Transnuclear retrotransposition of the Tad element of Neurospora

The Influence of LINE-1 and SINE Retrotransposons on Mammalian Genomes

Transposable elements have had a profound impact on the structure and function of mammalian genomes. The retrotransposon Long INterspersed Element-1 (LINE-1 or L1), by virtue of its replicative mobilization mechanism, comprises ∼17% of the human genome. Although the vast majority of human LINE-1 sequences are inactive molecular fossils, an estimated 80-100 copies per individual retain the ability to mobilize by a process termed retrotransposition. Indeed, LINE-1 is the only active, autonomous retrotransposon in humans and its retrotransposition continues to generate both intra-individual and inter-individual genetic diversity. Here, we briefly review the types of transposable elements that reside in mammalian genomes. We will focus our discussion on LINE-1 retrotransposons and the non-autonomous Short INterspersed Elements (SINEs) that rely on the proteins encoded by LINE-1 for their mobilization. We review cases where LINE-1-mediated retrotransposition events have resulted in genetic disease and discuss how the characterization of these mutagenic insertions led to the identification of retrotransposition-competent LINE-1s in the human and mouse genomes. We then discuss how the integration of molecular genetic, biochemical, and modern genomic technologies have yielded insight into the mechanism of LINE-1 retrotransposition, the impact of LINE-1-mediated retrotransposition events on mammalian genomes, and the host cellular mechanisms that protect the genome from unabated LINE-1-mediated retrotransposition events. Throughout this review, we highlight unanswered questions in LINE-1 biology that provide exciting opportunities for future research. Clearly, much has been learned about LINE-1 and SINE biology since the publication of Mobile DNA II thirteen years ago. Future studies should continue to yield exciting discoveries about how these retrotransposons contribute to genetic diversity in mammalian genomes.

Retrohoming of a Mobile Group II Intron in Human Cells Suggests How Eukaryotes Limit Group II Intron Proliferation

Mobile bacterial group II introns are evolutionary ancestors of spliceosomal introns and retroelements in eukaryotes. They consist of an autocatalytic intron RNA (a “ribozyme”) and an intron-encoded reverse transcriptase, which function together to promote intron integration into new DNA sites by a mechanism termed “retrohoming”. Although mobile group II introns splice and retrohome efficiently in bacteria, all examined thus far function inefficiently in eukaryotes, where their ribozyme activity is limited by low Mg²⁺ concentrations, and intron-containing transcripts are subject to nonsense-mediated decay (NMD) and translational repression. Here, by using RNA polymerase II to express a humanized group II intron reverse transcriptase and T7 RNA polymerase to express intron transcripts resistant to NMD, we find that simply supplementing culture medium with Mg²⁺ induces the Lactococcus lactis Ll.LtrB intron to retrohome into plasmid and chromosomal sites, the latter at frequencies up to ~0.1%, in viable HEK-293 cells. Surprisingly, under these conditions, the Ll.LtrB intron reverse transcriptase is required for retrohoming but not for RNA splicing as in bacteria. By using a genetic assay for in vivo selections combined with deep sequencing, we identified intron RNA mutations that enhance retrohoming in human cells, but <4-fold and not without added Mg²⁺. Further, the selected mutations lie outside the ribozyme catalytic core, which appears not readily modified to function efficiently at low Mg²⁺ concentrations. Our results reveal differences between group II intron retrohoming in human cells and bacteria and suggest constraints on critical nucleotide residues of the ribozyme core that limit how much group II intron retrohoming in eukaryotes can be enhanced. These findings have implications for group II intron use for gene targeting in eukaryotes and suggest how differences in intracellular Mg²⁺ concentrations between bacteria and eukarya may have impacted the evolution of introns and gene expression mechanisms.

