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First published online July 3, 2003; 10.1105/tpc.011809 American Society of Plant Biologists Two-Step Regulation and Continuous Retrotransposition of the Rice LINE-Type Retrotransposon Karma
a Graduate School of Biological Sciences, Nara Institute of Science and Technology, Ikoma, Nara 630-0101, Japan 2 To whom correspondence should be addressed. E-mail akyozuka{at}mail.ecc.u-tokyo.ac.jp; fax 81-3-5841-5087
Here, we report the identification of Karma, a LINE-type retrotransposon of plants for which continuous retrotransposition was observed in consecutive generations. The transcription of Karma is activated in cultured cells of rice upon DNA hypomethylation. However, transcription is insufficient for retrotransposition, because no increase in the copy number was observed in cultured cells or in the first generation of plants regenerated from them. Despite that finding, copy number increase was detected in the next generation of regenerated plants as well as in later generations, suggesting that the post-transcriptional regulation of Karma retrotransposition is development dependent. Our results indicate that two different mechanisms, one transcriptional and the other developmental, control the mobilization of Karma. In addition, unlike other known active plant retrotransposons, Karma is not subject to de novo methylation, and retrotransposition persists through several generations.
The completion of the rice genome draft sequences revealed that retrotransposons account for >15% of the genome of rice (Goff et al., 2002  ; Yu et al., 2002). In contrast to DNA-type transposable elements, retrotransposons encode a reverse transcriptase (RT) activity and move by a replicative mechanism that involves an RNA intermediate. Thus, retrotransposons contributed greatly to the expansion and the evolution of the genome (reviewed by Kumar and Bennetzen, 1999; Prak and Kazazian, 2000; Feschotte et al., 2002).
Despite the fact that retrotransposons exist in high copy numbers in the genomes of most eukaryotes, the great majority of them are inactive or defective, and only a small portion of them retain the ability to retrotranspose (reviewed by Grandbastien, 1998
Recently, a survey of >400,000 EST sequences of maize identified only 56 retrotransposon cDNAs, supporting the notion that most retrotransposons are inactive (Meyers et al., 2001
Retrotransposons can be classified as either long terminal repeat (LTR) retrotransposons or non-LTR retrotransposons, depending on the presence or absence of terminal repeats. Retrotranspositionally active elements identified from plants to date all belong to the LTR subclass, and very limited information is available concerning non-LTR retrotransposons. Plant genomes contain both the long interspersed elements (LINEs) and short interspersed elements (SINEs) types of non-LTR retrotransposons; however, these are less abundant than LTRs (Noma et al., 1999 To fill the void of knowledge about plant non-LTR retrotransposons, isolation of active copies has been long desired. Here, the identification of Karma, a mobile LINE element in plants, is described. Karma activation in rice plants is controlled in two steps: the first occurs at transcription, and the second is post-transcriptional and development dependent. Interestingly, once the retrotransposition of Karma starts in the progeny of tissue culture–derived plants, Karma remains active for generations.
Karma Is a Novel LINE-Type Retrotransposon Karma was identified as an insertion in a mutant allele of the FRIZZY PANICLE2 locus (Komatsu et al., 2001 , 2003). DNA sequence analysis revealed that this insertion represents a novel rice non-LTR retrotransposon of the LINE group, which was designated Karma. Karma is 7080 bp long and has a 5' untranslated region of 39 bp, two nonoverlapping open reading frames of 3156 and 3594 bp, which are separated by an intergenic spacer of 220 bp and translated in different frames, and a 3' untranslated region of 71 bp; it is terminated by a poly(A) tail of 11 bases (Figure 1A). Domains conserved in LINE elements are observed in Karma. Short Cys-rich motifs are present at each open reading frame, and an endonuclease and a reverse transcriptase domain are found at the second open reading frame. Karma is related more closely to other plant LINEs, in particular to the maize Cin4 element (Schwarz-Sommer et al., 1997), with which it shares 37% amino acid identity in the reverse transcriptase domain (Figure 1B). Interestingly, all known plant LINEs belong to the L1 clade (Figure 2), which includes the mouse and human LINE-1 elements (Loeb et al., 1986; Dombroski et al., 1991).
Karma Distribution Varies between Rice Subspecies The number of Karma copies in the genome of japonica, javanica, and indica subspecies of rice was examined first by DNA gel blot analysis (Figures 3A and 3B). As indicated in Figure 1A, DNA was digested with EcoRV, and blots were hybridized with probes A and B from the 5' and 3' ends of Karma, respectively. In the eight japonica cultivars analyzed, only one fragment was hybridized by probe A (Figure 3A), whereas three fragments were detected by probe B (Figure 3B). All fragments were conserved in the eight cultivars, suggesting that japonica rice has one full-length and two 5' truncated copies of Karma. In the five indica cultivars analyzed, no fragments hybridized to probe A, whereas one or two fragments were detected by probe B, suggesting that indica rice has only 5' truncated Karma copies. Three cultivars of javanica, which also is a cultivated rice subspecies, were analyzed. One fragment detected by probe A and three fragments detected by probe B were conserved in the three javanica cultivars, suggesting that javanica rice also has one full-length and two 5' truncated copies of Karma. An additional fragment was detected by both probes in one of the javanica cultivars.
