Pontocerebellar hypoplasia type 1b (PCH1b) is an autosomal recessive disorder that causes cerebellar hypoplasia and spinal motor neuron degeneration, leading to mortality in early childhood. PCH1b is caused by mutations in the RNA exosome subunit gene, EXOSC3. The RNA exosome is an evolutionarily conserved complex, consisting of nine different core subunits, and one or two 39-59 exoribonuclease subunits, that mediates several RNA degradation and processing steps. The goal of this study is to assess the functional consequences of the amino acid substitutions that have been identified in EXOSC3 in PCH1b patients. To analyze these EXOSC3 substitutions, we generated the corresponding amino acid substitutions in the Saccharomyces cerevisiae ortholog of EXOSC3, Rrp40. We find that the rrp40 variants corresponding to EXOSC3-G31A and -D132A do not affect yeast function when expressed as the sole copy of the essential Rrp40 protein. In contrast, the rrp40-W195R variant, corresponding to EXOSC3-W238R in PCH1b patients, impacts cell growth and RNA exosome function when expressed as the sole copy of Rrp40. The rrp40-W195R protein is unstable, and does not associate efficiently with the RNA exosome in cells that also express wild-type Rrp40. Consistent with these findings in yeast, the levels of mouse EXOSC3 variants are reduced compared to wild-type EXOSC3 in a neuronal cell line. These data suggest that cells possess a mechanism for optimal assembly of functional RNA exosome complex that can discriminate between wildtype and variant exosome subunits. Budding yeast can therefore serve as a useful tool to understand the molecular defects in the RNA exosome caused by PCH1b-associated amino acid substitutions in EXOSC3, and potentially extending to disease-associated substitutions in other exosome subunits.KEYWORDS pontocerebellar hypoplasia type 1b; RNA exosome; EXOSC3; Rrp40; EXOSC2; RNA processing/degradation T HE RNA exosome is an evolutionarily conserved ribonuclease complex that is responsible for several essential RNA processing and degradation steps (Mitchell et al. 1997;Allmang et al. 1999;Schneider and Tollervey 2013). Major exosome substrates include mRNA, rRNA, and small RNAs. In addition to degrading aberrant and unneeded transcripts, the RNA exosome also trims precursor RNAs, including 5.8S rRNA (Mitchell et al. 1996). The RNA exosome thus plays critical roles in both RNA degradation and maturation.The subunits of the RNA exosome complex are evolutionarily conserved and many were first identified in Saccharomyces cerevisiae in a screen for ribosomal RNA processing (rrp) mutants (Mitchell et al. 1996(Mitchell et al. , 1997Allmang et al. 1999). S. cerevisiae Rrp subunits correspond to human EXOSC subunits. The functions of the RNA exosome have been extensively characterized in budding yeast (Sloan et al. 2012), and many are conserved in humans (Schilders et al. 2005;Staals et al. 2010;Lubas et al. 2011Lubas et al. , 2015 the RNA exosome, six subunits comprise a core ring, and three putative RNA-binding sub...
Replication-dependent histone mRNAs are the only cellular mRNAs that are not polyadenylated, ending in a stemloop instead of a polyA tail, and are normally regulated coordinately with DNA replication. SLBP binds the 3’ end of histone mRNA, and is required for processing and translation. During Drosophila oogenesis, large amounts of histone mRNAs and proteins are deposited in the developing oocyte.The maternally deposited histone mRNA is synthesized in stage 10B oocytes after the nurse cells complete endoreduplication. We report that in WT stage 10B oocytes, the Histone Locus Bodies (HLBs), formed on the histone genes, produce histone mRNAs in the absence of phosphorylation of Mxc, normally required for histone gene expression in S-phase cells. Two mutants of SLBP, one with reduced expression and another with a 10 aa deletion, fail to deposit sufficient histone mRNA in the oocyte, and don't transcribe the histone genes in stage 10B. Mutations in a putative SLBP nuclear localization sequence overlapping the deletion, phenocopy the deletion. We conclude a high concentration of SLBP in the nucleus of stage 10B oocytes is essential for histone gene transcription.
During Drosophila oogenesis, large amounts of histone mRNA and proteins are deposited in the developing oocyte. These are sufficient for the first 14 embryonic cell cycles and provide the developing embryo with sufficient histone proteins until the zygotic histone genes are activated. The maternally deposited histone mRNA is synthesized in stage 10b of oogenesis after completion of endoreduplication of the nurse cells. Histone mRNAs are the only cellular mRNAs that are not polyadenylated, ending instead in a conserved stemloop instead of a polyA tail. The Stem-loop binding protein (SLBP) binds the 3' end of histone mRNA and is essential for both the biosynthesis and translation of histone mRNA. We report that a 10 aa region in SLBP, which is not required for processing in vitro, is essential for transcription of histone mRNA in the stage 10b oocyte. In stage 10b the Histone Locus Bodies (HLBs) produce histone mRNAs in the absence of phosphorylation of Mxc, normally required for histone gene expression in S-phase cells. Mutants expressing this SLBP develop normally, produce small amounts of polyadenylated histone mRNA throughout development, but little histone mRNA in stage 10b resulting in death of the embryos in the first hr of development.
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