Two distinct subforms of the retrotransposable DRE element in NC4 strains of Dictyostelium discoideum

Genetically tagged TRE5-A retrotransposons reveal high amplification rates and authentic target site preference in the Dictyostelium discoideum genome

Retrotransposons contribute significantly to the evolution of eukaryotic genomes. They replicate by producing DNA copies of their own RNA, which are integrated at new locations in the host cell genome. In the gene-dense genome of the social amoeba Dictyostelium discoideum, retrotransposon TRE5-A avoids insertional mutagenesis by targeting the transcription factor (TF) IIIC/IIIB complex and integrating ∼ 50 bp upstream of tRNA genes. We generated synthetic TRE5-A retrotransposons (TRE5-A(bsr)) that were tagged with a selection marker that conferred resistance to blasticidin after a complete retrotransposition cycle. We found that the TRE5-A(bsr) elements were efficiently mobilized in trans by proteins expressed from the endogenous TRE5-A population found in D. discoideum cells. ORF1 protein translated from TRE5-A(bsr) elements significantly enhanced retrotransposition. We observed that the 5' untranslated region of TRE5-A could be replaced by an unrelated promoter, whereas the 3' untranslated region of TRE5-A was essential for retrotransposition. A predicted secondary structure in the RNA of the 3' untranslated region of TRE5-A may be involved in the retrotransposition process. The TRE5-A(bsr) elements were capable of identifying authentic integration targets in vivo, including formerly unnoticed, putative binding sites for TFIIIC on the extrachromosomal DNA element that carries the ribosomal RNA genes.

Dictyostelium transfer RNA gene-targeting retrotransposons: Studying mobile element-host interactions in a compact genome

The model species of social amoebae, Dictyostelium discoideum, has a compact genome consisting of about two thirds protein-coding regions, with intergenic regions that are rarely larger than 1,000 bp. We hypothesize that the haploid state of D. discoideum cells provides defense against the amplification of mobile elements whose transposition activities would otherwise lead to the accumulation of heterozygous, potentially lethal mutations in diploid populations. We further speculate that complex transposon clusters found on D. discoideum chromosomes do not a priori result from integration preferences of these transposons, but that the clusters instead result from negative selection against cells harboring insertional mutations in genes. D. discoideum cells contain a fraction of retrotransposons that are found in the close vicinity of tRNA genes. Growing evidence suggests that these retrotransposons use active recognition mechanisms to determine suitable integration sites. However, the question remains whether these retrotransposons also cause insertional mutagenesis of genes, resulting in their enrichment at tRNA genes, which are relatively safe sites in euchromatic regions. Recently developed in vivo retrotransposition assays will allow a detailed, genome-wide analysis of de novo integration events in the D. discoideum genome.

The C-module-binding factor supports amplification of TRE5-A retrotransposons in the Dictyostelium discoideum genome

Retrotransposable elements are molecular parasites that have invaded the genomes of virtually all organisms. Although retrotransposons encode essential proteins to mediate their amplification, they also require assistance by host cell-encoded machineries that perform functions such as DNA transcription and repair. The retrotransposon TRE5-A of the social amoeba Dictyostelium discoideum generates a notable amount of both sense and antisense RNAs, which are generated from element-internal promoters, located in the A module and the C module, respectively. We observed that TRE5-A retrotransposons depend on the C-module-binding factor (CbfA) to maintain high steady-state levels of TRE5-A transcripts and that CbfA supports the retrotransposition activity of TRE5-A elements. The carboxy-terminal domain of CbfA was found to be required and sufficient to mediate the accumulation of TRE5-A transcripts, but it did not support productive retrotransposition of TRE5-A. This result suggests different roles for CbfA protein domains in the regulation of TRE5-A retrotransposition frequency in D. discoideum cells. Although CbfA binds to the C module in vitro, the factor regulates neither C-module nor A-module promoter activity in vivo. We speculate that CbfA supports the amplification of TRE5-A retrotransposons by suppressing the expression of an as yet unidentified component of the cellular posttranscriptional gene silencing machinery.

