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Plant transposable elements: where genetics meets genomics.
Author: C. Feschotte
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"REVIEWS Transposable elements (TEs) are fragments of DNA that can insert into new chromosomal locations and often make duplicate copies of themselves in the process. With the advent of large-scale DNA sequenc- ing, it has become apparent that, far from being a rare component of some genomes, TEs are the single largest component of the genetic material of most eukaryotes. They account for at least 45% of the human genome 1 and 50?80% of some grass genomes 2?4 . TEs were discovered in maize by Barbara McClintock more than a half century ago as the genetic agents that are responsible for the sectors of altered pig- mentation on mutant kernels 5 . This discovery and the ensuing characterization of the genetic properties of TEs led to her being awarded a Nobel Prize in 1983, after TEs had been documented in the genomes of Drosophila melanogaster, yeast (Saccharomyces cerevisiae), Escherichia coli, Caenorhabditis elegans and humans (reviewed in REF. 6). The maize kernel was ideal for analysing the inter- play of TEs with host genes. An example of a TE- induced mutant phenotype is shown in FIG. 1. Most of what was known about TEs before their molecular char- acterization came from the analysis of similar unstable phenotypes that are expressed in the aleurone layer of the kernel, a single-cell-thick layer that is derived from the underlying starchy ENDOSPERM and that is the site of pigment biosynthesis. TE-induced alleles of several genes in the anthocyanin (pigment) biosynthetic path- way give rise to distinct patterns with respect to the size, frequency and intensity of sectors (reviewed in REF. 7). Mutant alleles such as these provided the raw material for molecular biologists to isolate active TEs from the maize genome. As discussed in this review, active elements com- prise only a tiny fraction of the TE complement of the genomes of maize and of most other multicellular organisms. However, the genomes of higher eukary- otes are filled with thousands, even millions, of seem- ingly inactive TEs. In the absence of a mutation caused by a TE insertion, the task of determining whether a particular TE is active, inactive or EPIGENETI- CALLY silenced presents a new challenge to those studying eukaryotic TEs. In response to this chal- lenge, various protocols have been developed to analyse TEs on a whole-genome basis rather than one at a time. Some of these protocols are described in this review in the context of analysing two types of TEs that are present in very high copy number in plants: miniature inverted-repeat transposable ele- ments (MITEs) and long terminal repeat (LTR) retrotransposons. Circumstantial evidence is rapidly accumulating that plant genomes are remarkably dynamic, largely due to the activity of TEs. Paradoxically, however, the high-copy-number ele- ments that so dramatically contribute to genome evolution at both the interspecific and intraspecific levels seem to be transpositionally inactive. We con- clude the review by describing recent studies that offer the promise of reactivating these sleeping giants so that they can be characterized to the same extent as the TEs first described by McClintock. PLANT TRANSPOSABLE ELEMENTS: WHERE GENETICS MEETS GENOMICS C�dric Feschotte, Ning Jiang and Susan R. Wessler Transposable elements are the single largest component of the genetic material of most eukaryotes. The recent availability of large quantities of genomic sequence has led to a shift from the genetic characterization of single elements to genome-wide analysis of enormous transposable-element populations. Nowhere is this shift more evident than in plants, in which transposable elements were first discovered and where they are still actively reshaping genomes. ENDOSPERM A triploid nutritive tissue in flowering plants. EPIGENETIC Any heritable change in gene expression that is not caused by a change in DNA sequence. NATURE REVIEWS | GENETICS VOLUME 3 | MAY 2002 | 329 Departments of Plant Biology and Genetics, The University of Georgia, Athens, Georgia 30602, USA. Correspondence to S.R.W. e-mail: sue@dogwood.botany.uga. edu DOI: 10.1038/nrg793 � 2002 Macmillan Magazines Ltd 330 | MAY 2002 | VOLUME 3 www.nature.com/reviews/genetics REVIEWS Whereas unstable mutant alleles yielded class 2 TEs, the cloning of mutations that are responsible for stable mutant alleles in maize led to the isolation of some of the first plant examples of another TE class ? LTR retrotransposons (BOX 1b). In these studies, five distinct LTR retrotransposons (Bs1, Stonor, Magellan, Hopscotch and B5/G;see TABLE 1) were recovered from eight mutant alleles 12?14 . A common feature of all mutagenic TEs (both class 2 elements and LTR retrotransposons) was their rela- tively low copy number (<100 copies overall) in their host genome. This was unexpected in the light of ear- lier investigations, which showed, using renaturation kinetics, that highly repetitive DNA predominated in plant and animal genomes 15,16 . What was the nature of the repetitive DNA, if not these mutagenic TEs? One clue came from the analysis of repetitive DNA in humans, in which two TE families, L1 and Alu,were found to be present at very high copy number 17 . L1 and Alu are members of large groups called long inter- spersed nuclear elements (LINEs) and short inter- spersed nuclear elements (SINEs), respectively, and are classified as non-LTR retrotransposons (BOX 1c). Together, these two families make up more than one- quarter of the human genome 1 . LINEs and SINEs are also present in plant genomes, where they have attained very high copy numbers in some species 18,19 (TABLE 1). However, analyses of the growing database of plant genomic sequence soon revealed that plant genomes harbour a huge diversity of TEs, and that two types ? MITEs and LTR retrotransposons ? have made important and recent contributions to plant genome organization and evolution. For this reason, these two elements are the focus of the rest of this review. MITEs: origin and amplification A decade ago, the results of computer-assisted searches for repeated DNA sequences showed that small, non- autonomous elements called MITEs predominate in the non-coding regions of grass genes 20?22 . These ele- ments were structurally reminiscent of active class 2 non-autonomous elements, with their small size (less than 600 bp) and terminal inverted repeats (BOX 1a). However, their high copy number, target-site prefer- ence (TA or TAA) and the uniformity of related ele- ments distinguished them from the previously described class 2 elements 23 . After their discovery in plants, MITE families were found in several animal genomes, including C. elegans 24 , mosquitoes 25?27 , fishes 28 , Xenopus 29 and humans 30,31 . The abundance of MITEs (and of DNA trans- posons in general) in the gene-rich regions of plant genomes was confirmed after the analysis of the com- plete genome sequence of Arabidopsis (which