GRASP55, a second mammalian GRASP protein involved in the stacking of Golgi cisternae in a cell-free system.

We have identified a 55 kDa protein, named GRASP55 (Golgi reassembly stacking protein of 55 kDa), as a component of the Golgi stacking machinery. GRASP55 is homologous to GRASP65, an N-ethylmaleimide-sensitive membrane protein required for the stacking of Golgi cisternae in a cell-free system. GRASP65 exists in a complex with the vesicle docking protein receptor GM130 to which it binds directly, and the membrane tethering protein p115, which also functions in the stacking of Golgi cisternae. GRASP55 binding to GM130, could not be detected using biochemical methods, although a weak interaction was detected with the yeast two-hybrid system. Cryo-electron microscopy revealed that GRASP65, like GM130, is present on the cis-Golgi, while GRASP55 is on the medial-Golgi. Recombinant GRASP55 and antibodies to the protein block the stacking of Golgi cisternae, which is similar to the observations made for GRASP65. These results demonstrate that GRASP55 and GRASP65 function in the stacking of Golgi cisternae.     

GM130 and GRASP65-dependent lateral cisternal fusion allows uniform Golgi-enzyme distribution

The mammalian Golgi apparatus exists as stacks of cisternae that are laterally linked to form a continuous membrane ribbon, but neither the molecular requirements for, nor the purpose of, Golgi ribbon formation are known. Here, we demonstrate that ribbon formation is mediated by specific membrane-fusion events that occur during Golgi assembly, and require the Golgi proteins GM130 and GRASP65. Furthermore, these GM130 and GRASP65-dependent lateral cisternal-fusion reactions are necessary to achieve uniform distribution of enzymes in the Golgi ribbon. The membrane continuity created by ribbon formation facilitates optimal processing conditions in the biosynthetic pathway.     

The multiple facets of the Golgi reassembly stacking proteins

The mammalian GRASPs (Golgi reassembly stacking proteins) GRASP65 and GRASP55 were first discovered more than a decade ago as factors involved in the stacking of Golgi cisternae. Since then, orthologues have been identified in many different organisms and GRASPs have been assigned new roles that may seem disconnected. In vitro, GRASPs have been shown to have the biochemical properties of Golgi stacking factors, but the jury is still out as to whether they act as such in vivo. In mammalian cells, GRASP65 and GRASP55 are required for formation of the Golgi ribbon, a structure which is fragmented in mitosis owing to the phosphorylation of a number of serine and threonine residues situated in its C-terminus. Golgi ribbon unlinking is in turn shown to be part of a mitotic checkpoint. GRASP65 also seems to be the key target of signalling events leading to re-orientation of the Golgi during cell migration and its breakdown during apoptosis. Interestingly, the Golgi ribbon is not a feature of lower eukaryotes, yet a GRASP homologue is present in the genome of Encephalitozoon cuniculi, suggesting they have other roles. GRASPs have no identified function in bulk anterograde protein transport along the secretory pathway, but some cargo-specific trafficking roles for GRASPs have been discovered. Furthermore, GRASP orthologues have recently been shown to mediate the unconventional secretion of the cytoplasmic proteins AcbA/Acb1, in both Dictyostelium discoideum and yeast, and the Golgi bypass of a number of transmembrane proteins during Drosophila development. In the present paper, we review the multiple roles of GRASPs.     

GRASPing for consensus about the Golgi apparatus

Cisternae of the Golgi apparatus adhere to each other to form stacks, which are aligned side by side to form the Golgi ribbon. Two proteins, GRASP65 and GRASP55, previously implicated in stacking of cisternae, are shown to be required for the formation of the Golgi ribbon.

