水稻逆转录转座子RIRE10拷贝数与LTR区转录活性的鉴定

在水稻第四号染色体的长臂上鉴定了一个结构完整的Ty3型逆转录转座子RIRE10。RIRE10两LTR间的中间区域在gag pol的上游还包含另一个开放阅读框。通过RT PCR与Northern印迹杂交检测到来自LTR区的转录产物 ;根据点杂交结果 ,鉴定出包含中间区域的RIRE10成员的个数以及LTR区的拷贝数。除了 6 5个完整的逆转录转座子所具备的两个LTR外 ,水稻基因组还含有近 90 0个RIRE10的solo LTR。LTR区的转录以及导致solo LTR产生的同源重组可能影响了RIRE10成员在水稻基因组中的转座活性     

Dasheng: a recently amplified nonautonomous long terminal repeat element that is a major component of pericentromeric regions in rice

A new and unusual family of LTR elements, Dasheng, has been discovered in the genome of Oryza sativa following database searches of approximately 100 Mb of rice genomic sequence and 78 Mb of BAC-end sequence information. With all of the cis-elements but none of the coding domains normally associated with retrotransposons (e.g., gag, pol), Dasheng is a novel nonautonomous LTR element with high copy number. Over half of the approximately 1000 Dasheng elements in the rice genome are full length (5.6-8.6 kb), and 60% are estimated to have amplified in the past 500,000 years. Using a modified AFLP technique called transposon display, 215 elements were mapped to all 12 rice chromosomes. Interestingly, more than half of the mapped elements are clustered in the heterochromatic regions around centromeres. The distribution pattern was further confirmed by FISH analysis. Despite clustering in heterochromatin, Dasheng elements are not nested, suggesting their potential value as molecular markers for these marker-poor regions. Taken together, Dasheng is one of the highest-copy-number LTR elements and one of the most recent elements to amplify in the rice genome.     

New transposable elements identified as insertions in rice transposon Tnr1

Tnr1 (235 bp long) is a transposable element in rice. Polymerase chain reactions (PCRs) done with a primer(s) that hybridizes to terminal inverted repeat sequences (TIRs) of Tnr1 detected new Tnr1 members with one or two insertions in rice genomes. Six identified insertion sequences (Tnr4, Tnr5, Tnr11, Tnr12, Tnr13 and RIRE9) did not have extensive homology to known transposable elements, rather they had structural features characteristic of transposable elements. Tnr4 (1767 bp long) had imperfect 64-bp TIRs and appeared to generate duplication of a 9-bp sequence at the target site. However, the TIR sequences were not homologous to those of known transposable elements, indicative that Tnr4 is a new transposable element. Tnr5 (209 bp long) had imperfect 46-bp TIRs and appeared to generate duplication of sequence TTA like that of some elements of the Tourist family. Tnr11 (811 bp long) had 73-bp TIRs with significant homology to those of Tnr1 and Stowaway and appeared to generate duplication of sequence TA, indicative that Tnr11 is a transposable element of the Tnr1/Stowaway family. Tnr12 (2426 bp long) carried perfect 9-bp TIRs, which began with 5'-CACTA- -3' from both ends and appeared to generate duplication of a 3-bp target sequence, indicative that Tnr12 is a transposable element of the En/Spm family. Tnr13 (347 bp long) had 31-bp TIRs and appeared to generate duplication of an 8-bp target sequence. Two sequences, one the transposon-like element Crackle, had partial homology in the Tnr13 ends. All five insertions appear to be defective elements derived from autonomous ones encoding the transposase gene. All had characteristic tandem repeat sequences which may be recognized by transposase. The sixth insertion sequence, named RIRE9 (3852 bp long), which begins with 5'-TG- -3' and ends with 5'- -CA-3', appeared to generate duplication of a 5-bp target sequence. These and other structural features indicate that this insertion is a solo LTR (long terminal repeat) of a retrotransposon. The transposable elements described above could be identified as insertions into Tnr1, which do not deleteriously affect the growth of rice cells.     

