog, Xenopus tropicalis. Tol2 transposons are stable in the frog genome and are transmitted to the offspring at the expected Mendelian frequency.     

Low number of mitochondrial pseudogenes in the chicken (<Emphasis Type="Italic">Gallus gallus</Emphasis>) nuclear genome: implications for molecular inference of population history and phylogenetics

Background  

Mitochondrial DNA has been detected in the nuclear genome of eukaryotes as pseudogenes, or Numts. Human and plant genomes harbor a large number of Numts, some of which have high similarity to mitochondrial fragments and thus may have been inadvertently included in population genetic and phylogenetic studies using mitochondrial DNA. Birds have smaller genomes relative to mammals, and the genome-wide frequency and distribution of Numts is still unknown. The release of a preliminary version of the chicken (Gallus gallus) genome by the Genome Sequencing Center at Washington University, St. Louis provided an opportunity to search this first avian genome for the frequency and characteristics of Numts relative to those in human and plants.     

Characterization of a Tc1-like transposable element in zebrafish (Danio rerio)

We have characterized Tdr1, a family of Tc1-like transposable elements found in the genome of zebrafish (Danio rerio). The copy number and distribution of the sequence in the zebrafish genome have been determined, and by these criteria Tdr1 can be classified as a moderately repetitive, interspersed element. Examination of the sequences and structures of several copies of Tdr1 revealed that a particular deletion derivative, 1250 by long, of the transposon has been amplified to become the dominant form of Tdr1. The deletion in these elements encompasses sequences encoding the N-terminal portion of the putative Tdr1 transposase. Sequences corresponding to the deleted region were also detected, and thus allowed prediction of the nucleotide sequence of a hypothetical full-length element. Well conserved segments of Tc1-like transposons were found in the flanking regions of known fish genes, suggesting that these elements have a long evolutionary history in piscine genomes. Tdr1 elements have long, 208 by inverted repeats, with a short DNA motif repeated four times at the termini of the inverted repeats. Although different from that of the prototype C. elegans transposon Tc1, this inverted repeat structure is shared by transposable elements from salmonid fish species and two Drosophila species. We propose that these transposons form a subgroup within the Tc1-like family. Comparison of Tc1-like transposons supports the hypothesis that the transposase genes and their flanking sequences have been shaped by independent evolutionary constraints. Although Tc1-like sequences are present in the genomes of several strains of zebrafish and in salmonid fishes, these sequences are not conserved in the genus Danio, thus raising the possibility that these elements can be exploited for gene tagging and genome mapping.     

<Emphasis Type="Italic">Mutator</Emphasis>-like elements identified in melon,Arabidopsis and rice contain ULP1 protease domains

The transposon Mutator was first identified in maize, and is one of the most active mobile elements in plants. The Arabidopsis thaliana genome contains at least 200 Mutator-like elements (MULEs), which contain the Mutator-like transposase gene, and often additional genes. We have detected a novel type of MULEs in melon (CUMULE), which, besides the transposase, contains two ubiquitin-like specific protease-like sequences (ULP1). This element is not present in the observed location in some melon cultivars. Multiple copies of this element exist in the Cucumis melo genome, and it has been detected in other Cucurbitaceae species. Analysis of the A. thaliana genome revealed more than 90 CUMULE-like elements, containing one or two Ulp1-like sequences, although no evidence of mobility exists for these elements. We detected various putative transposable elements containing ULP1-like sequences in rice. The discovery of these MULEs in melon and Arabidopsis, and the existence of similar elements in rice and maize, suggest that a proteolytic function may be important for this subset of the MULE transposable elements. Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users. Nucleotide sequence data reported are available in the GenBank database under the accession number AY524004.     

Short Inverted-Repeat Transposable Elements in Teleost Fish and Implications for a Mechanism of Their Amplification

Angel is the first miniature inverted-repeat transposable element (MITE) isolated from fish. Angel elements are imperfect palindromes with the potential to form stem-loop structures in vitro. Despite sequence divergence of elements of up to 55% within and between species, their inverted repeat structures have been maintained, implying functional importance. We estimate that there are about 10³–10⁴ Angels scattered throughout the zebrafish genome, evidence that this family of transposable elements has been significantly amplified over the course of evolution. Angel elements and Xenopus MITEs carry common sequence motifs at their termini, indicating common origin and/or related mechanisms of transposition. We present a model in which MITEs take advantage of the basic cellular mechanism of DNA replication for their amplification, which is dependent on the characteristic inverted repeat structures of these elements. We propose that MITEs are genomic parasites that transpose via a DNA intermediate, which forms by a folding-back of a single strand of DNA, that borrow all of the necessary factors for their amplification from products encoded in the genomes in which they reside. DNA polymorphisms in different lines of zebrafish were detected by PCR using Angel-specific primers, indicating that such elements, combined with other transposons in vertebrate genomes, will be useful molecular tools for genome mapping and genetic analyses of mutations. Received: 7 April 1998 / Accepted: 7 April 1998     

