Eight intact LTR retrotransposons (Nbr1-Nbr8) have been previously characterized from the genome of Nosema bombycis, a eu- karyotic parasite with a compact and reduced genome. Here we describe six novel transcribed ...Eight intact LTR retrotransposons (Nbr1-Nbr8) have been previously characterized from the genome of Nosema bombycis, a eu- karyotic parasite with a compact and reduced genome. Here we describe six novel transcribed Nbr elements (Nbr9-Nbr14) identified through either cDNA library or RT-PCR. Like previously determined ones, all of them belong to the Ty3/Gypsy superfamily. Retrotransposon diversity and incomplete domains with insertions (Nbr12), deletions (Nbrll) and in-frame stop codons in coding regions (Nbr9) were detected, suggesting that both defective and loss events of LTR retrotransposon have happened in N. bornbycis genome. Analysis of selection showed that strong purifying selection acts on all elements except Nbr11. This implies that selective pressure keeps both these Nbrs and their functions in genome. Interestingly, Nbrll is under positive selection and some positively selected codons were identified, indicating that new functionality might have evolved in the Nbrll retrotransposon. Unlike other transposable elements, Nbrll has integrated into a conserved syntenic block and probably resulted in the inversion of both flanking regions. This demonstrates that transposable element is an important factor for the reshuffling and evolution of their host genomes, and may be maintained under natural selection.展开更多
Long terminal repeat (LTR) retrotransposons, one of the foremost types of transposons, continually change or modify gene function and reorganize the genome through bursts of dramatic proliferation. Many LTR-TEs pref...Long terminal repeat (LTR) retrotransposons, one of the foremost types of transposons, continually change or modify gene function and reorganize the genome through bursts of dramatic proliferation. Many LTR-TEs preferen-tially insert within other LTR-TEs, but the cause and evolutionary significance of these nested LTR-TEs are not well under-stood. In this study, a total of 1.52 Gb of Brassica sequence containing 2020 bacterial artificial chromosomes (BACs) was scanned, and six bacterial artificial chromosome (BAC) clones with extremely nested LTR-TEs (LTR-TEs density: 7.24/kb) were selected for further analysis. The majority of the LTR-TEs in four of the six BACs were found to be derived from the rapid proliferation of retrotransposons originating within the BAC regions, with only a few LTR-TEs originating from the proliferation and insertion of retrotransposons from outside the BAC regions approximately 5-23 Mya. LTR-TEs also pref-erably inserted into TA-rich repeat regions. Gene prediction by Genescan identified 207 genes in the 0.84Mb of total BAC sequences. Only a few genes (3/207) could be matched to the Brassica expressed sequence tag (EST) database, indicating that most genes were inactive after retrotransposon insertion. Five of the six BACs were putatively centromeric. Hence, nested LTR-TEs in centromere regions are rapidly duplicated, repeatedly inserted, and act to suppress activity of genes and to reshuffle the structure of the centromeric sequences. Our results suggest that LTR-TEs burst and proliferate on a local scale to create nested LTR-TE regions, and that these nested LTR-TEs play a role in the formation of centromeres.展开更多
Stochastic introgression of alien DNA may impose a genomic stress to the recipient genome. Herein, we report that apparent de novo genomic rearrangements in 10 of 13 selected endogenous, lowcopy, and potentially activ...Stochastic introgression of alien DNA may impose a genomic stress to the recipient genome. Herein, we report that apparent de novo genomic rearrangements in 10 of 13 selected endogenous, lowcopy, and potentially active long terminal repeat (LTR) retrotransposons occurred in one or more of three rice lines studied that were introgressed by wild rice (Zizania latifolia Griseb.). For nine retrotransposons in which both the reverse-transcriptase (RT) region and the LTR region were available, largely concordant rearrangements occurred at both regions in five elements and at the RT region only in the remaining four elements. A marked proportion of the genomic changes was shared by two or all three introgression lines that were derived from a single F~ plant. This indicates that most of the genomic changes occurred at early developmental stages of the F~ somatic cells, which then gave rise to germline cells, and, hence, ensured inheritance of the changes to later generations. Possible causes and potential implications of the introgression-induced genomic rearrangements in LTR retrotransposons are discussed in the context of plant genome evolution and breeding.展开更多
