Abstract
The adenosine deaminase acting on RNA (ADAR) enzymes deaminate adenosine to inosine in double-stranded (ds)RNA. Mammals express two catalytically active enzymes: ADAR1, which is ubiquitously expressed and essential for innate immune homeostasis, and ADAR2, which is enriched in the brain and vascular system. Here, we investigate the ADAR2 interactome and uncover a shared interaction network with ADAR1, including multiple components of the RNA exosome complex, a multi-subunit RNase involved in RNA processing, turnover, and surveillance. The interactions between ADARs and RNA exosome components are nuclear, and resistance to RNase A treatment implies their close proximity. We validated these interactions by immunoprecipitation of both endogenous and epitope-tagged ADAR proteins in multiple cell lines and mapped the interaction interfaces to their dsRNA-binding domains. Exploiting an MS2-MCP tethering system, we show that recruitment of ADAR1 or ADAR2 to the 3' UTR of a reporter transcript decreases its stability. This decrease in RNA levels was reversed when EXOSC3 was depleted, demonstrating that this destabilizing effect of ADARs on RNA is via the RNA exosome complex. Finally, knockdown of ADARs perturbs rRNA processing, a canonical function of the nuclear exosome, demonstrating a cellular consequence of disrupting ADAR-exosome interactions.