Transfer RNA gene-targeted integration: an adaptation of retrotransposable elements to survive in the compact Dictyostelium discoideum genome

Almost every organism carries along a multitude of molecular parasites known as transposable elements (TEs). TEs influence their host genomes in many ways by expanding genome size and complexity, rearranging genomic DNA, mutagenizing host genes, and altering transcription levels of nearby genes. The eukaryotic microorganism Dictyostelium discoideum is attractive for the study of fundamental biological phenomena such as intercellular communication, formation of multicellularity, cell differentiation, and morphogenesis. D. discoideum has a highly compacted, haploid genome with less than 1 kb of genomic DNA separating coding regions. Nevertheless, the D. discoideum genome is loaded with 10% of TEs that managed to settle and survive in this inhospitable environment. In depth analysis of D. discoideum genome project data has provided intriguing insights into the evolutionary challenges that mobile elements face when they invade compact genomes. Two different mechanisms are used by D. discoideum TEs to avoid disruption of host genes upon retrotransposition. Several TEs have invented the specific targeting of tRNA gene-flanking regions as a means to avoid integration into coding regions. These elements have been dispersed on all chromosomes, closely following the distribution of tRNA genes. By contrast, TEs that lack bona fide integration specificities show a strong bias to nested integration, thus forming large TE clusters at certain chromosomal loci that are hardly resolved by bioinformatics approaches. We summarize our current view of D. discoideum TEs and present new data from the analysis of the complete sequences of D. discoideum chromosomes 1 and 2, which comprise more than one third of the total genome.

Transfer RNA gene-targeted retrotransposition of Dictyostelium TRE5-A into a chromosomal UMP synthase gene trap

The genome of the eukaryotic microorganism Dictyostelium discoideum hosts a family of seven non-long terminal repeat retrotransposons (TREs) that show remarkable insertion preferences near tRNA genes. We developed an in vivo assay to detect tRNA gene-targeted retrotransposition of endogenous TREs in a reporter strain of D. discoideum. A tRNA gene positioned within an artificial intron was placed into the D. discoideum UMP synthase gene. This construct was inserted into the D. discoideum genome and presented as a landmark for de novo TRE insertions. We show that the tRNA gene-tagged UMP synthase gene was frequently disrupted by de novo insertions of endogenous TRE5-A copies, thus rendering the resulting mutants resistant to 5-fluoroorotic acid selection. Approximately 96% of all isolated 5-FOA-resistant clones contained TRE5-A insertions, whereas the remaining 4% resulted from transposition-independent mutations. The inserted TRE5-As showed complex structural variations and were found about 50 bp upstream of the reporter tRNA gene, similar to previously analysed genomic copies of TRE5-A. No integration by other members of the TRE family was observed. We found that only 51% of the de novo insertions were derived from autonomous TRE5-A.1 copies. The remaining 49% of new insertions were due to TRE5-A.2 elements, which lack the proteins required for reverse transcription and integration, but retain functional promoter sequences.

Skipper, an LTR retrotransposon of Dictyostelium

The complete sequence of a retrotransposon from Dictyostelium discoideum , named skipper , was obtained from cDNA and genomic clones. The sequence of a nearly full-length skipper cDNA was similar to that of three other partially sequenced cDNAs. The corresponding retrotransposon is represented in approximately 15-20 copies and is abundantly transcribed. Skipper contains three open reading frames (ORFs) with an unusual sequence organization, aspects of which resemble certain mammalian retroviruses. ORFs 1 and 3 correspond to gag and pol genes; the second ORF, pro, corresponding to protease, was separated from gag by a single stop codon followed shortly thereafter by a potential pseudoknot. ORF3 (pol) was separated from pro by a +1 frameshift. ORFs 2 and 3 overlapped by 32 bp. The computed amino acid sequences of the skipper ORFs contain regions resembling retrotransposon polyprotein domains, including a nucleic acid binding protein, aspartyl protease, reverse transcriptase and integrase. Skipper is the first example of a retrotransposon with a separate pro gene. Skipper is also novel in that it appears to use stop codon suppression rather than frameshifting to modulate pro expression. Finally, skipper and its components may provide useful tools for the genetic characterization of Dictyostelium.

A nuclear protein factor binds specifically to the 3'-regulatory module of the long-interspersed-nuclear-element-like Dictyostelium repetitive element

The Dictyostelium repetitive element DRE integrates in a position-specific manner upstream of tRNA genes in the Dictyostelium discoideum genome. DRE has structural similarities to the group of long interspersed nuclear elements, whose replication mechanism is poorly understood. The C-module at the 3' end of DRE encodes a regulatory cis-acting sequence that contains an RNA polymerase II promoter. This promoter directs the synthesis of RNAs that are thought to play a critical role in DRE transposition. In this study, we describe the identification of a nuclear protein factor that binds to the C-module in a sequence-specific manner. The C-module-binding factor (CMBF) recognizes three DNA sequence motifs that contain homopolymeric (dT) stretches of variable lengths, but does not bind to a standard RNA polymerase II promoter from D, discoideum. Analysis of highly CMBF-enriched fractions and glycerol gradient sedimentation of CMBF suggest that the factor exists as a monomeric 115-kDa protein. Possible roles of CMBF in DRE transposition are discussed.

