The exquisite structural biophysics of the Golgi Reassembly and Stacking Proteins.

Golgi Reassembly and Stacking Proteins (GRASPs) were firstly described as crucial elements in determining the structure of the Golgi complex. However, data have been accumulating over the years showing GRASPs can participate in various cell processes beyond the Golgi maintenance, including cell adhesion and migration, autophagy and unconventional secretion of proteins. A comprehensive understanding of the GRASP functions requires deep mechanistic knowledge of its structure and dynamics, especially because of the unique structural plasticity observed for many members of this family coupled with their high promiscuity in mediating protein-protein interactions. Here, we critically review data regarding the structural biophysics of GRASPs in the quest for understanding the structural determinants of different functionalities. We dissect GRASP structure starting with the full-length protein down to its separate domains (PDZ1, PDZ2 and SPR) and outline some structural features common to all members of the GRASP family (such as the presence of many intrinsically disordered regions). Although the impact of those exquisite properties in vivo will still require further studies, it is possible, from our review, to pinpoint factors that must be considered in future interpretation of data regarding GRASP functions, thus bringing somewhat new perspectives to the field.

The golgin family exhibits a propensity to form condensates in living cells.

The Golgi is surrounded by a ribosome-excluding matrix. Recently, we reported that the cis-Golgi-localized golgin GM130 can phase-separate to form dynamic, liquid-like condensates in vitro and in vivo. Here, we show that the overexpression of each of the remaining cis (golgin160, GMAP210)- and trans (golgin97, golgin245, GCC88, GCC185)-golgins results in novel protein condensates. Focused ion beam scanning electron microscopy (FIB-SEM) images of GM130 condensates reveal a complex internal organization with branching aqueous channels. Pairs of golgins overexpressed in the same cell form distinct juxtaposed condensates. These findings support the hypothesis that, in addition to their established roles as vesicle tethers, phase separation may be a common feature of the golgin family that contributes to Golgi organization.