contains ~1,200 MITEs and ~1,000 other DNA transposons, together constituting ~6% of the genome 32 ) and the partial genome sequence of rice (~100,000 MITEs and ~10,000 other DNA transposons, forming ~12% of the genome 33,34 ; N.J., C.F. and S.R.W., unpublished observations). Characterizing one element at a time The first element that was recognized to be transposable was a site of chromosome breakage in maize and, as such, was named Dissociation (Ds). Ds could transpose or break chromosomes only in the presence of another genetic locus, called Activator (Ac), which could also pro- mote its own transposition. Together, Ac and Ds consti- tute a TE family that includes autonomous (Ac) and non-autonomous (Ds) elements (for a review, see REF. 8). Similar TE families were later found to underlie unstable mutant phenotypes in other plants (for example, snapdragon, petunia, soybean and sorghum) and in animals (such as Drosophila and C. elegans). All were DNA or class 2 elements (BOX 1a). This group is distinguished by terminal inverted repeats (TIRs) and transposition through a DNA intermediate, in which the element usually excises from one site and reinserts elsewhere in the genome (reviewed in REFS 6,9). The analysis of complex and diverse mutant phenotypes that are induced by insertion and excision of class 2 elements into plant genes revealed a myriad of ways that these elements can modify gene regulation. These include that genes or regulatory regions sustain inser- tions of transposon footprints (a few extra base pairs) that are usually left behind when elements excise; that some non-autonomous elements function as introns; and that insertions in promoters or other regulatory sequences can alter tissue-specific patterns of expres- sion (for reviews, see REFS 7,10,11). Small spots: frequent excision late in kernel development Large spot: excision early in kernal development No excision, autonomous element not in genome Revertant: element excised, expression restored No product Activator Excision of TE in somatic cells = spot in germ cells = revertant TE Pigment gene Figure 1 | Using kernel phenotypes to study transposon behaviour. Kernels on a maize ear show unstable phenotypes due to the interplay between a transposable element (TE) and a gene that encodes an enzyme in the anthocyanin (pigment) biosynthetic pathway. Sectors of revertant (pigmented) aleurone tissue result from the excision of the TE in a single cell. The size of the sector reflects the time in kernel development at which excision occurred. An understanding of the genetic basis of this and similar mutant phenotypes led to the discovery of TEs and to an amazingly detailed description of the behaviour of what we now call class 2 (DNA) elements (see main text for details). � 2002 Macmillan Magazines Ltd NATURE REVIEWS | GENETICS VOLUME 3 | MAY 2002 | 331 REVIEWS This situation has changed markedly in the past few years, as MITE classification and relationships with transposases have become established. First, most of the tens of thousands of MITEs in plant genomes can now be divided into two groups ? Tourist-like MITEs and Stowaway-like MITEs ? on the basis of the simi- larity of their TIRs and target-site duplications (TSDs) 23,33?35 . Second, two approaches have been used to establish relationships between each group and newly discovered plant-transposase families (reviewed in REF. 36). We call these the ?bottom-up? and ?top-down? approaches, as the former uses the MITE sequence to identify the partner transposase, whereas the latter con- nects an active source of transposase to a MITE family. Although descriptions of MITE families have proliferated in the literature, their origin and mecha- nism of transposition have remained mysterious. Two main obstacles were initially encountered in attempts to classify MITEs with respect to existing transposons. First, none of the available MITE sequences revealed clear-cut relationships with TEs that encode known transposases (autonomous elements). Second, and perhaps more significantly, no MITE family has been shown to be actively trans- posing. In the absence of coding sequences and activ- ity, it has been difficult to determine how MITEs originate and how they attain their high copy numbers. Box 1 | Structural features and classification of plant transposable elements Eukaryotic transposable elements (TEs) are divided into two classes according to whether their transposition intermediate is RNA (class 1) or DNA (class 2). For all class 1 elements, it is the element-encoded transcript (mRNA), and not the element itself (as with class 2 elements), that forms the transposition intermediate. Each group of TEs contains autonomous and non-autonomous elements. Autonomous elements have open reading frames (ORFs; red boxes) that encode the products required for transposition. Non-autonomous elements that are able to transpose have no significant coding capacity but retain the cis-sequences necessary for transposition. Integration of almost all TEs results in the duplication of a short genomic sequence at the site of insertion. These target-site duplications (arrows flanking the element) are variable in size and/or sequence among TE superfamilies and families. Several examples of plant TEs are given in TABLE 1. Class 2 elements DNA transposons (a) have terminal inverted-repeat (black triangles) and target-site (arrows) duplications of conserved length (and sometimes sequence) in superfamilies (for example, 8 bp for hAT; TA for Tc1/mariner). Non-autonomous family members are usually derived from an autonomous family member by internal deletion. Class 1 elements Class 1 elements can be divided into two groups on the basis of transposition mechanism and structure. LTR retrotransposons (b) have long terminal repeats (LTRs) in direct orientation (black triangles). Autonomous elements contain at least two genes, called gag and pol. The gag gene encodes a capsid-like protein and the pol gene encodes a polyprotein that is responsible for protease, reverse transcriptase, RNase H and integrase activities. Non-autonomous elements lack most or all coding sequence 87?89 . Their internal region (green boxes) can be variable in size and unrelated to the autonomous element (for an example, see REF. 88). Non-LTR retrotransposons (c) are divided into long interspersed nuclear elements (LINEs) and short interspersed nuclear elements (SINEs). Coding regions include: ORF1,a gag-like protein; EN, endonuclease; and RT, reverse transcriptase. Both LINEs and SINEs terminate by a simple sequence repeat, usually poly(A). All SINEs described so far are characterized by an internal RNA pol III promoter (black stripes) near the 5? end. The 3? half of SINEs is of unknown origin, but the extreme 3? tail of some SINEs share homology with the 3? tail of LINEs present in the same genome. This indicates that SINEs could parasitize the transposition machinery of partner LINEs 90 . Recent studies have determined that previously described high-copy-number repeats in the genomes of Arabidopsis (~2% of the genome), rice and Caenorhabditis