Molecular analysis of the genomic organization of the Hymenoptera Diadromus pulchellus and Eupelmus vuilleti

The genomic organization of two parasitic wasps was analyzed by DNA reassociation. Cot curves revealed a pattern with three types of components. A highly repetitive DNA, accounting for 15 to 25% of the genome, was identified as satellite DNA. The moderately repetitive DNA corresponds to 26 to 42% of the genome in both species, and shows large variations in complexity, repetitive frequency and a number of sub-components between males and females. These variations are seen as resulting from DNA amplification during somatic and sexual differentiation. Dot blot analyses show that such DNA amplifications concern several types of structural and regulatory genes. The presence of repeated mobile elements was studied by the Roninson method to compare the repeated sequence patterns of Diadromus pulchellus and Eupelmus vuilleti with those of Drosophila melanogaster. The occurrence and organization of mobile elements in these Hymenoptera differ from those of the neighboring order of Diptera. The repetitive and unique components define very large genomes (1 to 3 × 10⁹ base pairs). The genomic organization in Parasitica appears to be an extreme drosophilan type. We propose that the germinal genome of these parasitic wasps is primarily composed of satellite DNA blocks and very long stretches of unique sequences, separated by a few repeated and/or variously deleted, interspersed elements of each mobile element family.     

The Au family, a novel short interspersed element (SINE) from Aegilops umbellulata

A novel plant short interspersed nuclear element (SINE) was identified in the second intron of the acetyl CoA carboxylase gene of Aegilops umbellulata which has been designated ”Au”, for the host species in which it was discovered. Au elements have a tRNA-related region, direct flanking repeats, and a short stretch of T at the 3′ end, which are features common to Au and previously characterized SINEs. Au elements are detected in the genomes of several monocots and dicots by DNA dot hybridization and are also found in the tobacco genome by database searching. Au elements are present at an especially high copy number (approximately 10⁴ copies per haploid genome) in wheat and Ae. umbellulata. This suggests a recent amplification of Au in the Triticum and Aegilops species. In situ hybridization revealed a dispersed distribution of Au elements on wheat chromosomes. Au elements were amplified by PCR from monocot and dicot species and the phylogenetic relationships among Au elements were inferred. This phylogenetic analysis suggests amplification of Au elements in a manner consistent with the retrotransposon model for SINE dispersion. The high copy number of Au elements and their dispersed distribution in wheat are desirable characteristics for a molecular marker system in this important species. Received: 15 April 2000 / Accepted: 24 August 2000     

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．     

Mobilization of a Hobo-related Sequence in the Genome of Drosophila simulans

The hobo transposable element can occur under three forms in the Drosophila genome: as a complete element (also called canonical), as internally deleted copies, or as hobo-related sequences (relics). Some evidence indicated that canonical elements and internally deleted copies are recent acquisitions of Drosophila genomes, while the “relics” are old components, normally degenerated and immobile. Here we present the characterization of a hobo-related sequence, found in the genome of a hypermutable strain of D. simulans, which insertion into the white locus raised a de novo white mutation. It is a shorter hobo related element presenting, overall, roughly 18% of divergence at the DNA level from the canonical hobo, with many indels that make clear this element is defective. However, its ITRs and flanking regions are extremely conserved. This is the first hobo “relic” showed to be mobilizable. We suggest, and point up some evidences, toward the idea that this sequence could have been mobilized by the canonical element. The presence of a similar “relic” element in D. sechellia allows us to suggest that these elements have been maintained mobilizable since the time of divergence between these species.     

A Protein Similarity Approach For Detecting Prophage Regions In Bacterial Genomes

Background  

Numerous completely sequenced bacterial genomes harbor prophage elements. These elements have been implicated in increasing the virulence of the host and in phage immunity. The e14 element is a defective lambdoid prophage element present at 25 min in the Escherichia coli K-12 genome. e14 is a well-characterized prophage element and has been subjected to in-depth bioinformatic analysis.     

