Conformational flexibility of GRASPs and their constituent PDZ subdomains reveals structural basis of their promiscuous interactome

Mendes, Luis Felipe Santos; Batista, Mariana; Judge, Peter J.; Watts, Anthony; Redfield, Christina; Costa-Filho, Antonio J.

doi:10.1111/febs.15206

Cited by 11 publications

(14 citation statements)

References 84 publications

(135 reference statements)

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“…Our group has been exploring the biophysics of GRASPs in the last few years [20–25]. In one of our last contributions [22], we described novel structural features of Grh1, the GRASP from Saccharomyces cerevisiae .…”

Section: Introductionmentioning

confidence: 99%

In vivo amyloid-like fibrils produced under stress

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Rosse

Watts

et al. 2021

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The participation of amyloids in neurodegenerative diseases and in functional processes has triggered the quest for methods allowing their direct detection in vivo. Despite the plethora of data, those methods are still lacking. We used the autofluorescence from the extended β-sheets of amyloids to follow fibrillation of S. cerevisiae Golgi Reassembly and Stacking Protein (Grh1). Grh1 has been implicated in starvation-triggered unconventional protein secretion (UPS) and here we suggest the idea of its participation also in heat shock response (HSR). Fluorescence Lifetime Imaging (FLIM) was 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 was further supported by size exclusion chromatography and ultracentrifugation. Our data show 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.

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Section: Introductionmentioning

confidence: 99%

In vivo amyloid-like fibrils produced under stress

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Rosse

Watts

et al. 2021

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“…The strand 2 and the helix 2 form the binding groove of GRASP's PDZs [ 12,45,46 ]. Interestingly, the GRASP promiscuous interactome was previously suggested as a direct outcome of the somewhat low stability and high flexibility of the 2 helix in the PDZ1, a region enriched in high configurational frustration (Figure 2B) [ 25 ].…”

Section: The Distribution Of Coevolving Residues and Frustration Explains Metazoa's Grasp-golgin Specificitymentioning

confidence: 81%

“…It comes as quite a surprise that there is still a significant gap in understanding how GRASPs can perform those functionalities. The second portion of the GRASP's structure, the so-called Serine and Proline-Rich (SPR) domain, has a regulatory function [ 15 ] and presents a very low sequence identity even for closely related species [ 25 ].…”

Section: Introductionmentioning

confidence: 99%

“…The N-terminal one, called the GRASP domain (DGRASP), is formed by two PDZ subdomains with an unusual circular permutation in eukaryotes, making them resemble prokaryotic PDZs [ 24 ]. The PDZs are connected in tandem to allow rigid body reorganization, facilitating their interaction with multiple different protein partners [ 25 ]. This promiscuity for interaction with several different protein partners and their unusual structural plasticity [ 26,27 ] might be the convergent features of GRASPs in different cell functional tasks, including as anchoring factors of Golgins [ 12,15,23 ], their direct participation in Golgi dynamics during mitotic and apoptotic times [ [28][29][30] and their self-association during stress conditions triggering UPS [ 4,31 ].…”

Section: Introductionmentioning

confidence: 99%

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Resurrecting Golgi proteins to grasp Golgi ribbon formation and self-association under stress

Mendes

Batista

Kava

et al. 2021

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The Golgi complex is a membranous organelle located in the heart of the eukaryotic secretory pathway. A subfamily of the Golgi matrix proteins, called GRASPs, are key players in the stress-induced unconventional secretion, the Golgi dynamics during mitosis/apoptosis, and Golgi ribbon formation. The Golgi ribbon is vertebrate-specific and correlates with the appearance of two GRASP paralogs (GRASP55/GRASP65) and two coiled-coil Golgins (GM130/Golgin45), which interact with each other in vivo. Although essential for the Golgi ribbon formation and the increase in Golgi structural complexity, the molecular details leading to their appearance only in this subphylum are still unknown. Moreover, despite the new functionalities supported by the GRASP paralogy, little is known about the structural and evolutionary differences between these paralogues. In this context, we used ancestor sequence reconstruction and several biophysical/biochemical approaches to assess the evolution of the GRASP structure, flexibility, and how they started anchoring their Golgin partners. Our data showed that the Golgins appeared in evolution and were anchored by the single GRASP ancestor before gorasp gene duplication and divergence in Metazoans. After the gorasp divergence, variations inside the GRASP binding pocket determined which paralogue would recruit each Golgin partner (GRASP55 with Golgin45 and GRASP65 with GM130). These interactions are responsible for the protein's specific Golgi locations and the appearance of the Golgi ribbon. We also suggest that the capacity of GRASPs to form supramolecular structures is a long-standing feature, which likely affects GRASP's participation as a trigger of the stress-induced secretory pathway.

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“…The highly conserved GRASP domain (DGRASP) is myristoylated at the glycine 2 (Gly2) and anchored to the Golgi membranes (Jarvela and Linstedt 2012). DGRASP is, in turn, formed by two PDZ ( P SD95/ D lgA/ Z o-1) sub-domains(Mendes et al 2020), conventionally named PDZ 1 and 2. The interaction between GRASPs and their golgin partners involves the participation of the C-terminal region of the golgin that interacts at two distinctsites in DGRASP concurrently: the canonical peptide-binding groove of the PDZ1 and additional residues located either on the surface of the PDZ2 or in the region connecting both subdomains (Hu et al 2015; Zhao et al 2017).…”

Section: Introductionmentioning

confidence: 99%

Myristoylation and its effects on the human Golgi Reassembly and Stacking Protein 55

Kava

Mendes

Batista

et al. 2021

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GRASP55 is a myristoylated protein localized in the medial/trans-Golgi faces and involved in the Golgi structure maintenance and the regulation of unconventional secretion pathways. It is believed that GRASP55 achieves its main functionalities in the Golgi organization by acting as a tethering factor and, when bound to the lipid bilayer, its orientation relative to the membrane surface is restricted to determine its proper trans-oligomerization. Despite the paramount role of myristoylation in GRASP function, the impact of such protein modification on the membrane-anchoring properties and the structural organization of GRASP remains elusive. Here, an optimized protocol for the myristoylation in E. coli of the membrane-anchoring domain of GRASP55 is presented. The biophysical properties of the myristoylated/non-myristoylated GRASP55 GRASP domain were characterized in a membrane-mimicking micellar environment. Although myristoylation did not cause any impact on the protein's secondary structure, according to our circular dichroism data, it had a significant impact on the protein's thermal stability and solubility. Electrophoresis of negatively charged liposomes incubated with the two GRASP55 constructions showed different electrophoretic mobility for the myristoylated anchored protein only, thus demonstrating that myristoylation is essential for the biological membrane anchoring. Molecular dynamics simulations were used to further explore the anchoring process in determining the restricted orientation of GRASPs in the membrane.

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Conformational flexibility of GRASPs and their constituent PDZ subdomains reveals structural basis of their promiscuous interactome

Cited by 11 publications

References 84 publications

In vivo amyloid-like fibrils produced under stress

In vivo amyloid-like fibrils produced under stress

Resurrecting Golgi proteins to grasp Golgi ribbon formation and self-association under stress

Myristoylation and its effects on the human Golgi Reassembly and Stacking Protein 55

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