Abstract
In this perspective, we discuss the regulatory impact of nuclear RNA export and decay on messenger RNA (mRNA) functionality. It is well established that control of protein-coding gene expression in eukaryotes employs the regulated production of mRNA, its intra-cellular transfer to cytoplasmic ribosomes and final transcript degradation. Despite a rich body of literature on these events, an involvement of nuclear RNA decay systems remains largely unexplored. Instead, nuclear RNA degradation is often considered a quality control precaution engaged primarily in ridding cells of aberrantly processed transcripts and spurious non-coding RNA. Recent research from human and budding yeast cells, however, demonstrates that even protein-coding transcripts fall prey to nuclear decay and that this is countered by their nuclear export. Here, we outline the potential of nuclear polyA-binding proteins in tuning levels of cellular mRNA to maintain transcript homeostasis.
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Tudek, A., Schmid, M. & Jensen, T.H. Escaping nuclear decay: the significance of mRNA export for gene expression. Curr Genet 65, 473–476 (2019). https://doi.org/10.1007/s00294-018-0913-x
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DOI: https://doi.org/10.1007/s00294-018-0913-x