A nuclear role for ARGONAUTE-2 in regulation of neuronal alternative polyadenylation

Argonaute 2 (AGO2), the effector protein partner of microRNAs (miRNAs) in the cytoplasmic RNA induced silencing complex, is further involved in nuclear RNA processing. However, a role for AGO2 in regulation of alternative polyadenylation was not yet demonstrated. Here, we reveal unexpected abundance of AGO2 in mouse neuronal nuclei and characterize nuclear AGO2 interactors by mass spectrometry. We discover that AGO2 broadly regulated alternative polyadenylation (APA) in neuronal cells. Specifically, we demonstrate how two isoforms of Ret mRNA, which encodes a receptor tyrosine kinase are regulated by AGO2-depenent APA, affecting downstream GDNF signaling in primary motor neurons.

TASOR is a pseudo-PARP that directs HUSH complex assembly and epigenetic transposon control

SummaryThe Human Silencing Hub (HUSH) complex epigenetically represses retroviruses, transposons and genes in vertebrates. HUSH therefore maintains genome integrity and is central in the interplay between intrinsic immunity, transposable elements and transcriptional regulation. Comprising three subunits – TASOR, MPP8 and Periphilin – HUSH regulates SETDB1-dependent deposition of the transcriptionally repressive epigenetic mark H3K9me3 and recruits MORC2 to modify local chromatin structure. However the mechanistic roles of each HUSH subunit remain undetermined. Here we show that TASOR lies at the heart of HUSH, providing a platform for assembling the other subunits. Targeted epigenomic profiling supports the model that TASOR binds and regulates H3K9me3 specifically over LINE-1 repeats and other repetitive exons in transcribed genes. We find TASOR associates with several components of the nuclear RNA processing machinery and its modular domain architecture bears striking similarities to that of Chp1, the central component of the yeast RNA-induced transcriptional silencing (RITS) complex. Together these observations suggest that an RNA intermediate may be important for HUSH activity. We identify the TASOR domains necessary for HUSH assembly and transgene repression. Structural and genomic analyses reveal that TASOR contains a poly-ADP ribose polymerase (PARP) domain dispensable for assembly and chromatin localization, but critical for epigenetic regulation of target elements. This domain contains a degenerated and obstructed active site and has hence lost catalytic activity. Together our data demonstrate that TASOR is a pseudo-PARP critical for HUSH complex assembly and H3K9me3 deposition over its genomic targets.

Coupling genetics and post-genomic approaches to decipher the cellular splicing code at a systems-wide level

Nuclear RNA processing is a critical stage in eukaryotic gene expression, and is controlled in part by the expression and concentration of nuclear RNA-binding proteins. Different nuclear RNA-binding proteins are differentially expressed in different cells, helping the spliceosome to decode pre-mRNAs into alternatively spliced mRNAs. Recent post-genomic technology has exposed the complexity of nuclear RNA processing, and is starting to reveal the mechanisms and rules through which networks of RNA-binding proteins can regulate multiple parallel pathways. Identification of multiple parallel processing pathways regulated by nuclear RNA-binding proteins is leading to a systems-wide understanding of the rules and consequences of alternative nuclear RNA processing.