Identification of Tissue‐Specific RNA Exosome Cofactors as an Approach to Define Disease Mechanism

Abstract

The RNA exosome, a 10‐subunit complex that mediates both RNA processing and degradation, plays a critical role in defining cellular expression profiles. This complex is ubiquitously expressed, essential, and critical for fundamental cellular functions, such as ribosomal RNA processing. Recent studies have linked mutations in genes encoding multiple subunits of the complex to tissue‐specific human disease. For example, mutations in the human EXOSC3 gene, coding for a subunit, cause Pontocerebellar Hypoplasia type 1b (PCH1b), a disease characterized by atrophy of the pons and cerebellum. The missense mutations encode single amino acid changes in conserved regions of the EXOSC3 protein. How these amino acid substitutions confer tissue‐specific phenotypes is not known. One possible mechanism underlying the distinct disease phenotypes could be a decrease in the interaction of the RNA exosome complex with cofactors that confer specificity for RNA targets. However, most studies that identify and characterize RNA exosome cofactors have been carried out in budding yeast and thus, do not provide insight into whether tissue‐specific cofactors could exist. Our studies use immunoprecipitation from neuronal cell culture (N2A) and mouse tissues to define RNA exosome cofactors. Biochemical experiments that employ cultured N2A cells identified RNA exosome interacting proteins that are enriched in both the nucleus and cytoplasm. Preliminary results from this analysis identify an association between the RNA exosome and a large complex of tRNA ligase enzymes, which could link defects in tRNA maturation to disease pathology. We are extending these studies to explore the possibility of tissue‐specific cofactors by immunoprecipitating EXOSC3 and analyzing co‐purifying proteins from the cerebellum (affected in disease) and the cortex (unaffected) in mouse brain. Finally, using CRISPR/Cas9 genome editing, we are testing whether the amino acid changes that occur in disease alter interactions with both known RNA exosome cofactors and interactors identified in our co‐immunoprecipitation studies. These studies will provide insight into both the functional consequences of amino acid substitutions in the RNA exosome that cause disease and the role of cofactors in conferring RNA target specificity.Support or Funding InformationR01GM130147This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.