Abstract
While gene expression is a fundamental and tightly controlled cellular process that is regulated at multiple steps, the exact contribution of each step remains unknown in any organism. The absence of transcription initiation regulation for RNA polymerase II in the protozoan parasite Trypanosoma brucei greatly simplifies the task of elucidating the contribution of translation to global gene expression. Therefore, we have sequenced ribosome-protected mRNA fragments in T. brucei, permitting the genome-wide analysis of RNA translation and translational efficiency. We find that the latter varies greatly between life cycle stages of the parasite and ∼100-fold between genes, thus contributing to gene expression to a similar extent as RNA stability. The ability to map ribosome positions at sub-codon resolution revealed extensive translation from upstream open reading frames located within 5′ UTRs and enabled the identification of hundreds of previously un-annotated putative coding sequences (CDSs). Evaluation of existing proteomics and genome-wide RNAi data confirmed the translation of previously un-annotated CDSs and suggested an important role for >200 of those CDSs in parasite survival, especially in the form that is infective to mammals. Overall our data show that translational control plays a prevalent and important role in different parasite life cycle stages of T. brucei.
Highlights
Eukaryotic gene expression is regulated at multiple levels, including extensive and elaborate post-transcriptional regulation that affects RNA stability, protein translation and protein turnover [1]
We observed no correlation between RNA abundance and translational efficiency (R2 = 0.03), suggesting that translational efficiency is regulated independently of RNA stability
Previously unidentified coding sequences (CDSs) appear to be essential for parasite fitness, and the analysis of available proteomics data confirmed the existence of at least 20 of these previously unknown CDSs
Summary
Eukaryotic gene expression is regulated at multiple levels, including extensive and elaborate post-transcriptional regulation that affects RNA stability, protein translation and protein turnover [1]. How much these individual levels contribute to the final outcome, the steady state level of a protein, is not known for any organism. The genome organization of kinetoplastids differs from that of other eukaryotes in that most protein-coding genes are transcribed from long polycistronic transcription units (PTUs). These PTUs can encompass >100 mostly functionally unrelated genes [10,11,12,13]. The absence of promoter sequence motifs, the organization of genes in PTUs and an apparently conserved open chromatin structure
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