IntroductionThe Golgi apparatus is an intermediate organelle along the secretory pathway that receives proteins and lipids (“cargo”) from the endoplasmic reticulum, covalently modifies them, and then exports them via transport vesicles for trafficking to the plasma membrane or other organelles. In most eukaryotic cells, disc-shaped membrane cisternae, each containing a distinct repertoire of cargo-processing enzymes, are stacked one on top of another to form the “Golgi stack,” a visual hallmark of the organelle (Fig. 1). The cisternae of the Golgi stack are polarized, with the compartment receiving endoplasmic reticulum–derived cargo termed the cis cisterna followed by the medial; trans; and finally, the trans-Golgi network. The physiological advantages conferred by stacking of Golgi cisternae are unclear, but it is thought to enhance the efficiencies of the sequential chemical modifications of glycoproteins and glycolipids during secretion. Cultured mammalian cells may possess more than 100 Golgi stacks, which are aligned side by side about the centrosome to form the “Golgi ribbon” (Fig. 1). Vesicles and tubules span the intervening, “noncompact” zones between stacks of cisternae, connecting analogous cisternae across the ribbon and thereby ensuring a homogeneous distribution of Golgi resident proteins among all cisternae. During mitosis, the Golgi ribbon is unlinked, the stacks are disassembled, and the cisternae are converted to vesicles and tubules; after cytokinesis, the process is reversed, and the Golgi is rebuilt. The dynamic nature of Golgi structure in interphase and mitotic cells implies the existence of a reversible mechanism that tethers Golgi cisternae to each other to form the stack and a mechanism that aligns and links the stacks into the ribbon.Open in a separate windowFigure 1.The organization of the Golgi apparatus in vertebrate cells. Individual stacks of Golgi cisternae are aligned side to side to form the Golgi ribbon. The GRASP65 and GRASP55 proteins are depicted to be enriched on the rims of the indicated cisternae within individual stacks of cisternae, where they are required to maintain the arrangement of stacks into the ribbon.GRASP proteins tether Golgi cisternae in vitroInvestigations into the molecular basis of Golgi cisterna stacking have ultimately focused attention on a handful of cytoplasmic proteins called “Golgins” and “GRASPs” that are associated with specific Golgi cisternae and interact with each other. Of particular interest are two related proteins GRASP65 and GRASP55 (respective systematic names GORASP1 and GORASP2), discovered by Warren and colleagues via in vitro reconstitution experiments, as capable of mediating stacking of Golgi cisternae (Barr et al., 1997; Shorter et al., 1999). Whereas GRASP65 localizes to the cis cisterna, GRASP55 localization favors medial/trans Golgi cisternae (Shorter et al., 1999); hence, these proteins could, in principle, tether cisternae to form a minimal Golgi stack. In these in vitro assays, perturbations (mutations, antibody interference) to either GRASP65 or GRASP55 inhibited stacking of reformed Golgi cisternae. Moreover, GRASP proteins are phosphorylated in mitosis just before vesiculation of Golgi cisternae, and preventing phosphorylation impairs the disassembly of the Golgi apparatus and mitotic progression (Wang et al., 2003). These findings underpin models of the Golgi stack where GRASP65 and GRASP55, along with Golgin proteins, constitute the core components of a cytoplasmic “matrix” of proteins that surround the cisternae, mediating their stacking as well as the tethering of transport vesicles to cisternae. Curiously, plant cells contain stacked Golgi cisternae, yet they do not express any GRASP or GRASP-related proteins. And some nonvertebrate organisms with stacked Golgi cisternae express just one GRASP-related protein, while the Golgi cisternae are not stacked in other nonvertebrate organisms (e.g., yeast) that express a single GRASP (Glick and Malhotra, 1998). Apparently, the presence or number of GRASP proteins expressed does not correlate with stacked cisternae.Whereas the results of in vitro biochemical assays underpin our conceptions of GRASP protein function, probing their roles in vivo has proven to be quite challenging. First, depletion/deletion of each individual GRASP protein is largely without effect on Golgi stack or ribbon formation, but a very complex phenotype results from depletion/deletion of both GRASP proteins. Thus, some reports conclude that the GRASP proteins function redundantly to stack cisternae (Bekier et al., 2017), while others conclude that the Golgi ribbon, not the stack per se, is perturbed upon loss of GRASP proteins (Puthenveedu et al., 2006; Feinstein and Linstedt, 2008; Xiang and Wang, 2010; Lee et al., 2014; Veenendaal et al., 2014). Recently, two papers published in the Journal of Cell Biology employed different methodologies to perturb GRASP protein functions in vivo (Grond et al., 2020; Zhang and Seemann, 2021), providing the most conclusive insight to date into the roles of GRASP proteins in Golgi structure.The Golgi ribbon is unlinked upon loss of GRASP proteinsRabouille and colleagues used traditional mouse gene knockout technology to delete GRASP65, finding that such mice are viable with no apparent physiological deficits or gross morphological perturbations of the Golgi (Veenendaal et al., 2014). In their recent study (Grond et al., 2020), GRASP55 was deleted in the GRASP65 null background, but double-knockout mice could not be obtained, consistent with GRASP proteins being at least partially