The full-length Karma copies conserved in japonica and javanica cultivars separated into bands of different sizes in DNA gel blot analyses. Sequencing of their flanking regions and rough mapping using recombinant inbred lines confirmed that they are localized at different positions in the genome. The japonica full-length copy is 7080 bp long and is localized on chromosome 11, whereas the javanica full-length copy is 7068 bp long and is localized on chromosome 1. PCR amplifications demonstrating the divergence in japonica and javanica full-length copy locations are shown in Figure 3C. Nondisrupted PCR products also were sequenced and showed no deletions or truncations that could indicate genome rearrangements (data not shown). Both copies were flanked by direct repeats and were terminated by poly(A) tails of different lengths (Figure 3D).
With the publication of draft sequences for the japonica and indica rice genomes (Goff et al., 2002
Karma Distribution Varies in Oryza Species The number and distribution of Karma copies also diverged in accessions of Oryza rufipogon (Figure 4), the proposed wild ancestor of rice (Wang et al., 1992 ; Khush, 1997; Bautista et al., 2001), and other Oryza species. This divergence suggests that Karma transposition may have been activated occasionally during the course of rice domestication. However, the possibility that the difference in band sizes results from genome rearrangements cannot be excluded. A conserved pattern of distribution was not observed among O. rufipogon accessions from China or tropical Asia, indicating that the divergence in Karma copy distribution occurred before the domestication of rice. Accordingly, hybridization also was observed in O. longistaminata but not in other Oryza species besides O. rufipogon (Figure 4).
Karma Retrotransposes in Regenerated Plants but Not in Cultured Cells Because retrotransposons move in a "copy-and-paste" manner, an increase in copy number indicates the occurrence of retrotransposition. No increase in copy number was detected in 54 independent lineages of cells cultured for 5 months to 4 years (Table 3, Figure 5A), suggesting that Karma did not retrotranspose in cultured cells. Karma retrotransposition also was not detected in leaves of 13 independent R0 seedlings, which were regenerated from cultured cells. However, an increase in Karma copy numbers was observed in plants of R1 lineages (Table 3, Figure 5B). Most interestingly, we detected additional copy number increases in regenerated plants of consecutive generations up to R6, which was the most advanced generation analyzed (Table 3). Although we did not analyze the same lineage for more than two subsequent generations, the transmission of new insertions of the parental plant to the progeny was observed, as shown in Figures 5C and 5D. Lineages in which the copy number did not increase in the R1 generation but increased in R2 also were observed (data not shown).
To determine if the new copies actually resulted from retrotransposition and not from DNA rearrangements, the sequences flanking five new copies were recovered using inverse PCR. As shown in Table 4, the five new copies had short or long 5' deletions, were terminated by poly(A) tails of variable lengths, and were flanked by direct repeats of different lengths, indicating the formation of target-site duplications. These three features have been reported extensively for mammalian L1 element retrotransposition (Luan et al., 1993 ; Ostertag and Kazazian, 2001) and indicate that the new copies of Karma indeed resulted from retrotranspositional events.
Karma Transcription Is Insufficient for Transposition The transcription of Karma in regenerated plants and cultured cells was analyzed by RT-PCR (Figure 6A). Whereas Karma was not transcribed in leaves of normal plants, transcription was detected in leaves of regenerated plants. Transcription also was observed in cells cultured for 1 month to 4 years. The fact that Karma retrotransposition was not observed even though it was transcribed suggests that transcription is insufficient for the retrotransposition of Karma. This also was the case for R0 plants, in which transcription, but not retrotransposition, was detected (data not shown).
Karma Is Hypomethylated in Cultured Cells and Regenerated Plants Karma methylation levels were examined by DNA gel blot analysis using the methylation-sensitive HpaII and the methylation-insensitive MspI restriction enzymes. HpaII does not cleave methylated CCGG sequences, whereas its isoschizomer, MspI, cleaves C5mCGG but not 5mCCGG sequences. Correlating with transcription, Karma methylation levels in cultured cells and regenerated plants were lower than those in wild-type plants (Figure 6B). In wild-type plants, the fragment of Karma hybridized by probe A was not digested with HpaII, indicating that Karma is methylated under normal conditions. A slight decrease in methylation levels was observed in cells cultured for 1 month. In cells cultured for 5 months, 2 years, and 4 years, methylation levels decreased considerably. Hypomethylation of Karma also was observed in lineages of regenerated plants from different generations, indicating that Karma was not subject to de novo methylation in them.