The Saccharomyces cerevisiae genome contains functional and nonfunctional copies of transposon Ty1.

Saccharomyces cerevisiae Ty elements are transposons closely related to retroviruses. The DNA sequence of a functional Ty element (TyH3) is presented. The long terminal repeat sequences are different, suggesting that TyH3 is a recombinant Ty element. A chromosomal Ty element near the LYS2 gene, Ty173, was found to be nonfunctional, even though it has no detectable insertions or deletions. The defect in Ty173 transposition is caused by a missense mutation giving rise to a Leu-to-Ile substitution in the TYB (pol) open reading frame. Several chromosomal Ty elements carry this lesion in their DNA, indicating that nonfunctional Ty elements are common in the yeast genome.     

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.     

Formation of solo-LTRs through unequal homologous recombination counterbalances amplifications of LTR retrotransposons in rice Oryza sativa L

We studied the dynamics of hopi, Retrosat1, and RIRE3, three gypsy-like long terminal repeat (LTR) retrotransposons, in Oryza sativa L. genome. For each family, we assessed the phenetic relationships of the copies and estimated the date of insertion of the complete copies through the evaluation of their LTR divergence. We show that within each family, distinct phenetic groups have inserted at significantly different times, within the past 5 Myr and that two major amplification events may have occurred during this period. We show that solo-LTR formation through homologous unequal recombination has occurred in rice within the past 5 Myr for the three elements. We thus propose an increase/decrease model for rice genome evolution, in which both amplification and recombination processes drive variations in genome size.     

Identification and mapping of expressed genes, simple sequence repeats and transposable elements in centromeric regions of rice chromosomes.

The genomic sequences derived from rice centromeric regions were analyzed to facilitate the comprehensive understanding of the rice genome. A rice centromere-specific satellite sequence, RCS2/TrsD/CentO, was used to screen P1-derived artificial chromosome (PAC) and bacterial artificial chromosome (BAC) genomic libraries derived from Oryza sativa L. ssp. japonica cultivar Nipponbare. Physical maps of the centromeric regions were constructed by DNA fingerprinting methods and the aligned clones were analyzed by end sequencing. BLAST analysis revealed the composition of genes, centromeric satellites and other repetitive elements, such as RIRE7/CRR, RIRE8, Squiq, Anaconda, CACTA and miniature inverted-repeat transposable elements. Fiber-fluorescent in situ hybridization analysis also indicated the presence of distinct clusters of RCS2/TrsD/CentO satellite interspersed with other elements, instead of a long homogeneous region. Several expressed genes, sequences representative of ancestral organellar insertions, relatively long simple sequence repeats (SSRs), and sequences corresponding to 5S and 45S ribosomal RNA genes were also identified. Thirty-one gene sequences showed high-similarity to rice full-length cDNA sequences that had not been matched to the published rice genome sequence in silico. These results suggest the presence of expressed genes within and around the clusters of RCS2/TrsD/CentO satellites in unsequenced centromeric regions of the rice chromosomes.     

A new gypsy-type retrotransposon, RIRE7: preferential insertion into the tandem repeat sequence TrsD in pericentromeric heterochromatin regions of rice chromosomes