elegans belong to a new type of TE. Elements called Helitrons are unique in structure and are mostly represented by non-autonomous copies. Helitrons have been classified as class 2 elements because putative autonomous elements show structural and sequence similarities with bacterial rolling-circle transposons 91 . Helitrons are not discussed further in this review because additional data, beyond their initial discovery, has not been reported. a DNA transposons Autonomous elements Transposase DNA-mediated TEs (class 2) RNA-mediated TEs (class 1) Non-autonomous elements c Non-LTR retrotransposons ORF1 EN RT b LTR retrotransposons gag pol LINEs SINEs pol III (A) n (A) n trse � 2002 Macmillan Magazines Ltd 332 | MAY 2002 | VOLUME 3 www.nature.com/reviews/genetics REVIEWS Top-down approach. A different method was used to reveal the origin and transposase source of Tourist-like elements, the other principal MITE superfamily in plants. The top-down approach used in the discovery of the transposase source began with the fortuitous discovery that a genetically active DNA transposon family in maize (called PIF; P instability factor 39 ) is related in sequence to a vast group of Tourist-like MITEs (called mPIF; minia- ture PIF 40 ). PIF and mPIF have identical 14-bp TIRs and similar subterminal sequences (~70% identity over ~100 bp at each end), and have the same target-site pref- erence for the 9-bp palindrome CWCTTAGWG (in which W stands for either A or T). Whereas the extent of sequence similarity alone indicates that mPIF was proba- bly derived from the active PIF element or from a closely related element, their identical, extended target sites pro- vided the strongest evidence that both elements were mobilized by the same or a related transposase 40 . This transposase was identified through the isolation of an ele- ment (called PIFa) that co-segregated with PIF activity 40 . Bottom-up approach. This method relies completely on the vast amount of DNA sequence generated by genome projects and the development of database search tools (TABLE 2) to identify potentially autonomous family mem- bers that are related to MITE sequences. In the simplest case, a MITE shares sequence similarity over its entire length with a larger, transposase-encoding element. This situation indicates that MITEs, like previously described non-autonomous DNA elements, originate from autonomous elements. In other cases, sequence similarity between the MITE and a DNA transposon is restricted to their TIRs and TSDs (see REF. 36 for further discussion). The bottom-up approach has revealed complex rela- tionships between dozens of MITE families and the well-characterized Tc1/mariner superfamily of trans- posases 24,31,36,37 . Although Tc1/mariner transposons were thought to be rare in plants, recent studies indicate that they are widespread in plant genomes, in which they have given rise to a large fraction of plant MITEs, including those of the Stowaway superfamily 33,37,38 . Table 1 | Examples of transposable elements in plants Class/subclass/ Species Autonomous Non-autonomous Copy number References superfamily member(s) member(s) of the entire family* Class 1 Non-LTR retrotransposons LINEs; L1 clade Z. mays Cin4 ? 50?100 98 L. speciosum Del2 ? ? 250,000 19 A. thaliana Tal1 ? ?1?6 9 SINEs N. tabacum ? TS 50,000 18 B. napus ? S1 500 100 LTR retrotransposons copia-like N. tabacum Tnt1A ? >100 50 N. tabacum Tto1 ? 30 (300) 60 Hordeum sp. BARE-1 ? 5,000?22,000 3 O. sativa Tos17 ? 2?5 (30) 61 Z. mays Hopscotch ? 5?8 101 Z. mays Opie-2 ? ? 100,000 4 Z. mays ? BS1 1?5 87 gypsy-like Z. mays Magellan ? 4?8 102 Z. mays Huck-2 ? ? 200,000 4 O. sativa RIRE2 ? Dasheng 1,200 88 A. thaliana Athila 4 ? ?22 85 A. thaliana Athila 6 ? ?11 A. thaliana Ta3 ? 1 103 A. thaliana Tar17 ?2 60 Class 2 DNA transposons hAT Z. mays Ac Ds 50?100 7 CACTA Z. mays Spm dSpm 50?100 104 A. thaliana CAC1 CAC2 4 (20) 83 Mutator Z. mays MuDR Mu1 10?100 105 A. thaliana AtMu1 ? 1 (4) 82 PIF/Harbinger Z. mays PIFa mPIF 6,000 40 Angiosperms PIF-like Tourist-like Variable 40,41 Tc1/mariner Angiosperms MLEs Stowaway-like Variable 33,38 *Copy numbers are approximate; those in parentheses result from transpositional activation in cell culture (Tos17 and Tto1) or in mutant backgrounds (CAC and AtMu1). ? Copies identified so far seem to be full-length, but do not contain an intact open reading frame. Ac, Activator; Ds, Dissociation; LINE, long interspersed nuclear element; LTR, long terminal repeat; MLE, mariner-like element; mPIF, miniature P instability factor; PIF, P instability factor; SINE, short interspersed nuclear element; Spm, Suppressor?Mutator. Species names: A. thaliana, Arabidopsis thaliana; B. napus, Brassica napus; L. speciosum, Lilium speciosum; N. tabacum, Nicotiana tabacum; O. sativa, Oryza sativa; Z. mays, Zea mays. � 2002 Macmillan Magazines Ltd NATURE REVIEWS | GENETICS VOLUME 3 | MAY 2002 | 333 REVIEWS The high sequence identity observed for many MITE families indicates that these families might have spread recently throughout their respective host genomes. Consistent with this view is the fact that MITE insertion sites are frequently polymorphic with respect to their presence or absence at a particular locus between indi- viduals of the same species 21,22,35,45,46 . Because MITE excisions seem to be extremely rare, MITE insertion polymorphisms have been successfully exploited as genetic markers in maize and rice 46?48 . MITEs are known to be preferentially located in the vicinity of genes. Many examples have been docu- mented of MITE insertion polymorphisms in promot- ers, introns or 3? flanking sequences among ORTHOLOGOUS and PARALOGOUS genes (for example, REFS 20?22,28,29,35,45). Hence, MITEs are an important factor in creating struc- tural allelic diversity. One challenge for the future will be to determine whether, and how frequently, the sequence diversity created by MITE insertions has altered gene expression or gene products. LTR retrotransposons in plant-genome evolution Whereas MITEs are the predominant TE in or near plant genes, one of the surprising findings of the past decade has been that LTR retrotransposons, which are located largely in intergenic regions, are the single largest component of most plant genomes 49 . LTR retro- transposons are members of the retroelement or class 1 family, which also includes retroviruses, LINEs and SINEs (BOX 1b). For all class 1 elements, it is the element- encoded transcript (mRNA), and not the element itself (as with class 2 elements), that forms the transposition intermediate (for a review, see REF. 9). LTR retrotransposons were first discovered in plants as sources of both spontaneous and induced mutations in maize and tobacco 12,13,50 . As with the active class 2 ele- ments that are responsible for unstable mutations, the mutagenic LTR retrotransposons are members of low to moderately repetitive element families 4,50?52 . For exam- ple, the Bs1 element, which was first detected as an insertion in the alcohol dehydrogenase1 gene (adh1), is present in only 1?5 copies in the maize genome 12 . The discovery