Karma Retrotransposition Continues through Several Generations Although LINE elements are found in the genomes of several plant species, evidence of recent retrotransposition was not observed previously. We demonstrated that Karma transcription is activated by tissue culture and that Karma retrotransposes continuously in regenerated plants. Unlike plant retrotransposons reported to date, the transcription of Karma is not silenced after activation, and hypomethylated states persist through several generations. Although the precise mechanisms of the epigenetic regulation of transposons in general remain unclear, mobilization often is associated with hypomethylation and transcriptional activation (Hirochika et al., 2000 ; Lindroth et al., 2001; Tompa et al., 2002). Recently, it was demonstrated that short interfering RNAs derived from retroelements are found in wild-type Arabidopsis and tobacco plants and that long short interfering RNAs are correlated specifically with retroelement DNA methylation but not with mRNA degradation (Hamilton et al., 2002; Llave et al., 2002; Zilberman et al., 2003). We observed an inverse correlation between Karma methylation and mRNA levels. However, whether Karma methylation prevents transcription or RNA degradation sets Karma methylation in wild-type plants, and the specific effect of tissue culture in these processes, remain to be determined.
The persistence of Karma hypomethylation through generations may result from the low activity of plant de novo methyltransferases (Vongs et al., 1993
Regulation of Karma Retrotransposition
In the case of Karma, we showed that transcripts were not detected in leaves of wild-type plants but were observed in cultured cells and leaves of regenerated plants. Therefore, although we did not analyze the transcription of Karma in other tissues of wild-type plants, the suppression of transcription or the degradation of transcripts might be the first stage in the regulation of Karma retrotransposition. However, transcription is required but is insufficient for the retrotransposition of Karma, because new copies were not detected in cultured cells or in the R0 generation of regenerated plants despite the fact that transcripts were observed. Therefore, post-transcriptional regulation may prevent additional steps of Karma retrotransposition. Evidence of transcription but no recent integration has been reported for some LTR and SINE retrotransposons (Bi and Laten, 1996
Plant Materials and Cell Culture Regenerated rice (Oryza sativa) plants were obtained from 18 independent transgenic callus lineages that were transformed and cultivated as described previously (Izawa et al., 1991 ; Hiei et al., 1994; Nakagawa et al., 2002).
DNA Extraction and DNA Gel Blot Analysis
Characterization of Karma Copies by Inverse PCR
Ligated DNA was subjected to PCR using the following primer pairs: 5'-CGCATTCTCACTAACCTCCATG-3' and 5'-GATGTGATTGCCATGTTGGAG-3' (full-length 5' flanks); 5'-AGGAGATTGTCAGCGAGAAGTG-3' and 5'-GATGTGATTGCCATGTTGGAG-3' (5' truncated 5' flanks); and 5'-CGGACAGCATAGTGTTGTGTTG-3' and 5'-GAATGTTGTTGTGGTTTGCAATG-3' (3' flanks). The full-length Karma copies of japonica and javanica cultivars were amplified using primers JP1 and JP2 (5'-TAGCTCCGAAAGCAACTACAGAG-3' and 5'-CAGGCAGGAACTGAGGAAAG-3', respectively) and JV1 and JV2 (5'-TGAGAAGGCCTTCTTCCTTTG-3' and 5'-TACGAGTATGCAGATGGCCC-3', respectively). PCR samples of 20 µL contained 0.5 units of ExTaq DNA polymerase (Takara Bio), 1x PCR reaction buffer (Takara Bio), 0.2 mM of each deoxynucleotide triphosphate, 10 µM of each primer, 4% DMSO, and
DNA Sequence Analysis
Mapping and Basic Local Alignment Search Tool Analysis
RNA Isolation and Reverse Transcription PCR Analysis Upon request, materials integral to the findings presented in this publication will be made available in a timely manner to all investigators on similar terms for noncommercial research purposes. To obtain materials, please contact J. Kyozuka, akyozuka{at}mail.ecc.u-tokyo.ac.jp.
Accession Numbers
We are grateful to T. Ishii for providing DNA samples and seeds of rice cultivars and accessions and to N. Okada for assistance with the phylogenetic analysis. We thank J. Finnegan for critical reading of the manuscript and M. Nobuhara and Y. Satake for technical assistance. M.K. was supported by a Japan Society for the Promotion of Science Research Fellowship for Young Scientists.
Article, publication date, and citation information can be found at www.plantcell.org/cgi/doi/10.1105/tpc.011809.
1 Current address: Department of Agricultural and Environmental Biology, Graduate School of Agricultural and Life Sciences, University of Tokyo, Bunkyo, Tokyo 113-8657, Japan. Received March 12, 2003; accepted May 25, 2003.
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TOP
ABSTRACT
INTRODUCTION
30 ng of genomic DNA. PCR conditions included an initial step at 94°C for 2 min, 30 cycles of amplification (30 s at 94°C, 30 s at 60°C, and 2 min at 72°C), and a final step at 72°C for 5 min. 