A portion of an insertion sequence present in a member of the RIRE3 family of retrotransposons in Oryza sativa L. cv. IR36 was found to have an LTR sequence followed by a PBS sequence complementary to the 3'-end region of tRNAMet, indicative of another rice retrotransposon (named RIRE7). Cloning and sequencing of PCR-amplified fragments that made up all parts of the RIRE7 sequence showed that RIRE7 is a gypsy-type retrotransposon with partial homology in the pol region to the rice gypsy-type retrotransposons RIRE2 and RIRE3 identified in rice previously. Interestingly, various portions of the RIRE7 sequence were homologous to several DNA segments present in the centromere regions of cereal chromosomes. Further cloning and nucleotide sequencing of fragments flanking RIRE7 copies showed that RIRE7 was inserted into a site within a tandem repeat sequence that has a unit length of 155 bp. The tandem repeat sequence, named TrsD, was homologous to tandem repeat sequences RCS2 and CentC, previously identified in the centromeric regions of rice and maize chromosomes. Fluorescence in situ hybridization (FISH) analysis of the metaphase chromosomes of O. sativa cv. Nipponbare showed that both RIRE7 and TrsD sequences were present in the centromere regions of the chromosomes. The presence of RIRE7 and the TrsD sequences in the centromere regions of several chromosomes was confirmed by the identification of several YAC clones whose chromosomal locations are known. Further FISH analysis of rice pachytene chromosomes showed that the TrsD sequences were located in a pericentromeric heterochromatin region. These findings strongly suggest that RIRE7 and TrsD are components of the pericentromeric heterochromatin of rice chromosomes.     

Tnat1 and Tnat2 from Arabidopsis thaliana: novel transposable elements with tandem repeat sequences.

A computer-aided homology search of databases found that the nucleotide sequences flanking ATLN44, a non-LTR retrotransposon (LINE) from Arabidopsis thaliana, are repeated in the A. thaliana genome. These sequences are homologous to flanking sequences of 664 bp with terminal inverted repeat sequences of about 70 bp. The 664-bp sequence and most of the 14 homologues identified were flanked by direct repeat sequences of 9 bp. These findings indicate that the repeated sequence, named Tnat1, is a transposable element that duplicates a 9-bp sequence at the target site on transposition and that ATLN44 is inserted in one Tnat1 member. Interestingly, all of the Tnat1 members had tandem repeats comprised of several units of a 60-bp sequence, the number of repeats differing among Tnat1 members. Of the Tnat1 members identified, one was inserted into another sequence repeated in the A. thaliana genome: that sequence is about 770 bp long and has terminal inverted repeat sequences of about 110 bp. The sequence is flanked by direct repeats of a 9-bp sequence, indicating that it is another transposable element, named Tnat2, from A. thaliana. Moreover, Tnat2 members had a tandem repeat about 240 bp long. Tnat1 and Tnat2 with tandem repeats in their internal regions show no homology to each other or to any of the elements identified previously; therefore they appear to be novel transposable elements.     

Nucleotide sequence of terminal repeats of 412 transposable elements of Drosophila melanogaster: A similarity to proviral long terminal repeats and its implications for the mechanism of transposition

We have sequenced the long terminal direct repeats (and adjacent DNA) of two members of the 412 family of transposable elements of Drosophila melanogaster cloned on fragments of DNA from strain Oregon R. The repeats of the first element are identical and 481 base-pairs long; the repeats of the second are also identical but are 571 base-pairs long. The first 482 base-pairs of the 571 base-pair sequence correspond to the 481 base-pair repeat differing by five base substitutions and one addition/deletion. The 571 base-pair repeats are rare. Each of these 412 elements is flanked by a four base-pair direct repeat, suggesting that insertion of a 412 element is associated with duplication of four base-pairs. Analysis of the “empty site” from strain Canton S corresponding to one of these elements supports this conclusion. The sequence of 481 base-pair repeats and of 412 DNA immediately adjacent to them show striking similarities to corresponding regions of vertebrate proviruses and we discuss the implications this may have for the mechanism of transposition.     

Varied truncation and clustering characterize some short repeats identified in micronucleus-specific DNA of Tetrahymena thermophila

