Abstract
In eukaryotic cells, a group of messenger ribonucleic acids (mRNAs) encoding functionally interrelated proteins together with the trans-acting factors that coordinately modulate their expression is termed a post-transcriptional regulon, due to their partial analogy to a prokaryotic polycistron. This mRNA clustering is organized by sequence-specific RNA-binding proteins (RBPs) that bind cis-regulatory elements in the noncoding regions of genes, and mediates the synchronized control of their fate. These recognition motifs are often characterized by conserved sequences and/or RNA structures, and it is likely that various classes of cis-elements remain undiscovered. Current evidence suggests that RNA regulons govern gene expression in trypanosomes, unicellular parasites which mainly use post-transcriptional mechanisms to control protein synthesis. In this study, we used motif discovery tools to test whether groups of functionally related trypanosomatid genes contain a common cis-regulatory element. We obtained conserved structured RNA motifs statistically enriched in the noncoding region of 38 out of 53 groups of metabolically related transcripts in comparison with a random control. These motifs have a hairpin loop structure, a preferred sense orientation and are located in close proximity to the open reading frames. We found that 15 out of these 38 groups represent unique motifs in which most 3′-UTR signature elements were group-specific. Two extensively studied Trypanosoma cruzi RBPs, TcUBP1 and TcRBP3 were found associated with a few candidate RNA regulons. Interestingly, 13 motifs showed a strong correlation with clusters of developmentally co-expressed genes and six RNA elements were enriched in gene clusters affected after hyperosmotic stress. Here we report a systematic genome-wide in silico screen to search for novel RNA-binding sites in transcripts, and describe an organized network of several coordinately regulated cohorts of mRNAs in T. cruzi. Moreover, we found that structured RNA elements are also conserved in other human pathogens. These results support a model of regulation of gene expression by multiple post-transcriptional regulons in trypanosomes.
Highlights
The kinetoplastid protozoa comprise a group of unicellular parasites that belong to a distinctive evolutionary lineage of eukaryotes
Conserved structural RNA elements in 3 -UTRs of messenger ribonucleic acids (mRNAs) encoding metabolically interrelated proteins of T. cruzi Using a bioinformatic approach, we focused our work on the detection of potential structural cis-elements located in noncoding regions of functionally related transcripts
The regulon model states that RNA-binding proteins (RBPs) coordinately regulate multiple mRNAs coding for interrelated proteins by interacting with transcripts containing shared elements
Summary
The kinetoplastid protozoa comprise a group of unicellular parasites that belong to a distinctive evolutionary lineage of eukaryotes Members of this taxonomic group include etiological agents of several neglected zoonoses such as Chagas disease (Trypanosoma cruzi), sleeping sickness (Trypanosoma brucei) and Leishmaniasis (Leishmania spp.). These three species are digenetic unicellular microorganisms that suffer continuous morphological changes throughout their complex life-cycles (Barrett et al, 2003). Individual mature messenger ribonucleic acids (mRNAs) are generated by 5 trans-splicing and 3 polyadenylation of precursor RNAs (Hendriks & Matthews, 2007) Given these unique genetic features, trypanosomes essentially make use of post-transcriptional processes to control gene expression [reviewed in (De Gaudenzi et al, 2011)]
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