of PIFa in maize led to the recognition of a new superfamily of transposases, called PIF/Harbinger 40 . These transposases are probably of ancient origin as they are distantly related to bacterial IS5 transposases, and have been identified in a wide range of eukaryotes, including various flowering plants, a fungus and nematodes 40,41 . Once PIF-like DNA elements were uncovered in the genomic sequences of rice, Arabidopsis and nematodes, it was not difficult to identify their asso- ciated Tourist-like MITEs by searching their respective genomic sequences for non-autonomous members 40,42 . Origin and amplification. On the basis of these recent data, a model for the origin and amplification of MITEs has been proposed 36 (FIG. 2). In this model, MITEs are seen as non-autonomous elements that originated from DNA transposons in a two-step process. First, transposi- tion of an autonomous element gives rise to various, internally deleted, non-autonomous derivatives (FIG. 2). This step is very likely to be dependent on transposase and has been observed for other class 2 families, such as Ac/Ds or P-elements 43,44 . In a second step, it is proposed that some derivatives can (for unknown reasons) amplify to high copy numbers. The very high copy numbers attributed to many MITE families might actually result from independent amplifications of different subfamilies in the same genome (diversification step in FIG. 2). This is best seen in rice, in which Stowaway MITEs account for more than 2% of genomic DNA, but can in fact be divided into more than 35 different but related subfamilies. Only a small number of these subfamilies have attained copy numbers that are significantly greater than 2,000 (N.J., C.F. and S.R.W., unpublished data). A complex subfamily structure is also observed for Tourist MITEs (which make up ~3% of the rice genome). Accordingly, each Stowaway and Tourist MITE subfamily probably arose from the activity of related, but distinct, mariner- like and PIF-like autonomous elements, respectively. This hypothesis is supported by the recent discovery that rice and other plant genomes contain a tremendous diversity of mariner-like and PIF-like transposases 38,40 . ORTHOLOGOUS GENES Homologous genes that originated through speciation (for example, human and mouse ?-globin). PARALOGOUS GENES Homologous genes that originated by gene duplication (for example, human ?-globin and ?-globin). Table 2 | Examples of programs used for mining transposable elements in DNA sequences Type of search Application Advantages and drawbacks Programs URL or reference Homology based Query* versus Primarily for masking � ? All repeats processed with one search CENSOR http://www.girinst.org/ database ? and annotating ? A known repeat library required Censor_Server.html repetitive sequences ? Only elements with sequence similarity RepeatMasker http://repeatmasker.genome. to known elements will be identified washington.edu Query* versus For recovering all types ? No previous knowledge about TEs Miropeats 106 query of repetitive sequences in the query are needed REPuter 107 ? Computationally intensive RECON http://www.genetics.wust.edu/ ? Further classification required eddy/recon Structure based Designed to find MITEs ? Fast processing but only elements Find-MITE http://www.biochem.vt.edu/ by searching IRs flanked with defined features will be found aedes by TSDs of defined length and/or sequence *Query refers to sequence of interest. ? Database refers to an existing repeat database such as Repbase 108 (http://www.girinst.org). � Sequences of repeats identified in the query are replaced by N or X; in this way, they will be ignored in subsequent sequence analyses. IR, inverted repeat; MITE, miniature inverted-repeat transposable element; TE, transposable element; TSD, target-site duplication. � 2002 Macmillan Magazines Ltd 334 | MAY 2002 | VOLUME 3 www.nature.com/reviews/genetics REVIEWS genome consists of LTR retrotransposons 34 ), to maize (~2,800 Mb, 50?80% retrotransposons 2,4 ) and barley (~4,800 Mb, >70% retrotransposons 3 ). Two studies in particular have raised the bar on our concept of the dynamic genome and have posi- tioned the grass clade as a focal point for future stud- ies. In a classic study, Jeff Bennetzen and co-workers 55 analysed a 280-kb region around the maize adh1 gene and found that nested LTR retrotransposons accounted for most of this sequence. This clustering of LTR retrotransposons in intergenic regions was shown to be representative of the rest of the genome. Their initial observation was dramatically followed up with the demonstration that bursts of LTR retrotrans- poson activity have doubled the maize genome within the past 6 million years (Myr) 56 . The temporal com- ponent to their analysis was made possible by exploit- ing the fact that the LTRs of a single element are iden- tical on insertion. By comparing the two LTR sequences of a single element, they were able to esti- mate the insertion time (FIG. 3). This result showed for the first time that TEs could rapidly restructure a genome. It has been known since the late 1980s, however, that both LTR and non-LTR retrotransposons can attain phe- nomenally high copy numbers in plant species that have large genomes (for a review, see REF. 49). The incredible potential of amplification through retrotransposition in plants was first illustrated by studies on members of the genus Lilium. The 14 species that were surveyed have enormous genomes of 30,000?45,000 Mb, the size of which seems to result from massive amplification of retrotransposons 19,53 . An important series of recent studies has shown that differential amplification of LTR retrotrans- posons largely accounts for the ?C-value paradox? among the agronomically important members of the grass clade. The C-value paradox is the observed lack of correlation between increases in DNA content and the complexity of an organism 54 . This paradox has been documented for both plant and animal species, but so far seems to be ?solved? only for members of the grass family. In this family, the fraction of the genome contributed by LTR retrotransposons increases with genome size from rice, the smallest characterized grass genome (~15% of its 430-Mb ABORTIVE GAP REPAIR The double-stranded DNA break left at the site of excision of a class 2 transposon is repaired by the host machinery (gap repair). This gap is sometimes repaired by making an identical copy of the excised transposon, using the element still present on the sister chromatid or the homologous chromosome as a template. The process can be incomplete due to slippage and mispairing events. Such aberrant repairs are commonly responsible for the origin of an internally deleted copy of the excised transposon. Ancestor: autonomous TE Diversification Autonomous transposon Few copies Internal deletion derivatives Few copies Variable size MITEs Many copies Conserved size T MITE subfamily MITE family T T T Transposition and abortive gap repair MITE amplification Cross-mobilization? cis- mobilization trans-mobilization Figure 2 | Model for the origin