There are over 6000 internally eliminated DNA sequences (IESs) in the Tetrahymena genome that are deleted in a programmed fashion during the development of a polyploid, somatic macronucleus from a diploid germline micronucleus. Recently, based on several results, a homology and small RNA-based mechanism has been proposed for the efficient elimination of IES elements. Since the RNAi machinery is proposed to be intimately involved in silencing potentially harmful repeats such as transposons and viruses, characterization of repeats and the conditions for their developmental elimination from the somatic genome is warranted. Three short (500–600 bp) repeat families, members of which had been experimentally identified in IESs, that is, in micronucleus-specific DNA, are examined here using the Tetrahymena genome database. Members of all three families display varied degrees of truncation and are represented in macronuclear sequences. A 200 bp segment of one of the families can appear in the genome on its own, or as part of a 600 bp repeat detected experimentally, or in association with an unrelated 1 kb sequence to form a 1.2 kb repeat that is also frequently truncated. The 1 kb sequence contains a 300 bp section similar to a repeat associated with a non-long terminal repeat-like element and is often found accompanied by several more copies of this shorter repeat. These observations indicate that transposition may have had a role in the evolution of the short repeat families.     

Whole genome resequencing reveals natural target site preferences of transposable elements in Drosophila melanogaster

Transposable elements are mobile DNA sequences that integrate into host genomes using diverse mechanisms with varying degrees of target site specificity. While the target site preferences of some engineered transposable elements are well studied, the natural target preferences of most transposable elements are poorly characterized. Using population genomic resequencing data from 166 strains of Drosophila melanogaster, we identified over 8,000 new insertion sites not present in the reference genome sequence that we used to decode the natural target preferences of 22 families of transposable element in this species. We found that terminal inverted repeat transposon and long terminal repeat retrotransposon families present clade-specific target site duplications and target site sequence motifs. Additionally, we found that the sequence motifs at transposable element target sites are always palindromes that extend beyond the target site duplication. Our results demonstrate the utility of population genomics data for high-throughput inference of transposable element targeting preferences in the wild and establish general rules for terminal inverted repeat transposon and long terminal repeat retrotransposon target site selection in eukaryotic genomes.     

水稻基因组中一类具有潜在转座活性的Solo—LTR的结构分析和鉴定

在水稻4号染色体两个BAC克隆序列分析中,发现了两个solo-LTR,分别命名为SLTR1和SLTR2。它们分别位于水稻18S rRNA基因和一逆转座子内部。序列比较发现,SLTR1和SLTR2存在着较高的同源性,并与水稻逆转座子RIRE8的LTR序列高度同源,分别为89.1%和70.1%。它们属于一类水稻gypsy类型逆转座子。利用SLTR1和SLTR2与水稻DNA杂交,结果显示两者广泛分布于水稻基因组中,是一类高拷贝重复序列。分别利用SLTR1和SLTR2的两侧特异性序列设计引物进行PCR扩增,结果发现在基因组的相应位置并不存在SLTR1或SLTR2;利用它们两侧被打断基因的特异性片段杂交基因组DNA,得到了同样的结果。这意味着SLTR1和SLTR2来源于基因组的其它位置,并通过某种转座的过程进入18S rRNA基因和另一逆转座子内部。Solo-LTR存在着这种潜在的转座活性,对于进一步研究solo-LTR的来源以及其在基因组进货和基因的表达调控中具有一定的意义。     

Tec3, a new developmentally eliminated DNA element in Euplotes crassus

More than 100,000 interstitial segments of DNA (internal eliminated sequences [IESs]) are excised from the genome during the formation of a new macronucleus in Euplotes crassus. IESs include unique sequence DNA as well as two related families of transposable elements, Tec1 and Tec2. Here we describe a new class of E. crassus transposons, Tec3, which is present in 20 to 30 copies in the micronuclear genome. Tec3 elements have long inverted terminal repeats and contain a degenerate open reading frame encoding a tyrosine-type recombinase. One characterized copy of Tec3 (Tec3-1) is 4.48 kbp long, has 1.23-kbp inverted terminal repeats, and resides within the micronuclear copy of the ribosomal protein L29 gene (RPL29). The 23 bp at the extreme ends of this element are very similar to those in other E. crassus IESs and, like these other IESs, Tec3-1 is excised during the polytene chromosome stage of macronuclear development to generate a free circular form with an unusual junction structure. In contrast, a second cloned element, Tec3-2, is quite similar to Tec3-1 but lacks the terminal 258 bp of the inverted repeats, so that its ends do not resemble the other E. crassus IES termini. The Tec3-2 element appears to reside in a large segment of the micronuclear genome that is subject to developmental elimination. Models for the origins of these two types of Tec3 elements are presented, along with a discussion of how some members of this new transposon family may have come to be excised by the same machinery that removes other E. crassus IESs.     