Mobile group II introns are bacterial retrotransposons that are evolutionary ancestors of spliceosomal introns and retroelements in eukaryotes. They consist of an autocatalytic intron RNA (a ribozyme) and an intron-encoded reverse transcriptase, which together promote intron mobility to new DNA sites by a mechanism called retrohoming. Although found in bacteria, archaea and eukaryotic organelles, group II introns are absent from eukaryotic nuclear genomes, where host defenses impede their expression and lower intracellular Mg²⁺ concentrations limit their ribozyme activity. Here, we developed a mobile group II intron expression system that bypasses expression barriers and show that simply adding Mg²⁺ to culture medium enables group II intron retrohoming into plasmid and chromosomal target sites in human cells at appreciable frequencies. Genetic selections and deep sequencing identified intron RNA mutations that moderately enhance retrohoming in human cells, but not without added Mg²⁺. Thus, low Mg²⁺ concentrations in human cells are a natural barrier to efficient retrohoming that is not readily overcome by mutational variation and selection. Our results have implications for group II intron use for gene targeting in higher organisms and highlight the impact of different intracellular environments on intron evolution and gene expression mechanisms in bacteria and eukarya.

A yeast model for target-primed (non-LTR) retrotransposition

Background

Target-primed (non-LTR) retrotransposons, such as the human L1 element, are mobile genetic elements found in many eukaryotic genomes. They are often present in large numbers and their retrotransposition can cause mutations and genomic rearrangements. Despite their importance, many aspects of their replication are not well understood.

Results

We have developed a yeast model system for studying target-primed retrotransposons. This system uses the Zorro3 element from Candida albicans. A cloned copy of Zorro3, tagged with a retrotransposition indicator gene, retrotransposes at a high frequency when introduced into an appropriate C. albicans host strain. Retrotransposed copies of the tagged element exhibit similar features to the native copies, indicating that the natural retrotransposition pathway is being used. Retrotransposition is dependent on the products of the tagged element's own genes and is highly temperature-regulated. The new assay permits the analysis of the effects of specific mutations introduced into the cloned element.

Conclusion

This Zorro3 retrotransposition assay system complements previously available target-primed retrotransposition assays. Due to the relative simplicity of the growth, manipulation and analysis of yeast cells, the system should advance our understanding of target-primed retrotransposition.

L1 retrotransposition in nondividing and primary human somatic cells

Whether long interspersed element-1 (L1 or LINE-1) retrotransposition can occur in quiescent, nondividing, and/or terminally differentiated somatic cells has remained an unanswered fundamental question in human genetics. Here, we used a ubiquitously active phosphoglycerate kinase-1 promoter to drive the expression of a highly active human L1 element from an adenovirus-L1 hybrid vector. This vector system achieved retrotransposition in up to 91% of actively growing immortalized cells, and we demonstrated that L1 retrotransposition can be suppressed by the reverse transcriptase inhibitor 3'-azido-3'-deoxythymidine. This adenovirus vector enabled efficient delivery of the L1 element into differentiated primary human somatic cells and G1/S-arrested cells, resulting in retrotransposition in both cases; however, it was not detected in G0-arrested cells. Thus, these data indicate that L1 retrotransposition can occur in nondividing somatic cells.

Genome evolution mediated by Ty elements in Saccharomyces

How mobile genetic elements molded eukaryotic genomes is a key evolutionary question that gained wider popularity when mobile DNA sequences were shown to comprise about half of the human genome. Although Saccharomyces cerevisiae does not suffer such "genome obesity", five families of LTR-retrotransposons, Ty1, Ty2, Ty3, Ty4, and Ty5 elements, comprise about 3% of its genome. The availability of complete genome sequences from several Saccharomyces species, including members of the closely related sensu stricto group, present new opportunities for analyzing molecular mechanisms for chromosome evolution, speciation, and reproductive isolation. In this review I present key experiments from both the pre- and current genomic sequencing eras suggesting how Ty elements mediate genome evolution.

Transposable elements in filamentous fungi

The past 10 years have been productive in the characterization of fungal transposable elements (TEs). All eukaryotic TEs described are found including an extraordinary prevalence of active members of the pogo family. The role of TEs in mutation and genome organization is well documented, leading to significant advances in our perception of the mechanisms underlying genetic changes in these organisms. TE-mediated changes, associated with transposition and recombination, provide a broad range of genetic variation, which is useful for natural populations in their adaptation to environmental constraints, especially for those lacking the sexual stage. Interestingly, some fungal species have evolved distinct silencing mechanisms that are regarded as host defense systems against TEs. The examination of forces acting on the evolutionary dynamics of TEs should provide important insights into the interactions between TEs and the fungal genome. Another issue of major significance is the practical applications of TEs in gene tagging and population analysis, which will undoubtedly facilitate research in systematic biology and functional genomics.