and amplification of MITEs. In this model, the accumulation of miniature inverted-repeat transposable elements (MITEs) within a genome is explained by the activity of numerous related, but distinct, autonomous elements (shown in different colours). Related autonomous elements arise from a single ancestral element, but have diversified to the point at which they only share sequence similarity in their terminal inverted repeats (TIRs; black triangles) and transposase gene (boxes, in darker colour). The activity of each element, mediated by its transposase (circled T), is proposed to form non-autonomous derivatives through mechanisms such as ABORTIVE GAP REPAIR 43,44 . The subsequent amplification of one or a few deletion derivatives gives rise to a group of homogeneous non-autonomous elements (that is, a MITE subfamily). This step is likely to be mediated by the same transposase or one that is produced by a close relative (?trans-? or ?cross-mobilization?, respectively). See text and REF. 36 for further discussion of the model. TE, transposable element. � 2002 Macmillan Magazines Ltd NATURE REVIEWS | GENETICS VOLUME 3 | MAY 2002 | 335 REVIEWS Transcriptional activation of LTR retrotransposons. Some LTR retrotransposons that are largely inactive during development can be transcriptionally activated and transpose under conditions of biotic and abiotic stress. The first active plant retrotransposon, Tnt1, was isolated from tobacco by selecting for insertions into the previously cloned nitrate reductase (NR) gene; these insertions were identified by the chlorite-resistant phe- notype that is characteristic of NR-deficient cells or plants. Screening millions of plants for such a rare event is physically impossible. Instead, Grandbastien et al. 50 used microbiological techniques to screen millions of PROTOPLASTS (which can be routinely regenerated into healthy tobacco plants) for the chlorite-resistant pheno- type. It turned out that Tnt1 transcription (which is necessary to produce the transposition intermediate, mRNA) is largely quiescent during normal develop- ment, but was fortuitously activated when exposed to the fungal extract used to degrade the cell wall to make protoplasts 59 . Subsequent to this pioneering study, two additional tobacco elements, Tto1 and Tto2, and a rice element, Tos17, were isolated using a simpler reverse- transcription PCR protocol that was devised to amplify a conserved reverse transcriptase domain in mRNAs that were isolated during cell culture 60,61 . So far, tobacco retrotransposons Tnt1 and Tto1 have been shown to be activated by various abiotic and biotic stresses, including wounding, oxidative stress, pathogen infection and microbial elicitors (reviewed in REFS 49,62). The restricted transcription of LTR retrotransposons in plants is also illustrated by their under-representation in expressed sequence tag (EST) collections. A recent analysis of 407,000 maize ESTs revealed that only 56 are derived from LTR retrotransposons 4 . Furthermore, most of these sequences are derived from the low-to- middle repetitive LTR retrotransposons, and not from the very high copy number elements (including Huck-2, ~200,000 copies, and Opie-2, ~100,000 copies) that have been responsible for doubling the size of the maize genome in the past 5?6 million years 4,56 . Transcription of LTR retrotransposons does not necessarily correlate with new insertions in the genome (transposition). The replication cycle for LTR retro- transposons includes four steps: transcription, transla- tion, reverse transcription and integration of element cDNA. Regulation at any of these steps can limit the transposition rate. For example, transcripts of the yeast Ty1 retrotransposon are abundant, but new insertions are extremely rare, largely because only one Ty1 cDNA, on average, is made for every 14,000 Ty1 transcripts 63 . The limited data on the activity of plant LTR retro- transposons indicate that transposition is regulated pri- marily at the level of transcription initiation 64 .After stress-induced transcription, the genomic copy num- ber of the rice LTR retrotransposon Tos17 increased from 2 to more than 30 copies in some strains, as mea- sured by Southern blots 61 . The relatively high copy number of Tnt1 in the tobacco genome (>100 copies per haploid genome, before induction) 50 precluded the use of Southern blots to assess whether transcriptional activation led to an increase in genomic copy number. In a second study, Kalendar et al. presented a striking example of TE-mediated genome restructuring in pop- ulations of the wild barley Hordeum spontaneum 57 .In this case, genome restructuring takes the form of pro- nounced intraspecific genome size variation due to amplification of the BARE-1 LTR retrotransposon. The copy number of BARE-1 among nearby populations that are subjected to different levels of water stress var- ied between 8,300 and 22,100, corresponding to 1.8?4.7% of the nuclear DNA 57 . The correlation between BARE-1 copy number, genome size and local environmental conditions indicated that a mechanistic connection might exist between the amplification of a particular TE and the adaptive evolution of its host. Plant TEs: so many elements, so little activity The phylogenetic analysis of human TEs has revealed that marked amplification ceased almost 35?50 Myr ago 1 . (For a description of some of the methods available for reconstructing TE phylogenies, see BOX 2.) It is, there- fore, not surprising that, despite comprising almost 45% of the genome (more than 1,200 Mb), only a handful of human TEs remain active. For example, only 30?60 L1 elements out of 500,000 in this LINE family are thought to be active at present 1,58 . By contrast, the comparative analysis of closely related plant genomes (particularly those of the grasses) has revealed that TE amplification is responsible for a large fraction of the variation in genome size at both interspecific and intraspecific lev- els 2,57 . Such circumstantial evidence for massive TE activ- ity in the recent past might lead one to expect that active TEs (especially active LTR retrotransposons) ? the ?smoking guns? of transposition ? could be routinely isolated from plants. In this regard, it is paradoxical that so few active retroelements have been identified. Here, we address this issue by turning our attention to the reg- ulation of TE activity in plant genomes. PROTOPLAST A cell after the removal of its cell wall. Time (Myr) 0 1 2 3 4 5 % similarity LTR?LTR 100 90 80 70 Nested LTR retrotransposons Figure 3 | Estimating the time of retrotransposon insertion. At the time of insertion, the long terminal repeats (LTRs) of an element are identical because both are copied from the same template during cDNA synthesis. As time passes, nucleotide changes accumulate in each LTR (represented by vertical bars in the LTRs). If the average rate of nucleotide substitution per year is known for the host organism, then sequence divergence between the LTRs provides an estimate of when insertion occurred. This method has been applied to date the insertions