The Dictyostelium discoideum RNA-dependent RNA polymerase RrpC silences the centromeric retrotransposon DIRS-1 post-transcriptionally and is required for the spreading of RNA silencing signals.

Dictyostelium intermediate repeat sequence 1 (DIRS-1) is the founding member of a poorly characterized class of retrotransposable elements that contain inverse long terminal repeats and tyrosine recombinase instead of DDE-type integrase enzymes. In Dictyostelium discoideum, DIRS-1 forms clusters that adopt the function of centromeres, rendering tight retrotransposition control critical to maintaining chromosome integrity. We report that in deletion strains of the RNA-dependent RNA polymerase RrpC, full-length and shorter DIRS-1 messenger RNAs are strongly enriched. Shorter versions of a hitherto unknown long non-coding RNA in DIRS-1 antisense orientation are also enriched in rrpC- strains. Concurrent with the accumulation of long transcripts, the vast majority of small (21 mer) DIRS-1 RNAs vanish in rrpC- strains. RNASeq reveals an asymmetric distribution of the DIRS-1 small RNAs, both along DIRS-1 and with respect to sense and antisense orientation. We show that RrpC is required for post-transcriptional DIRS-1 silencing and also for spreading of RNA silencing signals. Finally, DIRS-1 mis-regulation in the absence of RrpC leads to retrotransposon mobilization. In summary, our data reveal RrpC as a key player in the silencing of centromeric retrotransposon DIRS-1. RrpC acts at the post-transcriptional level and is involved in spreading of RNA silencing signals, both in the 5' and 3' directions.

Conserved gene regulatory function of the carboxy-terminal domain of dictyostelid C-module-binding factor.

C-module-binding factor A (CbfA) is a jumonji-type transcription regulator that is important for maintaining the expression and mobility of the retrotransposable element TRE5-A in the social amoeba Dictyostelium discoideum. CbfA-deficient cells have lost TRE5-A retrotransposition, are impaired in the ability to feed on bacteria, and do not enter multicellular development because of a block in cell aggregation. In this study, we performed Illumina RNA-seq of growing CbfA mutant cells to obtain a list of CbfA-regulated genes. We demonstrate that the carboxy-terminal domain of CbfA alone is sufficient to mediate most CbfA-dependent gene expression. The carboxy-terminal domain of CbfA from the distantly related social amoeba Polysphondylium pallidum restored the expression of CbfA-dependent genes in the D. discoideum CbfA mutant, indicating a deep conservation in the gene regulatory function of this domain in the dictyostelid clade. The CbfA-like protein CbfB displays ∼25% sequence identity with CbfA in the amino-terminal region, which contains a JmjC domain and two zinc finger regions and is thought to mediate chromatin-remodeling activity. In contrast to CbfA proteins, where the carboxy-terminal domains are strictly conserved in all dictyostelids, CbfB proteins have completely unrelated carboxy-terminal domains. Outside the dictyostelid clade, CbfA-like proteins with the CbfA-archetypical JmjC/zinc finger arrangement and individual carboxy-terminal domains are prominent in filamentous fungi but are not found in yeasts, plants, and metazoans. Our data suggest that two functional regions of the CbfA-like proteins evolved at different rates to allow the occurrence of species-specific adaptation processes during genome evolution.

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.

A host factor supports retrotransposition of the TRE5-A population in Dictyostelium cells by suppressing an Argonaute protein.

BACKGROUND: In the compact and haploid genome of Dictyostelium discoideum control of transposon activity is of particular importance to maintain viability. The non-long terminal repeat retrotransposon TRE5-A amplifies continuously in D. discoideum cells even though it produces considerable amounts of minus-strand (antisense) RNA in the presence of an active RNA interference machinery. Removal of the host-encoded C-module-binding factor (CbfA) from D. discoideum cells resulted in a more than 90 % reduction of both plus- and minus-strand RNA of TRE5-A and a strong decrease of the retrotransposition activity of the cellular TRE5-A population. Transcriptome analysis revealed an approximately 230-fold overexpression of the gene coding for the Argonaute-like protein AgnC in a CbfA-depleted mutant. RESULTS: The D. discoideum genome contains orthologs of RNA-dependent RNA polymerases, Dicer-like proteins, and Argonaute proteins that are supposed to represent RNA interference pathways. We analyzed available mutants in these genes for altered expression of TRE5-A. We found that the retrotransposon was overexpressed in mutants lacking the Argonaute proteins AgnC and AgnE. Because the agnC gene is barely expressed in wild-type cells, probably due to repression by CbfA, we employed a new method of promoter-swapping to overexpress agnC in a CbfA-independent manner. In these strains we established an in vivo retrotransposition assay that determines the retrotransposition frequency of the cellular TRE5-A population. We observed that both the TRE5-A steady-state RNA level and retrotransposition rate dropped to less than 10 % of wild-type in the agnC overexpressor strains. CONCLUSIONS: The data suggest that TRE5-A amplification is controlled by a distinct pathway of the Dictyostelium RNA interference machinery that does not require RNA-dependent RNA polymerases but involves AgnC. This control is at least partially overcome by the activity of CbfA, a factor derived from the retrotransposon's host. This unusual regulation of mobile element activity most likely had a profound effect on genome evolution in D. discoideum.

The calcineurin dependent transcription factor TacA is involved in development and the stress response of Dictyostelium discoideum.

Calcineurin is an important signalling protein in a plethora of Ca(2+)-regulated cellular processes. In contrast to what is known about the function of calcineurin in various organisms, information on calcineurin substrates is still limited. Here we describe the identification and characterisation of the transcription factor activated by calcineurin (TacA) in the model organism Dictyostelium discoideum. TacA is a putative zinc-finger transcription factor orthologue of yeast Crz1. In resting unstimulated cells the protein is located in the cytosol and translocates to the nucleus in a calcineurin-dependent manner after Ca(2+)-stimulation. Nuclear export of TacA is partially dependent on GskA, the Dictyostelium orthologue of mammalian GSK3. The expression of tacA is developmentally regulated with its kinetics roughly paralleling calcineurin regulation. Silencing of tacA via RNAi leads to developmental defects and dysregulation of developmentally regulated and Ca(2+)-regulated marker genes. Additionally, TacA is involved in the stress response of D. discoideum during development in a separate pathway to the well-known stress response in Dictyostelium via STATc. Finally we provide evidence that TacA is not only an orthologue of yeast Crz1 but also functionally related to mammalian NFAT.