The rixosome is a large multisubunit complex that initiates RNA decay during critical nuclear transactions including ribosome assembly and heterochromatin maintenance. The overall architecture of the complex remains undefined because several subunits contain intrinsically disordered regions (IDRs). In this study from the Warren and Stanley (NIH, Chapel Hill, USA) labs featuring research from PhD student Jacob Gordon (Cambridge-NIH scholar), structural and functional approaches were combined to establish PELP1 as the central scaffold of the rixosome upon which the enzymatic subunits modularly assemble. The C-terminal half of PELP1 is composed of a proline-rich IDR that mediates association with the AAA-ATPase MDN1, histones, and the SUMO-specific protease SENP3. The PELP1 IDR contains a glutamic acid-rich region that we establish can chaperone the histone octamer in vitro. Last, the X-ray structure of a small linear motif (SLiM) from the PELP IDR bound to SENP3 reveals how PELP1 allosterically activates SUMO protease activity. This work provides an integrated structural model for understanding the rixosome's dynamic architecture and how it modularly coordinates several cellular functions.