of LTR retrotransposons nested in the intergenic regions that surround the maize alcohol dehydrogenase1 (adh1) gene 56 . See text for details. Myr, million years. � 2002 Macmillan Magazines Ltd 336 | MAY 2002 | VOLUME 3 www.nature.com/reviews/genetics REVIEWS way, Melayah et al. 64 showed that 38 out of 41 new DNA bands corresponded to de novo insertions of Tnt1. It is clear from this study that transposon display is a powerful technique to detect activity among mod- erate and highly repetitive TE families. Furthermore, Instead, a technique known as ?transposon display? (also called sequence-specific amplification polymor- phism, or S-SAP 65 ) was used to resolve PCR products that were derived from Tnt1 insertions from tobacco genomic DNA before and after induction (FIG. 4). In this Box 2 | Phylogenetic analyses of transposable elements Access to the genomic sequence of an organism offers unprecedented opportunities to study the evolutionary history of the full transposable element (TE) complement. Many sequence-analysis and phylogenetic programs are freely available on the internet (for a recent compilation, see link to Sue Wessler?s lab). Two examples are presented that illustrate some of these procedures and their application to the study of TEs. A third is shown in FIG. 3. Panel a shows a whole-genome phylogenetic analysis of the Arabidopsis Ty3/gypsy superfamily of LTR retrotransposons (reproduced with permission from REF. 85 � (2002) Cold Spring Harbor Laboratory Press). This phylogenetic tree was constructed from a multiple alignment of all 191 Ty3/gypsy reverse transcriptase (RT) amino-acid sequences in the Arabidopsis genome (available at http://www.public.iastate.edu/~voytas). The topology of the tree emphasizes: first, the heterogeneity of RT sequences, as reflected by the length of the main branches; second, the clustering of related elements into monophyletic groups that define distinct families (for example, Ta t or Athila) and subfamilies (for example, Ta t 4 or Athila5); third, the replicative and explosive nature of the transposition process, as revealed by the presence of several subfamilies of highly homogeneous sequence (small groups with very short branch lengths, such as Athila4); and fourth, the tempo and succession of family and subfamily amplification. For example, groups with short branch lengths are likely to have been amplified more recently than those with longer branch lengths (for example, the Athila4 subfamily was amplified more recently than Athila5). Panel b illustrates how an active transposase can be reconstructed on the basis of phylogenetic analyses of a subset of inactive TE copies. This approach has been used successfully to reconstruct autonomous elements of the Tc1/mariner superfamily 92,93 . A schematic alignment of transposase sequences cloned from a given organism (1?9) and the deduced consensus sequence (C) are shown. After insertion, transposase genes usually evolve as pseudogenes, quickly accumulating substitutions and insertions or deletions. Substitutions might introduce amino-acid changes (coloured squares) or stop codons (grey triangles). This can result in a disrupted open reading frame (ORF) and/or an inactive transposase. The consensus sequence is deduced from a simple majority rule from a multiple alignment of several copies and is likely to reflect the ancestral, active sequence of an element. A consensus transposase sequence can be experimentally reconstructed, expressed and tested in vitro and in vivo for each of the steps of a ?cut-and-paste? transposition event 93 , including: transport into the nucleus mediated by the nuclear localization signal (NLS); sequence-specific binding to the substrate DNA as mediated by the DNA binding domain (DB); and excision and integration of transposon DNA as mediated by the catalytic domain of the transposase (CAT). Other recent examples of computer-assisted and phylogenetic approaches to study the structural evolution and population dynamics of TEs can be found in REFS 1,32,94?97. Classic group 0.05 changes Tat group Athila group Tma3-1 Tat4-1 Athila5 Athila7 Athila8 Athila8 Athila4 Athila6 Athila1 a b 1 2 3 4 5 6 7 8 9 C ? ? ? ? + + ? + ? + DB NLS CAT ORF ? + + ? ? + + ? ? + DB + + + ? ? + ? + ? + NLS ? ? ? ? ? ? ? ? ? + CAT � 2002 Macmillan Magazines Ltd NATURE REVIEWS | GENETICS VOLUME 3 | MAY 2002 | 337 REVIEWS activity of some family members 66,67 . A very close rela- tive of BARE-1 (based on sequence identity) is OARE-1, a Ty1/copia LTR element in oat, with a copy number of at least 10,000 per haploid genome 68 . The recent demonstration that OARE-1 transcription is activated by biotic and abiotic stress 68 indicates that amplification of this element is responsive to environmental condi- tions. Unfortunately, new insertions have not yet been detected for either the BARE-1 or OARE-1 family. However, this probably reflects the difficulty that is inherent in distinguishing de novo insertion events from the background of existing BARE-1 or OARE-1 inser- tions. Techniques such as transposon display might prove valuable in detecting such ?needles in a haystack?. Epigenetic silencing of transposable elements. The para- dox of plant TE activity is dramatically illustrated in the ability to identify newly transposed elements (by cutting out and re-amplifying bands) will allow the identification of the few active elements in a large TE family and the recovery of flanking sequences for the analysis of target-site preferences. To understand the impact of retrotransposition on plant genome evolution, it will be necessary to identify active members of families that are present in very high copy numbers. Among the characterized elements, only two related families offer the promise of activity at pre- sent: BARE-1 and OARE-1. As mentioned above, the copy number of BARE-1 shows remarkable variation among species in the genus Hordeum and among popu- lations of the wild barley species Hordeum sponta- neum 3,57 . In addition, the detection of BARE-1 tran- scripts and virus-like particles is consistent with the Biotic and/or abiotic stress a b c EcoR I RNA AAA Tnt1 EcoR I gag pol EcoR I gag pol EcoR I EcoR I gag pol gag pol Integration into genome Digest genomic DNA and ligate adaptors PCR amplification (one or two rounds) 1234567 Amplified product Figure 4 | Detection of new genomic insertions by transposon display. The transposon-display technique for detecting new transposable element (TE) insertions is illustrated through the use of an example of stress-induced mobilization of the Tnt1 retrotransposon in tobacco. a | The isolation of protoplasts from tobacco leaf cells activates a stress response that induces transcription of the Tnt1 LTR retrotransposon. Induction might be mediated by the binding of a transcriptional activator to a cis-motif (yellow box) in the LTR 62 . Some Tnt1- encoded mRNAs are converted into double-stranded cDNAs that integrate into the tobacco genome. b | The transposon- display protocol begins with the digestion of genomic DNA with a restriction enzyme (here EcoRI). Most of the thousands of restriction fragments do not have TE insertions. Adaptors (pink boxes) are ligated to all fragments and the mixture is used as template for one (as shown) or two (not shown) round(s) of PCR amplification, using primers that are complementary to subterminal TE sequences (arrows). c | New integration events appear as additional bands (red arrows) on an autoradiograph of a transposon-display gel of genomic DNA. In this example, DNA was isolated from tobacco plants either before treatment (lanes 1,6) or after regeneration from protoplasts (lanes 2?5,7). (Photo of gel courtesy of M.