RESUMEN
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.
Asunto(s)
Biofisica , Aparato de Golgi/ultraestructura , Proteínas de la Matriz de Golgi/ultraestructura , Conformación Proteica , Cristalografía por Rayos X , Aparato de Golgi/química , Proteínas de la Matriz de Golgi/química , Humanos , Proteínas de la Membrana/química , Proteínas de la Membrana/ultraestructuraRESUMEN
Golgi Reassembly and Stacking Proteins (GRASPs), including GRASP65/GRASP55, were firstly found as stacking factors of Golgi cisternae. Their involvement in other processes, such as unconventional protein secretion (UPS), have been demonstrated, suggesting GRASPs act as interaction hubs. However, structural details governing GRASP functions are not understood thoroughly. Here, we explored the structural features of human cis-Golgi GRASP65 in aqueous solution and compared them with those from trans-Golgi GRASP55. Besides their distinct Golgi localization, GRASP65/55 also seem to be selectively recruited to mitosis-related events or to UPS. Despite preserving the monomeric form in solution seen for GRASP55, as inferred from our SEC-MALS and DLS data, GRASP65 exhibited higher intrinsic disorder and susceptibility to denaturant than GRASP55 (disorder prediction, urea denaturation and circular dichroism data). Moreover, spectroscopic and microscopic studies showed for GRASP65 the same temperature-dependent amorphous aggregation and time-dependent amyloid fibrillation at 37 °C seen for GRASP55. In the latter case, however, GRASP65 presented a lower aggregation rate than GRASP55. The present and previous data evidenced that intrinsic disorder and formation of higher-order oligomers, such as amyloid fibrils, are common features within GRASP family potentially impacting the protein's participation in cell processes.
Asunto(s)
Proteínas de la Matriz de Golgi/química , Proteínas Intrínsecamente Desordenadas/química , Proteínas de la Membrana/química , Amiloide/metabolismo , Aparato de Golgi/metabolismo , Humanos , Transporte de ProteínasRESUMEN
GRASP55, one of the two human GRASP proteins, has been implicated in the organization of Golgi stacks and in unconventional protein secretion. However, the detailed molecular mechanisms supporting GRASP55 participation in those processes remain mostly unclear. We have shown that GRASP55 exists as monomers in solution, which transitions to amorphous aggregates with increasing temperatures. Here, we further investigated the formation of higher order structures of GRASP55 by exploring its amyloid fibrillation at 37 °C. Sequence-based AGGRESCAN analysis revealed that GRASP55 has ten aggregation "hot spots", preferentially concentrated in its N-terminal half. Congo Red, ThT, and circular dichroism assays suggested GRASP55 formed amyloid-like fibrils in a time-dependent manner at 37 °C. Dynamic light scattering showed the mean hydrodynamic radius of GRASP55 amyloid-like fibrils increased with increasing incubation times at 37 °C. Transmission electron microscopy and intrinsic fluorescence lifetime imaging showed that, upon increasing incubation time at 37 °C, GRASP55 yielded amyloid-like fibrils in a nucleation-dependent process via a sequence of events: lag-phase (monomers to oligomers), growth phase (oligomers to organized protofibrils), and plateau phase (protofibrils to amyloid-like fibrils). The insights gained herein may help in better understanding the mechanisms of GRASP55 amyloid fibrillation in vivo and its potential association with neurological disorders.
Asunto(s)
Amiloide/química , Aparato de Golgi/fisiología , Proteínas de la Matriz de Golgi/química , Benzotiazoles/química , Dicroismo Circular , Biología Computacional , Rojo Congo/química , Humanos , Hidrodinámica , Cinética , Luz , Microscopía Electrónica de Transmisión , Enfermedades del Sistema Nervioso/fisiopatología , Conformación Proteica , Dominios Proteicos , Proteínas Recombinantes/química , Dispersión de Radiación , TemperaturaRESUMEN
In mammals, the Golgi apparatus is the central hub for intracellular trafficking, sorting and post-translational modifications of proteins and lipids. Golgi reassembly and stacking proteins (GRASPs) are somehow involved in Golgi stacking, which is relevant for its proper function, and also in unconventional protein secretion. However, the structural details on how GRASPs accomplish those tasks are still elusive. Here, we have explored the biochemical and biophysical properties of human full-length GRASP55 in solution. Sequence-based analyses and circular dichroism spectroscopy suggest that GRASP55 presents multiple intrinsically disordered sites, although keeping considerable contents of regular secondary structure. Size exclusion chromatography and multiple-angle light scattering show that GRASP55 are monomers in solution. Urea denaturation of GRASP55 suggests the transition to the unfolded state is a cooperative process. Differential scanning calorimetry analysis displays two endothermic transitions for GRASP55, indicating the existence of an intermediate state prior to unfolding. Thioflavin T fluorescence suggests GRASP55 intermediate can be aggregates/fibrils. Transmission electron microscopy and fluorescence lifetime imaging microscopy prove GRASP55 forms large amorphous aggregates but not amyloid-like fibrils in the intermediate state. These results could be helpful in discussing the proper function of human GRASP55 in the Golgi organization as well as unconventional secretion of proteins.