physiologically redundant. Next, using a conditional knockout approach, double GRASP null cells were produced postnatally in the small intestine, and the Golgi of intestinal epithelial cells was examined. In these cells, stacked Golgi cisternae were observed, but their arrangement into a ribbon was compromised, a result corroborated by more detailed analysis of cells in organoid cultures. These findings are at odds with the conclusions of Wang and colleagues (Bekier et al., 2017), who used CRISPR-Cas9 gene editing technology to construct cultured mammalian cell lines that do not express GRASP65 and GRASP55. They found that the appearance of Golgi cisternae was grossly altered, resembling clusters of tubules and vesicles (“tubulovesicular clusters”) about swollen cisterna remnants that debatably appeared to be stacked. One possible reason for the disparities between these two studies is that Bekier et al. (2017) documented that loss of GRASP proteins in cultured mammalian cells also resulted in depletion of a subset of Golgin proteins (e.g., GM130, Golgin-45) from Golgi cisternae, so it was not possible to parse the specific contributions of GRASP proteins to Golgi structure.Analyses of siRNA-depleted and gene-edited cell lines and modified animals are often complicated by incomplete depletion of a query protein, unintended loss of other proteins, or compensatory processes that obscure loss-of-function effects. Notably, siRNA depletion of GM130, which is associated with GRASP65 on the cis cisterna, impairs secretory traffic from the endoplasmic reticulum to the Golgi apparatus, resulting in a reduction in the size of Golgi cisternae and diminished interstack connectivity possibly due to vesiculation of cisternae (Seemann et al., 2000; Puthenveedu et al., 2006). To minimize these drawbacks, Zhang and Seemann (2021) used gene editing to modify the GRASP65 and GRASP55 loci to append an inducible protein degradation domain to each protein in cultured mammalian cells, which was used to elicit degradation of the GRASP proteins within just 2 h. Hence, the acute effects of GRASP protein depletion could be determined before the onset of potentially confounding effects. Fluorescence recovery after photobleaching assays of a fluorescently tagged Golgi resident protein revealed that acute depletion of both GRASP65 and GRASP55 resulted in decreased mobility of the resident Golgi enzyme within the ribbon, indicating that connectivity of cisternae between stacks was compromised. Stacks of Golgi cisternae with proper cis–trans polarity were observed by electron and light microscopy, both shortly (∼2 h) after GRASP protein turnover was initiated, and after mitosis, indicating that GRASP proteins are not required to establish or to maintain the Golgi stacks. Importantly, the authors observed no changes in the levels of GRASP-associated proteins (e.g., GM130) when assayed shortly after initiating GRASP protein turnover, but the amounts of several GRASP-associated proteins were reduced after prolonged growth in the absence of GRASP proteins. The results are in general agreement with experiments by Jarvela and Linstedt (2014), who expressed GRASP65 and GRASP55 fusion proteins appended with “killer RFP” and used chomophore-assisted light inactivation to rapidly (1 min) ablate the proteins in cultured mammalian cells. Similar to Zhang and Seemann (2021), they observed that the Golgi ribbon was disassembled upon inactivation of GRASP proteins, but stacking of cisternae was unaffected. Taken together, these results conclusively show that acute depletion of GRASP65 and GRASP55 impairs lateral linking of stacked Golgi cisternae within the ribbon while not affecting stacking of cisternae.Conclusions and perspectivesA body of work now more than 20 years old has shown that GRASP65 and GRAPS55 are core structural components of a matrix of cytoplasmic proteins associated with Golgi cisternae; however, the Grond et al. (2020) and Zhang and Seemann (2021) reports now firmly establish that GRASP proteins are dispensable for stacking of Golgi cisterna and indicate that they are required for linking Golgi stacks within the ribbon. These new studies suggest that the integrity of the Golgi matrix critically depends on the presence of GRASP proteins, and their absence perturbs the balance of cargo flow through the Golgi, reducing the interstack exchange required to maintain connectivity of stacks within the ribbon. How might GRASP proteins facilitate linking of stacks within the Golgi ribbon? When the ribbon is disrupted (using the microtubule depolymerizing reagent nocodazole) and individual Golgi stacks are examined, GRASP65 and GRASP55 appear to be enriched at the rims of Golgi cisternae (Fig. 1; Tie et al., 2018). Hence, the GRASP proteins are positioned at the vesicle-rich interface between adjacent cisternal stacks. Grond et al. (2020) observed reductions in the size of Golgi cisternae in cells deleted of both GRASP proteins and speculated that this may be due to increased coatomer I vesicle formation at the rims of cisternae. In this view, GRASP proteins dampen vesicle flux at the rims of Golgi cisternae, a model supported by the observation that depletion of GRASP proteins leads to an increase in secretion rate (Wang et al., 2008). These new studies firmly shift our view of GRASP protein function away from the stacking of Golgi cisternae, and we look forward to new mechanistic insights into the roles of GRASP proteins in Golgi ribbon formation as well as in non–Golgi-dependent processes, such as unconventional protein secretion (Kinseth et al., 2007).     