Internally located and oppositely oriented polymerase II promoters direct convergent transcription of a LINE-like retroelement, the Dictyostelium repetitive element, from Dictyostelium discoideum

The Dictyostelium discoideum NC4 genome harbors approximately 150 individual copies of a retrotransposable element called the Dictyostelium repetitive element (DRE). This element contains nonidentical terminal repeats (TRs) consisting of conserved building blocks A and B in the left TR and B and C in the right TR. Seven different-sized classes of RNA transcripts from these elements were resolved by Northern (RNA) blot analysis, but their combined abundance was very low. When D. discoideum cells were grown in the presence of the respiratory chain blocker antimycin A, steady-state concentrations of these RNA species increased 10- to 20-fold. The D. discoideum genome contains two DRE subtypes, the full-length 5.7-kb DREa and the internally deleted 2.4-kb DREb. Both subtypes are transcribed, as confirmed by analysis of cloned cDNA. Primary transcripts from the sense strand originate at nucleotide +1 and terminate at two dominant sites, located 21 or 28 nucleotides upstream from the 3' end of the elements. The activity of a reasonably strong polymerase II promoter in the 5'-terminal A module is slightly upregulated by the tRNA gene located 50 +/- 4 nucleotides upstream and drastically reduced by the adjacent B module of the DRE. Transcripts from the opposite DNA strand (complementary-sense transcripts) were also detected, directed by an internally located polymerase II promoter residing within the C module. This latter transcription was initiated at multiple sites within the oligo(dA12) stretch which terminates DREs.

Internally located and oppositely oriented polymerase II promoters direct convergent transcription of a LINE-like retroelement, the Dictyostelium repetitive element, from Dictyostelium discoideum

The Dictyostelium discoideum NC4 genome harbors approximately 150 individual copies of a retrotransposable element called the Dictyostelium repetitive element (DRE). This element contains nonidentical terminal repeats (TRs) consisting of conserved building blocks A and B in the left TR and B and C in the right TR. Seven different-sized classes of RNA transcripts from these elements were resolved by Northern (RNA) blot analysis, but their combined abundance was very low. When D. discoideum cells were grown in the presence of the respiratory chain blocker antimycin A, steady-state concentrations of these RNA species increased 10- to 20-fold. The D. discoideum genome contains two DRE subtypes, the full-length 5.7-kb DREa and the internally deleted 2.4-kb DREb. Both subtypes are transcribed, as confirmed by analysis of cloned cDNA. Primary transcripts from the sense strand originate at nucleotide +1 and terminate at two dominant sites, located 21 or 28 nucleotides upstream from the 3' end of the elements. The activity of a reasonably strong polymerase II promoter in the 5'-terminal A module is slightly upregulated by the tRNA gene located 50 +/- 4 nucleotides upstream and drastically reduced by the adjacent B module of the DRE. Transcripts from the opposite DNA strand (complementary-sense transcripts) were also detected, directed by an internally located polymerase II promoter residing within the C module. This latter transcription was initiated at multiple sites within the oligo(dA12) stretch which terminates DREs.

Different organization of the tRNA-gene-associated repetitive element, DRE, in NC4-derived strains and in other wild-type Dictyostelium discoideum strains

The retrotransposon DRE (Dictyostelium repetitive element) was discovered in the course of an extensive study concerning the genomic organization of tRNA genes in the NC4-derived strains AX2 and AX3 of the cellular slime mold Dictyostelium discoideum. As a striking feature, DRE was found exclusively in a constant orientation and at a constant distance upstream from different tRNA genes. About 150-200 DRE with intact 5'-terminal-repeat structures are present in NC4-derived strains. These strains were termed high-copy DRE strains (HCD strains) as opposed to low-copy DRE strains (LCD strains) such as the wild-type D. discoideum isolates DD61, WS380B, OHIO and V12. LCD strains contain only 3-15 DRE with intact 5'-terminal-repeat-structures. However, in addition to these few intact elements, many 5'-truncated DRE elements are present in LCD strains. In HCD strains, most DRE show typical structural characteristics of retrotransposons containing terminal repeats at both ends, which seems to be one prerequisite for active transposition. In LCD strains, however, most DRE elements are 5'-truncated, which is a common feature of eukaryotic LINE elements. Despite their truncated 5'-ends, DRE in LCD strains retain unique integration specificities, i.e. they are always found position-specifically and orientation-specifically integrated in front of tRNA genes, flanked by a 12-16-bp target-site duplication.