Person:

Wolf, Ashley Robin

Background:

Mounting evidence suggests a major role for epigenetic feedback in Plasmodium falciparum transcriptional regulation. Long non-coding RNAs (lncRNAs) have recently emerged as a new paradigm in epigenetic remodeling. We therefore set out to investigate putative roles for lncRNAs in P. falciparum transcriptional regulation.

Results:

We used a high-resolution DNA tiling microarray to survey transcriptional activity across 22.6% of the P. falciparum strain 3D7 genome. We identified 872 protein-coding genes and 60 putative P. falciparum lncRNAs under developmental regulation during the parasite's pathogenic human blood stage. Further characterization of lncRNA candidates led to the discovery of an intriguing family of lncRNA telomere-associated repetitive element transcripts, termed lncRNA-TARE. We have quantified lncRNA-TARE expression at 15 distinct chromosome ends and mapped putative transcriptional start and termination sites of lncRNA-TARE loci. Remarkably, we observed coordinated and stage-specific expression of lncRNA-TARE on all chromosome ends tested, and two dominant transcripts of approximately 1.5 kb and 3.1 kb transcribed towards the telomere.

Conclusions:

We have characterized a family of 22 telomere-associated lncRNAs in P. falciparum. Homologous lncRNA-TARE loci are coordinately expressed after parasite DNA replication, and are poised to play an important role in P. falciparum telomere maintenance, virulence gene regulation, and potentially other processes of parasite chromosome end biology. Further study of lncRNA-TARE and other promising lncRNA candidates may provide mechanistic insight into P. falciparum transcriptional regulation.

Transcription and translation of mammalian mitochondrial DNA (mtDNA) occurs within the mitochondrial matrix to produce oxidative phosphorylation subunits required for efficient energy production. These mtDNA-encoded subunits complex with mitochondrial-localized, nuclear-encoded subunits to form the respiratory chain, and aberrant production or function of these subunits can cause devastating human disease. In addition to 13 oxidative phosphorylation subunits, mtDNA encodes 2 rRNAs and 22 tRNAs. All proteins required for mitochondrial RNA transcription, processing, and translation are encoded in the nucleus and translocated into the mitochondria. Here, I characterize over 100 nuclear-encoded mitochondrial proteins with predicted RNA-binding domains. Using RNAi and an RNA profiling approach, MitoString, we further characterize previously identified RNA processing factors and identify the novel regulator FASTKD4, which influences the abundance of a subset of mitochondrial mRNAs. Next, we apply knowledge of the RNA degradation component SUPV3L1 gleaned from our RNAi studies and previous research to test whether a specific set of variants influence the function of this gene in patient fibroblasts. Using MitoString, we find no evidence of pathogenicity of these variants in our fibroblast model. Our approach highlights the value of a thorough understanding of mitochondrial proteins and the necessity of experimental techniques to validate the effect of variants found in exome-sequencing studies. Finally, we take an unbiased approach to characterizing the mitochondrial transcriptome of mouse liver by sequencing RNA from sequentially enriched mitochondrial fractions. Although we find an abundance of nuclear-encoded 5S rRNA, consistent with previous research, we fail to identify any imported nuclear-encoded tRNAs. Uniting genomics, biochemistry, and medicine, these findings advance our understanding of mitochondrial RNA biology.