Large scale analysis of sequences from Neurospora crassa

After 50 years of analysing Neurospora crassa genes one by one large scale sequence analysis has increased the number of accessible genes tremendously in the last few years. Being the only filamentous fungus for which a comprehensive genomic sequence database is publicly accessible N. crassa serves as the model for this important group of microorganisms. The MIPS N. crassa database currently holds more than 16 Mb of non-redundant data of the chromosomes II and V analysed by the German Neurospora Genome Project. This represents more than one-third of the genome. Open reading frames (ORFs) have been extracted from the sequence and the deduced proteins have been annotated extensively. They are classified according to matches in sequence databases and attributed to functional categories according to their relatives. While 41% of analysed proteins are related to known proteins, 30% are hypothetical proteins with no match to a database entry. The entire genome is expected to comprise some 13000 protein coding genes, more than twice as many as found in yeasts, and reflects the high potential of filamentous fungi to cope with various environmental conditions.

Transplantation of target site specificity by swapping the endonuclease domains of two LINEs

Long interspersed elements (LINEs) are ubiquitous genomic elements in higher eukaryotes. Here we develop a novel assay to analyze in vivo LINE retrotransposition using the telomeric repeat-specific elements SART1 and TRAS1. We demonstrate by PCR that silkworm SART1, which is expressed from a recombinant baculovirus, transposes in Sf9 cells into the chromosomal (TTAGG)n sequences, at the same specific nucleotide position as in the silkworm genome. Thus authentic retrotransposition by complete reverse transcription of the entire RNA transcription unit and occasional 5' truncation is observed. The retrotransposition requires conserved domains in both open reading frames (ORFs), including the ORF1 cysteine- histidine motifs. In contrast to human L1, recognition of the 3' untranslated region sequence is crucial for SART1 retrotransposition, which results in efficient trans-complementation. Swapping the endonuclease domain from TRAS1 into SART1 converts insertion specificity to that of TRAS1. Thus the primary determinant of in vivo target selection is the endonuclease domain, suggesting that modified LINEs could be used as gene therapy vectors, which deliver only genes of interest but not retrotransposons themselves in trans to specific genomic locations.

Elimination of active tad elements during the sexual phase of the Neurospora crassa life cycle

Tad is an active LINE-like retrotransposon isolated from the Adiopodoumé strain of Neurospora crassa. Extensive analysis of other Neurospora strains has revealed no other strain with active Tad, but all strains tested have multiple copies of defective Tad elements. We have examined the ability of Tad to survive during the sexual cycle of Neurospora and find that active Tad is rapidly eliminated. The characteristics of this elimination suggest that the repeat-induced point mutation (RIP) mechanism was responsible. By the use of transformation to switch the mating type of the Adiopodoumé strain we concluded that this strain is not defective in the RIP process. Analysis of defective Tad elements isolated from a variety of strains indicates that the major difference between these elements and active Tad is due to the presence of a large number of G-C to A-T transition mutations. This would be expected if the changes were due primarily to the RIP process. Mapping of a selection of defective Tad elements reveals that they are present on all of the chromosomes; however, many of the elements are not widely shared among strains. This suggests that repeated introduction and elimination of Tad elements has occurred. Mechanisms that might be responsible for this repeated introduction are discussed.

Transposition of the retrotransposon MAGGY in heterologous species of filamentous fungi

MAGGY is a gypsy-like LTR retrotransposon isolated from the blast fungus Pyricularia grisea (teleomorph, Magnaporthe grisea). We examined transposition of MAGGY in three P. grisea isolates (wheat, finger millet, and crabgrass pathogen), which did not originally possess a MAGGY element, and in two heterologous species of filamentous fungi, Colletotrichum lagenarium and P. zingiberi. Genomic Southern analysis of MAGGY transformants suggested that transposition of MAGGY occurred in all filamentous fungi tested. In contrast, no transposition was observed in any transformants with a modified MAGGY containing a 513-bp deletion in the reverse transcriptase domain. When a MAGGY derivative carrying an artificial intron was introduced into the wheat isolate of P. grisea and C. lagenarium, loss of the intron was observed. These results showed that MAGGY can undergo autonomous RNA-mediated transposition in heterologous filamentous fungi. The frequency of transposition differed among fungal species. MAGGY transposed actively in the wheat isolate of P. grisea and P. zingiberi, but transposition in C. lagenarium appeared to be rare. This is the first report that demonstrates active transposition of a fungal transposable element in heterologous hosts. Possible usage of MAGGY as a genetic tagging tool in filamentous fungi is discussed.