Master: a novel family of PIF/Harbinger-like transposable elements identified in carrot (Daucus carota L.)

Members of a novel Master family of class II transposons were identified in the carrot genome. Two elements, 2.5 kb long DcMaster1 and 4.4 kb long DcMaster-a, are characterized by 22 bp imperfect terminal inverted repeats and by 3 bp target site duplications. GenBank search revealed that related elements are also present in Medicago truncatula, including a 5.1 kb element MtMaster-a. Both DcMaster-a and MtMaster-a contain open reading frames encoding for putative transposases with the complete DDE domain typical for plant class II transposable elements belonging to PIF/Harbinger superfamily, where the Master elements form a distinct group. Less than 10 copies of the DcMaster element containing the DDE domain are present in genomes of carrot and other Apiaceae, but more copies with internal deletions or insertions may occur. DcMaster elements were associated with putative coding regions in 8 of 14 identified insertion sites. PCR amplification of carrot genomic DNA using a primer complementary to TIRs of DcMaster gave products <400 bp in size. We speculate that these may all represent a MITE-like family of transposable elements that we named Krak, present in the carrot genome in at least 3,600 copies. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users. Sequence data from this article have been deposited with the EMBL/GenBank Data Libraries under accession numbers DQ250792 to DQ250807 and DQ353734 to DQ353752.     

A maize cryptic Ac-homologous sequence derived from an Activator transposable element does not transpose.

Summary Sequences sharing homology to the transposable element Activator (Ac) are prevalent in the maize genome. A cryptic Ac-like DNA, cAc-11, was isolated from the maize inbred line 4Co63 and sequenced. Cryptic Ac-11 has over 90% homology to known Ac sequences and contains an 11 by inverted terminal repeat flanked by an 8 by target site duplication, which are characteristics of Ac and Dissociation (Ds) transposable elements. Unlike the active Ac element, which encodes a transposase, the corresponding sequence in cAc-11 has no significant open reading frame. A 44 by tandem repeat was found at one end of cAc-11, which might be a result of aberrant transposition. The sequence data suggest that cAc-11 may represent a remnant of an Ac or a Ds element. Sequences homologous to cAc-11 can be detected in many maize inbred lines. In contrast to canonical Ac elements, cAc-11 DNA in the maize genome is hypermethylated and does not transpose even in the presence of an active Ac element.     

A lineage‐specific centromere retrotransposon in Oryza brachyantha

Most eukaryotic centromeres contain large quantities of repetitive DNA, such as satellite repeats and retrotransposons. Unlike most transposons in plant genomes, the centromeric retrotransposon (CR) family is conserved over long evolutionary periods among a majority of the grass species. CR elements are highly concentrated in centromeres, and are likely to play a role in centromere function. In order to study centromere evolution in the Oryza (rice) genus, we sequenced the orthologous region to centromere 8 of Oryza sativa from a related species, Oryza brachyantha. We found that O. brachyantha does not have the canonical CRR (CR of rice) found in the centromeres of all other Oryza species. Instead, a new Ty3‐gypsy (Metaviridae) retroelement (FRetro3) was found to colonize the centromeres of this species. This retroelement is found in high copy numbers in the O. brachyantha genome, but not in other Oryza genomes, and based on the dating of long terminal repeats (LTRs) of FRetro3 it was amplified in the genome in the last few million years. Interestingly, there is a high level of removal of FRetro3 based on solo‐LTRs to full‐length elements, and this rapid turnover may have played a role in the replacement of the canonical CRR with the new element by active deletion. Comparison with previously described ChIP cloning data revealed that FRetro3 is found in CENH3‐associated chromatin sequences. Thus, within a single lineage of the Oryza genus, the canonical component of grass centromeres has been replaced with a new retrotransposon that has all the hallmarks of a centromeric retroelement.     

Analysis of the human <Emphasis Type="Italic">Alu</Emphasis> Ye lineage

Background  

Alu elements are short (~300 bp) interspersed elements that amplify in primate genomes through a process termed retroposition. The expansion of these elements has had a significant impact on the structure and function of primate genomes. Approximately 10 % of the mass of the human genome is comprised of Alu elements, making them the most abundant short interspersed element (SINE) in our genome. The majority of Alu amplification occurred early in primate evolution, and the current rate of Alu retroposition is at least 100 fold slower than the peak of amplification that occurred 30–50 million years ago. Alu elements are therefore a rich source of inter- and intra-species primate genomic variation.