-A. Grandbastien, Laboratoire de Biologie Cellulaire, Institut National de la Recherche Agronomique, Versailles, France.) � 2002 Macmillan Magazines Ltd 338 | MAY 2002 | VOLUME 3 www.nature.com/reviews/genetics REVIEWS a hallmark of actively transcribed and transposing class 2 elements. Hypermethylation is also associated with the intergenic clusters of LTR retrotransposons in maize. These regions, which make up at least 50% of the maize genome, are highly condensed and thought to comprise a transcriptionally repressive chromatin environment 4,55 . Although subsequent studies have shown that DNA methylation is required for the normal development of mammals and plants 74,75 , its precise role and origin are the subject of speculation. One hypothesis, originally formulated by Bestor for mammals 76 and Flavell for plants 77 , is that epigenetic mechanisms of gene regula- tion have evolved as a host defence to regulate the spread of invasive DNA, including TEs and viruses. Studies of plant TE methylation were put on the back burner as the attention of researchers turned to the host genes that are involved in the initiation and maintenance of epigenesis. The study of transgene silencing and viral resistance in plants and of TE regulation in animals led to the identification of two distinct epigenetic mechanisms, known as post-transcriptional gene silencing (PTGS) and transcriptional gene silencing (TGS). In PTGS (a process also referred to as co-suppression and related to RNA interference in animals), TE silencing is caused by maize, where the genome has recently doubled in size through transposition, but not a single active LTR retro- transposon has been identified. Furthermore, the paucity of maize retrotransposon-derived ESTs (REF. 4) indicates that some mechanisms, most likely epigenetic, might have been remarkably effective at repressing the transcription of a large fraction of the genome. The existence of epigenetic mechanisms to repress TEs goes back to the genetic analysis of unstable muta- tions in maize. McClintock documented examples of what she called ?changes in phase?, which were heritable and reversible (epigenetic) changes in the activity of Ac and Spm (Suppressor?Mutator) elements 69,70 . Characterization of the active and inactive phases of another maize TE family, Mutator, provided the first molecular evidence that the activity of members of this family correlated with methylation of cytosine residues 71 . Similar changes in methylation states were also shown to be associated with Ac and Spm elements that are under- going phase changes 72,73 . In all cases, genetically inactive elements were hypermethylated (especially at their ter- mini, where the transposase promoter resides in the autonomous family members) relative to their active counterparts, whereas hypomethylation was found to be Transcriptional silencing (TGS) Post-transcriptional silencing (PTGS) Nucleus Cytoplasm Readthrough transcription RNA RNA?RNA pairing AAA AAA DNA?DNA pairing? RNA?DNA pairing? RNA?protein interactions? + + + + DNA methylation Chromatin remodelling RNA degradation RNase (e.g. MUT-7) RdRP Methyltranferases (e.g. MET1) Chromomethylases (e.g. CMT3) SWI2/SNF2 chromatin- remodelling factors (e.g. DDM1, MOM) Protein kinases (e.g. MUT9p) Polycomb ? group proteins? RNA AAA AAA dsRNA 21?25-nt siRNA ? DICER RNA helicases (e.g. MUT6p, MUT-7, spn-E) Figure 5 | Epigenetic silencing of transposable elements. The figure emphasizes the role of host-encoded proteins in transcriptional gene silencing (TGS) and post-transcriptional gene silencing (PTGS) as revealed by mutant analysis (see TABLE 3), and the possible triggers of TE silencing (depicted by sirens). A key determinant for the activation of both TGS and PTGS is the multiple copies of identical or nearly identical TE sequences in the genome. TGS of TEs might be triggered by direct TE?TE interactions, as shown. So far, only TGS has been shown to regulate plant TEs, for which it is associated with the methylation of TE promoters. In PTGS, silencing is caused by sequence-specific degradation of RNAs in the cytoplasm. PTGS is triggered by double- stranded (ds)RNA produced by the pairing of sense and antisense RNAs or from RNAs that contain an inverted repeat (not shown). Antisense RNAs can be produced by readthrough transcription of a TE from an adjacent host gene. Formation of dsRNA might also involve RNA-dependent RNA polymerases (RdRP), as has been shown for the silencing of transgenes and plant viruses. dsRNA is degraded into 21?25-nucleotide (nt) small interfering RNAs (siRNAs) by an enzymatic complex that includes DICER-like proteins and RNA helicases. These small RNAs might act as guides for RNA degradation by RNase(s). siRNAs or dsRNAs might also enter the nucleus and mediate de novo methylation of transgenes, possibly through RNA?DNA interactions 80 . RNA-directed methylation occurs along the DNA regions that are complementary with the guide RNAs. It has been proposed that dsRNAs derived from TE promoters could promote methylation and TGS of TEs 80 . Examples of TEs known to be the targets of either TGS and/or PTGS mechanisms are listed in TABLE 3. CMT3, chromomethylase 3; DDM1, decreased DNA methylation 1; MET1, methyltransferase 1; MOM, Morpheus? molecule; spn-E, spindle E. � 2002 Macmillan Magazines Ltd NATURE REVIEWS | GENETICS VOLUME 3 | MAY 2002 | 339 REVIEWS of the elements. The DDM1 gene encodes a protein with strong similarity to SWI2/SNF2 chromatin-remodelling factors 86 . These results indicate a possible functional link between chromatin remodelling, DNA methylation and genome integrity. Reactivation of DNA transposons in the ddm1 mutant background might have a direct impact on host fitness, as the reactivated TEs have been found to insert into coding and regulatory sequences of genes 82,83 . It is likely that many of the developmental abnormalities that were observed in ddm1 plants were induced by the movement of reactivated transposons. Future directions: waking the sleeping giant TEs were first discovered and studied as the causative agents of genetically unstable mutations in maize. Many of these mutations had, in fact, been isolated from mutag- enized plants or in strains undergoing the BREAKAGE?FUSION?BRIDGE CYCLE. It has been proposed that these, and similar treatments, activated previously quies- cent elements that were normal residents of the genome 8 . The recent demonstration that Arabidopsis TEs can be reactivated in genetic backgrounds that