基金supported by the National Basic Research Program of China(No.2005CB121000)the project of Chongqing Science & Technology Commission(CSTC,No.2006AA5019 and 2009BB1241)+1 种基金the Programme of Introducing Talents of Discipline to Universities(No.B07045)State Development Fund at Risk of Callus Silk(No.M012005-000Y-00070)
文摘Eight intact LTR retrotransposons (Nbr1-Nbr8) have been previously characterized from the genome of Nosema bombycis, a eu- karyotic parasite with a compact and reduced genome. Here we describe six novel transcribed Nbr elements (Nbr9-Nbr14) identified through either cDNA library or RT-PCR. Like previously determined ones, all of them belong to the Ty3/Gypsy superfamily. Retrotransposon diversity and incomplete domains with insertions (Nbr12), deletions (Nbrll) and in-frame stop codons in coding regions (Nbr9) were detected, suggesting that both defective and loss events of LTR retrotransposon have happened in N. bornbycis genome. Analysis of selection showed that strong purifying selection acts on all elements except Nbr11. This implies that selective pressure keeps both these Nbrs and their functions in genome. Interestingly, Nbrll is under positive selection and some positively selected codons were identified, indicating that new functionality might have evolved in the Nbrll retrotransposon. Unlike other transposable elements, Nbrll has integrated into a conserved syntenic block and probably resulted in the inversion of both flanking regions. This demonstrates that transposable element is an important factor for the reshuffling and evolution of their host genomes, and may be maintained under natural selection.
文摘Long terminal repeat (LTR) retrotransposons, one of the foremost types of transposons, continually change or modify gene function and reorganize the genome through bursts of dramatic proliferation. Many LTR-TEs preferen-tially insert within other LTR-TEs, but the cause and evolutionary significance of these nested LTR-TEs are not well under-stood. In this study, a total of 1.52 Gb of Brassica sequence containing 2020 bacterial artificial chromosomes (BACs) was scanned, and six bacterial artificial chromosome (BAC) clones with extremely nested LTR-TEs (LTR-TEs density: 7.24/kb) were selected for further analysis. The majority of the LTR-TEs in four of the six BACs were found to be derived from the rapid proliferation of retrotransposons originating within the BAC regions, with only a few LTR-TEs originating from the proliferation and insertion of retrotransposons from outside the BAC regions approximately 5-23 Mya. LTR-TEs also pref-erably inserted into TA-rich repeat regions. Gene prediction by Genescan identified 207 genes in the 0.84Mb of total BAC sequences. Only a few genes (3/207) could be matched to the Brassica expressed sequence tag (EST) database, indicating that most genes were inactive after retrotransposon insertion. Five of the six BACs were putatively centromeric. Hence, nested LTR-TEs in centromere regions are rapidly duplicated, repeatedly inserted, and act to suppress activity of genes and to reshuffle the structure of the centromeric sequences. Our results suggest that LTR-TEs burst and proliferate on a local scale to create nested LTR-TE regions, and that these nested LTR-TEs play a role in the formation of centromeres.
文摘Stochastic introgression of alien DNA may impose a genomic stress to the recipient genome. Herein, we report that apparent de novo genomic rearrangements in 10 of 13 selected endogenous, lowcopy, and potentially active long terminal repeat (LTR) retrotransposons occurred in one or more of three rice lines studied that were introgressed by wild rice (Zizania latifolia Griseb.). For nine retrotransposons in which both the reverse-transcriptase (RT) region and the LTR region were available, largely concordant rearrangements occurred at both regions in five elements and at the RT region only in the remaining four elements. A marked proportion of the genomic changes was shared by two or all three introgression lines that were derived from a single F~ plant. This indicates that most of the genomic changes occurred at early developmental stages of the F~ somatic cells, which then gave rise to germline cells, and, hence, ensured inheritance of the changes to later generations. Possible causes and potential implications of the introgression-induced genomic rearrangements in LTR retrotransposons are discussed in the context of plant genome evolution and breeding.