Target site selection in transposition

Transposable elements are discrete mobile DNA segments that can insert into non-homologous target sites. Diverse patterns of target site selectivity are observed: Some elements display considerable target site selectivity and others display little obvious selectivity, although none appears to be truly "random." A variety of mechanisms for target site selection are used: Some elements use direct interactions between the recombinase and target DNA whereas other elements depend upon interactions with accessory proteins that communicate both with the target DNA and the recombinase. The study of target site selectivity is useful in probing recombination mechanisms, in studying genome structure and function, and also in providing tools for genome manipulation.

Error-prone retrotransposition: rime of the ancient mutators

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Epigenetic control of a transposon-inactivated gene in Neurospora is dependent on DNA methylation

An unstable allele of the Neurospora am (GDH) gene resulting from integration of the retrotransposon Tad3-2 into 5' noncoding sequences was found in previous work. We report that reversion to Am+ depends on DNA methylation within and upstream of Tad. Levels of methylation were correlated with the proportion of Am+ conidia, whether the cultures were derived from Am- or Am+ isolates. Reversion to Am+ did not occur when conidia were plated on 5-azacytidine, which reduces DNA methylation. The mutation dim-2, which appears to abolish DNA methylation, also prevented reversion to Am+. The native am allele, in a strain that lacked Tad elements, was replaced with am::Tad3-2 or with a deletion derivative that prevents transposition of Tad. Transformants of both classes showed instability comparable with that of the original isolates, which contain multiple Tad elements. Deletion of the upstream enhancer-like sequences, URSam alpha and beta, did not prevent the instability of am::Tad3-2. The results suggest that am expression is dependent on DNA methylation but not on proliferation or transposition of the Tad element and that the instability does not require the upstream sequences of am.

Identification and cloning of a mobile transposon from Aspergillus niger var. awamori

Aspergillus niger var. awamori contains multiple copies of a transposable element, Vader. This element was detected as a 437-bp insertion in four independently isolated spontaneous mutants of the niaD (nitrate reductase) gene. The Vader element is present in approximately 15 copies in both A. niger var. awamori and A. niger. A single copy of Vader was detected from only one of the two laboratory strains of A. nidulans which were also examined. Insertion of the Vader element into the niaD gene of A. niger var. awamori caused a 2-bp duplication (TA) of the target sequence. The Vader element is flanked by a 44-bp inverted repeat. The genetic stabilities of the inserted Vader elements at niaD were examined by studying reversion frequencies resulting in colonies able to grow on nitrate as a sole nitrogen source. Mutants niaD392 and niaD436 reverted at a frequency of 9x10(-3) and 4x10(-2), respectively. Two of the mutants, niaD587 and niaD410, reverted at a lower frequency of 6x10(-4).

Structure, inheritance, and transcriptional effects of Pce1, an insertional element within Phanerochaete chrysosporium lignin peroxidase gene lipI

A 1747-bp insertion within a lignin peroxidase allele of Phanerochaete chrysosporium BKM-F-1767 is described. Pce1, the element, lies immediately adjacent to the fourth intron of lip12. Southern blots reveal the presence of Pce1-homologous sequences in other P. chrysosporium strains. Transposon-like features include inverted terminal repeats and a dinucleotide (TA) target duplication. Atypical of transposons, Pce1 is present at very low copy numbers (one to five copies), and conserved transposase motifs are lacking. The mutation transcriptionally inactivates lip12 and is inherited in a 1:1 Mendelian fashion among haploid progeny. Thus, Pce1 is a transposon-like element that may play a significant role in generating ligninolytic variation in certain P. chrysosporium strains.