Terminal repeats of the Drosophila transposable element copia: nucleotide sequence and genomic organization

We have determined the nucleotide sequence of the terminal regions of two members of the copia sequence family of D. melanogaster. The first 276 bp at one end of a copia element are repeated in direct orientation at its other end. The direct repeats on a single copia element are identical to each other, but they differ by two nucleotide substitutions between the two elements which were examined; this suggests that during transposition only one direct repeat of the parent element is used as a template for both direct repeats of the transposed element. Each direct repeat itself contain a 17 bp imperfectly matched inveted terminal repetition. The ends of copia show significant sequence homology both to the yeast Ty1 element and to the integrated provirus of avian spleen necrosis virus, two other eucaryotic elements known to insert at many different chromosomal locations. Analysis of the genomic organization of the direct repeat sequence demonstrates that it seldom, if ever, occurs unlinked to an entire copia element.     

<Emphasis Type="Italic">MDM</Emphasis>-1 and <Emphasis Type="Italic">MDM</Emphasis>-2: Two <Emphasis Type="Italic">Mutator</Emphasis>-Derived MITE Families in Rice

Abstract Numerous miniature inverted repeat transposable elements (MITEs) are present in the rice genome but their transposition mechanisms are unknown. In this report, we present evidence that two novel MITE families may have arisen from Mutator-related transposable elements and thus may use a transposition mechanism similar to that of Mutator elements. Two families of novel MITEs, namely, MDM-1 and MDM-2, were identified by searching for MITEs nested with Kiddo, a previously identified MITE family. MDM-1 and MDM-2 bear hallmarks of Mutator elements, such as long terminal inverted repeats (LTIRs), 9-bp target-site duplications (TSDs), and putative transposase binding sites. Strikingly, the MDM-1 family has a 9-bp terminus identical to that of a rice Mutator-like element (MULE-9) and the MDM-2 family has an 8-bp terminus identical to that of the maize autonomous Mutator element MuDR. A putative transposase homologous to MURA protein is identified for the MDM-2 family. Thus, these two novel MITE families, with a total copy number of several hundred in rice, are designated Mutator-derived MITEs (MDMs). Interestingly, sequence decay analysis of MDM families revealed a number of insertion site duplications (ISDs) in the alignment gaps, and widespread historical nesting events are proposed to account for the existence of these ISDs. In addition to its value for discovering new MITEs, the nesting analysis approach used in this study simultaneously identifies MITE insertion polymorphisms.     

Molecular and cytological analyses of large tracks of centromeric DNA reveal the structure and evolutionary dynamics of maize centromeres

We sequenced two maize bacterial artificial chromosome (BAC) clones anchored by the centromere-specific satellite repeat CentC. The two BACs, consisting of approximately 200 kb of cytologically defined centromeric DNA, are composed exclusively of satellite sequences and retrotransposons that can be classified as centromere specific or noncentromere specific on the basis of their distribution in the maize genome. Sequence analysis suggests that the original maize sequences were composed of CentC arrays that were expanded by retrotransposon invasions. Seven centromere-specific retrotransposons of maize (CRM) were found in BAC 16H10. The CRM elements inserted randomly into either CentC monomers or other retrotransposons. Sequence comparisons of the long terminal repeats (LTRs) of individual CRM elements indicated that these elements transposed within the last 1.22 million years. We observed that all of the previously reported centromere-specific retrotransposons in rice and barley, which belong to the same family as the CRM elements, also recently transposed with the oldest element having transposed approximately 3.8 million years ago. Highly conserved sequence motifs were found in the LTRs of the centromere-specific retrotransposons in the grass species, suggesting that the LTRs may be important for the centromere specificity of this retrotransposon family.