In vivo observation of amyloid-like fibrils produced under stress.

The participation of amyloids in neurodegenerative diseases and functional processes has triggered the quest for methods allowing their direct detection in vivo. Despite the plethora of data, those methods are still lacking. The autofluorescence from the extended ß-sheets of amyloids is here used to track fibrillation of S. cerevisiae Golgi Reassembly and Stacking Protein (Grh1). Grh1 has been implicated in starvation-triggered unconventional protein secretion (UPS), and here its participation also in heat shock response (HSR) is suggested. Fluorescence Lifetime Imaging (FLIM) is used to detect fibril autofluorescence in cells (E. coli and yeast) under stress (starvation and higher temperature). The formation of Grh1 large complexes under stress is further supported by size exclusion chromatography and ultracentrifugation. The data show for the first time in vivo detection of amyloids without the use of extrinsic probes as well as bring new perspectives on the participation of Grh1 in UPS and HSR.

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 GRASP domain in golgi reassembly and stacking proteins: differences and similarities between lower and higher Eukaryotes.

The Golgi complex is part of the endomembrane system and is responsible for receiving transport cargos from the endoplasmic reticulum and for sorting and targeting them to their final destination. To perform its function in higher eukaryotic cells, the Golgi needs to be correctly assembled as a flattened membrane sandwich kept together by a protein matrix. The precise mechanism controlling the Golgi cisternae assembly is not yet known, but it is widely accepted that the Golgi Reassembly and Stacking Protein (GRASP) is a main component of the Golgi protein matrix. Unlike mammalian cells, which have two GRASP genes, lower eukaryotes present only one gene and distinct Golgi cisternae assembly. In this study, we performed a set of biophysical studies to get insights on the structural properties of the GRASP domains (DGRASPs) from both human GRASP55 and GRASP65 and compare them with GRASP domains from lower eukaryotes (Saccharomyces cerevisiae and Cryptococcus neoformans). Our data suggest that both human DGRASPs are essentially different from each other and that DGRASP65 is more similar to the subgroup of DGRASPs from lower eukaryotes in terms of its biophysical properties. GRASP55 is present mainly in the Golgi medial and trans faces, which are absent in both fungi, while GRASP65 is located in the cis-Golgi. We suggest that the GRASP65 gene is more ancient and that its paralogue GRASP55 might have appeared later in evolution, together with the medial and trans Golgi faces in mammalians.