Nuclear RNA Exosome and Pervasive Transcription: Dual Sculptors of Genome Function

The genome is pervasively transcribed across various species, yielding numerous non-coding RNAs. As a counterbalance for pervasive transcription, various organisms have a nuclear RNA exosome complex, whose structure is well conserved between yeast and mammalian cells. The RNA exosome not only regulates the processing of stable RNA species, such as rRNAs, tRNAs, small nucleolar RNAs, and small nuclear RNAs, but also plays a central role in RNA surveillance by degrading many unstable RNAs and misprocessed pre-mRNAs. In addition, associated cofactors of RNA exosome direct the exosome to distinct classes of RNA substrates, suggesting divergent and/or multi-layer control of RNA quality in the cell. While the RNA exosome is essential for cell viability and influences various cellular processes, mutations and alterations in the RNA exosome components are linked to the collection of rare diseases and various diseases including cancer, respectively. The present review summarizes the relationships between pervasive transcription and RNA exosome, including evolutionary crosstalk, mechanisms of RNA exosome-mediated RNA surveillance, and physiopathological effects of perturbation of RNA exosome.

Interplay of the RNA Exosome Complex and RNA-Binding Protein Ssd1 in Maintaining Cell Wall Stability in Yeast

Stressful conditions such as high temperatures can compromise cellular integrity and cause bursting. In microorganisms surrounded by a cell wall, such as yeast, the cell wall is the primary shield that protects cells from environmental stress.

The CTEXT complex in Saccharomyces cerevisiae plays a crucial role in degrading distinct sets of aberrant mRNAs by the nuclear exosome

In Saccharomyces cerevisiae, DRN (Decay of RNA in the Nucleus) requiring Cbc1/2p, Tif4631p, and Upf3p promotes the exosomal degradation of aberrantly long 3′-extended-, export-defective transcripts and a small group of normal (special) mRNAs. In this study, using a systematic proteomic analysis we show that each of the known components interacts with one another and they exist as a separate complex, which was dubbed CTEXT (CBC-Tif4631p-dependent EXosome Targeting). We also identified a DEAD-box RNA helicase Dbp2p as an additional novel component of CTEXT during this analysis which was further bolstered by the finding that genomic deletions of Dbp2p led to the stabilization of all the signature nuclear messages. Interestingly, the RRM domain of Tif4631p located at the extreme N-termini of this polypeptide was found to play a vital role in in mediating the interaction of the CTEXT with the core exosome complex. These inferences were substantiated by the finding that deletion of this domain led to the functional impairment of the CTEXT complex. Thus, the CTEXT constitutes an independent complex that assists the nuclear exosome in degrading the select classes of nuclear transcripts in Saccharomyces cerevisiae.

Post-transcriptional regulation by the exosome complex is required for cell survival and forebrain development via repression of P53 signaling

ABSTRACTFine-tuned gene expression is crucial for neurodevelopment. The gene expression program is tightly controlled at different levels, including RNA decay. N6-methyladenosine (m6A) methylation-mediated degradation of RNA is essential for brain development. However, m6A methylation impacts not only RNA stability, but also other RNA metabolism processes. How RNA decay contributes to brain development is largely unknown. Here, we show that Exosc10, a RNA exonuclease subunit of the RNA exosome complex, is indispensable for forebrain development. We report that cortical cells undergo overt apoptosis, culminating in cortical agenesis upon conditional deletion of Exosc10 in mouse cortex. Mechanistically, Exosc10 directly binds and degrades transcripts of the P53 signaling-related genes, such as Aen and Bbc3. Overall, our findings suggest a crucial role for Exosc10 in suppressing the P53 pathway, in which the rapid turnover of the apoptosis effectors Aen and Bbc3 mRNAs is essential for cell survival and normal cortical histogenesis.

Two siblings with a novel variant of EXOSC3 extended phenotypic spectrum of pontocerebellar hypoplasia 1B to an exceptionally mild form

Pontocerebellar hypoplasia type 1B (PCH1B) describes an autosomal recessive neurological condition that involves hypoplasia or atrophy of the cerebellum and pons, resulting in neurocognitive impairments. Although there is phenotypic variability, this is often an infantile lethal condition, and most cases have been described to be congenital and neurodegenerative. PCH1B is caused by mutations in the gene EXOSC3, which encodes exosome component 3, a subunit of the human RNA exosome complex. A range of pathogenic variants with some correlation to phenotype have been reported. The most commonly reported pathogenic variant in EXOSC3 is c.395A>C, p.(Asp132Ala); homozygosity for this variant has been proposed to lead to milder phenotypes than compound heterozygosity. In this case, we report two siblings with extraordinarily mild presentations of PCH1B who are compound heterozygous for variants in EXOSC3 c.155delC and c.80T>G. These patients drastically expand the phenotypic variability of PCH1B and raise questions about genotype–phenotype associations.

Post-transcriptional control of cellular differentiation by the RNA exosome complex

Given the complexity of intracellular RNA ensembles and vast phenotypic remodeling intrinsic to cellular differentiation, it is instructive to consider the role of RNA regulatory machinery in controlling differentiation. Dynamic post-transcriptional regulation of protein-coding and non-coding transcripts is vital for establishing and maintaining proteomes that enable or oppose differentiation. By contrast to extensively studied transcriptional mechanisms governing differentiation, many questions remain unanswered regarding the involvement of post-transcriptional mechanisms. Through its catalytic activity to selectively process or degrade RNAs, the RNA exosome complex dictates the levels of RNAs comprising multiple RNA classes, thereby regulating chromatin structure, gene expression and differentiation. Although the RNA exosome would be expected to control diverse biological processes, studies to elucidate its biological functions and how it integrates into, or functions in parallel with, cell type-specific transcriptional mechanisms are in their infancy. Mechanistic analyses have demonstrated that the RNA exosome confers expression of a differentiation regulatory receptor tyrosine kinase, downregulates the telomerase RNA component TERC, confers genomic stability and promotes DNA repair, which have considerable physiological and pathological implications. In this review, we address how a broadly operational RNA regulatory complex interfaces with cell type-specific machinery to control cellular differentiation.

Molecular basis of the selective processing of short mRNA substrates by the DcpS mRNA decapping enzyme

The 5′ messenger RNA (mRNA) cap structure enhances translation and protects the transcript against exonucleolytic degradation. During mRNA turnover, this cap is removed from the mRNA. This decapping step is catalyzed by the Scavenger Decapping Enzyme (DcpS), in case the mRNA has been exonucleolyticly shortened from the 3′ end by the exosome complex. Here, we show that DcpS only processes mRNA fragments that are shorter than three nucleotides in length. Based on a combination of methyl transverse relaxation optimized (TROSY) NMR spectroscopy and X-ray crystallography, we established that the DcpS substrate length-sensing mechanism is based on steric clashes between the enzyme and the third nucleotide of a capped mRNA. For longer mRNA substrates, these clashes prevent conformational changes in DcpS that are required for the formation of a catalytically competent active site. Point mutations that enlarge the space for the third nucleotide in the mRNA body enhance the activity of DcpS on longer mRNA species. We find that this mechanism to ensure that the enzyme is not active on translating long mRNAs is conserved from yeast to humans. Finally, we show that the products that the exosome releases after 3′ to 5′ degradation of the mRNA body are indeed short enough to be decapped by DcpS. Our data thus directly confirms the notion that mRNA products of the exosome are direct substrates for DcpS. In summary, we demonstrate a direct relationship between conformational changes and enzyme activity that is exploited to achieve substrate selectivity.