are deficient in aspects of epigenetic regulation brings this story full- circle and promises to revolutionize the study of TEs, especially in plants that have large genomes. As discussed above, circumstantial evidence strongly implicates the involvement of high-copy-number TEs, such as MITEs and LTR retrotransposons, in the recent restructuring of many plant genomes. However, current activity of these high-copy-number elements, as measured by new inser- tions in the genome, has not been documented. It is pos- sible that these elements were activated along with the class 2 elements described above. However, given their degradation of their RNAs. In TGS, TEs are transcrip- tionally repressed (FIG. 5;see TABLE 3 for references). The current model for how TE RNA is specifically recognized and degraded in PTGS is briefly described in FIG. 5. So far, PTGS has been found to regulate the activ- ity of TEs in animals that lack (extensive) DNA methy- lation (for example, C. elegans and D. melanogaster) and in the green alga Chlamydomonas reinhardtii. Although PTGS has been well documented in plants, most notably as a defence against viral replication 78 ,TGS seems to be the principal pathway to silence plant TEs 79 (FIG. 5;see TABLE 3 for references). Of course, this does not rule out the possibility that TGS and PTGS might overlap and combine to regulate some plant TEs (for further discussion, see REFS 79?81). As mentioned above, the methylation of TE sequences (especially the promoter of transposase genes) correlates with TE inactivation in maize. Similarly, the methylation of transgene promoter sequences correlates with TGS in plants 79 . Therefore, it is not surprising that recent experiments have shown that endogenous TEs can be activated in mutants that are impaired for the establishment and maintenance of TGS (FIG. 5).For example, in the Arabidopsis ddm1 (decreased DNA methylation 1) mutant, endogenous transposons of the Mutator and CACTA (En/Spm) superfamilies of class 2 elements are transcriptionally and transpositionally reac- tivated 82,83 . The endogenous retrotransposons Tar17, Athila4 and Athila5 were also transcriptionally reacti- vated in ddm1 backgrounds, but new insertions were not detected 84,85 . Plants that are homozygous for the ddm1 mutation have notably decreased CpG methylation. Consequently, the transcriptional derepression of TEs in the mutant strains was accompanied by demethylation BREAKAGE?FUSION?BRIDGE CYCLE In somatic cells, a cycle of chromosome breakage (at Ds, for example), DNA replication, chromatid fusion (forming a dicentric chromosome) and formation of a chromosome bridge occurs during mitotic anaphase. A new round follows when the chromosome breaks yet again as the two centromeres are pulled to opposite poles. Table 3 | Transposable-element targets of epigenetic gene silencing Species Protein Silenced transposable elements References involved Transcriptional gene silencing Arabidopsis thaliana DDM1 LTR retroelements Tar17* ? , Athila4,6 ? 84,85 DNA transposons AtMu1, CAC1,2* ?� 82,83 CMT3 LTR retroelements Ta3, Athila* ? 109,110 Non-LTR retrotransposon Tal1-like* 110 MET1 LTR retroelements Athila-like* ? 110,111 Non-LTR retrotransposon Tal1-like* 110 MOM1 LTR retroelements Athila-like ? 111,112 Chlamydomonas reinhardtii MUT9p LTR retrotransposon TOC1 ?� 81 DNA transposon Gulliver � 81 Post-transcriptional gene silencing Caenorhabditis elegans MUT-7 DNA transposons Tc1,3,4,5 � 113 Chlamydomonas reinhardtii MUT6p LTR retrotransposon TOC1 ?� 114 DNA transposon Gulliver � 114 Drosophila melanogaster Spn-E LTR retrotransposons 1731, mdg1 ? 115 Non-LTR retrotransposon F-element ? 115 ND Non-LTR retrotransposon I factor || 116 Trypanosoma brucei ND Non-LTR retrotransposons INGI, SLACS � 117 *Hypomethylation of the promoter region, ? transcriptional activation and � transpositional activation have been detected in mutant backgrounds; ?? homologous RNA-mediated silencing has been shown; � abundant 24?26-nucleotide RNAs that are homologous to these transposable elements have been cloned and detected by RNA blot analysis. CMT3, chromomethylase 3; DDM1, decreased DNA methylation 1; LTR, long terminal repeat; MET1, methyltransferase 1; MOM1, Morpheus? molecule; ND, not determined; Spn-E, spindle E. � 2002 Macmillan Magazines Ltd 340 | MAY 2002 | VOLUME 3 www.nature.com/reviews/genetics REVIEWS genomic DNA sequence from these species should be sufficient to identify high-copy-number TEs and to design family-specific primers for transposon display or genome-wide analysis of TE expression. In this way, it should be possible to isolate active TEs from a variety of plant species. Knowledge of these elements should greatly facilitate studies of the continuing co-evolution of TEs with their hosts. extremely high copy number, activation might have been lethal. Fortunately, modern assays to detect new TE insertions, such as transposon display using DNA from cultured cells, might offer an alternative way to identify elements that are still able to transpose. 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This paper and reference 81 show that the silencing of a DNA transposon and a LTR retrotransposon in Chlamydomonas involve enzymatic components of both PTGS and TGS, but do not seem to require DNA methylation. 115. Aravin, A. A. et al. Double-stranded RNA-mediated silencing of genomic tandem repeats and transposable elements in the D. melanogaster germline. Curr. Biol. 11, 1017?1027 (2001). 116. Jensen, S., Gassama, M. P. & Heidmann, T. Taming of transposable elements by homology-dependent gene silencing. Nature Genet. 21, 209?212 (1999). 117. Djikeng, A., Shi, H., Tschudi, C. & Ullu, E. RNA interference in Trypanosoma brucei: cloning of small interfering RNAs provides evidence for retroposon- derived 24?26-nucleotide RNAs. RNA 7, 1522?1530 (2001). Acknowledgements We thank members of the Wessler lab, Z. Bao and E. Pritham for suggestions on the manuscript and stimulating discussions, and H. Cerrutti, S. Eddy, M.-A. Grandbastien, R. Martienssen, J. Tu and D. Voytas for providing helpful information and unpublished data. This work was supported by grants from the National Science Foundation (Plant Genome Initiative), the National Institute of Health, the Department of Energy and the University of Georgia Research Foundation to S.R.W. Online links DATABASES The following terms in this article are linked online to: MaizeDB: http://www.agron.missouri.edu Ac | adh1 | Bs1 | Ds | Hopscotch | Huck-2 | Magellan | Mutator | Opie-2 | Spm | Stonor | Stowaway | Tourist The Arabidopsis Information Resource: http://www.arabidopsis.org ddm1 FURTHER INFORMATION Barbara McClintock: http://www.nobel.se/medicine/laureates/ 1983/mcclintock-autobio.html Encyclopedia of Life Sciences: http://www.els.net Repetitive DNA: evolution | Transposons; eukaryotic Sue Wessler?s lab: http://www.botany.uga.edu/wesslerlab Zhijiam Tu?s web page: http://www.biochem.vt.edu/aeo Access to this interactive links box is free online. � 2002 Macmillan Magazines Ltd "
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