Guest: a 98 bp inverted repeat transposable element in Neurospora crassa

The region immediately 3' of histidine-3 has been cloned and sequenced from two laboratory strains of the ascomycete fungus Neurospora crassa; St Lawrence 74A and Lindegren, which have different derivations from wild collections. Amongst the differences distinguishing these sequences are insertions ranging in size from 20 to 101 bp present only in St Lawrence. The largest of these is flanked by a 3 bp direct repeat, has terminal inverted repeats (TIR) and shares features with several known transposable elements. At 98 bp, it may be the smallest transposable element yet found in eukaryotes. There are multiple copies of the TIR in the Neurospora genome, similar but not identical to the one sequenced. PCR amplification of Neurospora genomic DNA, using 26 bp of the TIR as a single primer, gave products of discrete sizes ranging from 100 bp to about 1.3 kb, suggesting that the element isolated (Guest) may be a deletion derivative of a family of larger transposable elements. Guest appears to be the first transposable element reported in fungi that is not a retrotransposon.

The Neurospora transposon Tad is sensitive to repeat-induced point mutation (RIP)

RIP (repeat-induced point mutation) efficiently mutates repeated sequences in the sexual phase of the Neurospora crassa life cycle. Nevertheless, an active LINE-like retrotransposon, Tad, was found in a N. crassa strain from Adiopodoumé. The possibility was tested that Tad might be resistant to RIP, or that the Adiopodoumé strain might be incompetent for RIP. Tad elements derived from the Adiopodoumé strain were found to be susceptible to RIP. In addition, strains lacking active Tad elements, including common laboratory strains and strains representing seven species of Neurospora, were found to have sequences closely related to Tad but with numerous mutations of the type resulting from RIP (G:C to A:T). Even the Adiopodoumé strain showed Tad-like elements with mutations characteristic of RIP. Results of crossing of an Adiopodoumé transformant with progeny of Adiopodoumé suggest that the Adiopodoumé strain is proficient at RIP. We conclude that Tad is an old transposable element that has been inactivated by RIP in most strains. Finding relics of RIP in both heterothallic and homothallic species of Neurospora implicates RIP across the genus.

Tad1-1, an active LINE-like element of Neurospora crassa

Tad is a LINE-like retrotransposon of Neurospora crassa. The element was originally detected and cloned using the am gene as a transposon trap in hybrid strains derived from a cross of Adiopodoume (a wild collected strain) and a laboratory strain devoid of Tad elements. We report the cloning and sequencing of an active Tad element, Tad1-1, which is capable of independent transposition. Transposition was demonstrated by screening for transfer of the element from a donor nucleus that contained the Tad1-1 element as the only active Tad, into a naive nucleus within a forced heterokaryon. We also report here the sequence analysis of Tad1-1, and its comparison with the sequence of another active element, Tad3-2. These elements are approximately 7 kb in length. They contain two long open reading frames (ORFs) encoded on the strand of the same polarity as the full-length transcript. ORF1 encodes a putative protein of 486 amino acids. Homology to the first ORF of other LINE elements is confined to three cysteine-rich motifs, located near the carboxy-terminus, that are thought to be involved in binding nucleic acids. The second ORF is 1156 amino acids in length and shows homology to the reverse transcriptase domains of various retroviruses and retrotransposons. Tad1-1 and Tad3-2 differ in only ten positions over their whole length.

The Doc transposable element in Drosophila melanogaster and Drosophila simulans: genomic distribution and transcription

The mobile element Doc is similar in structure and coding potential to the LINE families found in various organisms. In this paper, we analyze the insertional and structural polymorphism of this element and show that it appears to have a long evolutionary history in the genome of D. melanogaster. Like the family of I elements, the Doc family seems to display three types of elements: full length elements, defective members that have recently transposed and long since immobilized members common to each D. melanogaster strain. These three classes of Doc elements seem to be present in D. simulans, a closely related species to D. melanogaster. Furthermore, we show that Doc is transcribed as a polyadenylated RNA of about 5 kb in length, presumed to be a full length RNA. This transcript is present in different tissues and at different stages of Drosophila development. These results are compared with previous records on the chromosomal distribution of LINEs or other transposable element families. Doc transcription is analyzed in an attempt to understand the link between Doc transcription and transposition.