Isoform-specific tethering links the Golgi ribbon to maintain compartmentalization

Homotypic membrane tethering by the Golgi reassembly and stacking proteins (GRASPs) is required for the lateral linkage of mammalian Golgi ministacks into a ribbon-like membrane network. Although GRASP65 and GRASP55 are specifically localized to cis and medial/trans cisternae, respectively, it is unknown whether each GRASP mediates cisternae-specific tethering and whether such specificity is necessary for Golgi compartmentalization. Here each GRASP was tagged with KillerRed (KR), expressed in HeLa cells, and inhibited by 1-min exposure to light. Significantly, inactivation of either GRASP unlinked the Golgi ribbon, and the immediate effect of GRASP65-KR inactivation was a loss of cis- rather than trans-Golgi integrity, whereas inactivation of GRASP55-KR first affected the trans- and not the cis-Golgi. Thus each GRASP appears to play a direct and cisternae-specific role in linking ministacks into a continuous membrane network. To test the consequence of loss of cisternae-specific tethering, we generated Golgi membranes with a single GRASP on all cisternae. Remarkably, the membranes exhibited the full connectivity of wild-type Golgi ribbons but were decompartmentalized and defective in glycan processing. Thus the GRASP isoforms specifically link analogous cisternae to ensure Golgi compartmentalization and proper processing.     

Mena–GRASP65 interaction couples actin polymerization to Golgi ribbon linking

In mammalian cells, the Golgi reassembly stacking protein 65 (GRASP65) has been implicated in both Golgi stacking and ribbon linking by forming trans-oligomers through the N-terminal GRASP domain. Because the GRASP domain is globular and relatively small, but the gaps between stacks are large and heterogeneous, it remains puzzling how GRASP65 physically links Golgi stacks into a ribbon. To explore the possibility that other proteins may help GRASP65 in ribbon linking, we used biochemical methods and identified the actin elongation factor Mena as a novel GRASP65-binding protein. Mena is recruited onto the Golgi membranes through interaction with GRASP65. Depleting Mena or disrupting actin polymerization resulted in Golgi fragmentation. In cells, Mena and actin were required for Golgi ribbon formation after nocodazole washout; in vitro, Mena and microfilaments enhanced GRASP65 oligomerization and Golgi membrane fusion. Thus Mena interacts with GRASP65 to promote local actin polymerization, which facilitates Golgi ribbon linking.     

A direct role for GRASP65 as a mitotically regulated Golgi stacking factor

Cell-free assays that mimic the disassembly and reassembly cycle of the Golgi apparatus during mitosis implicated GRASP65 as a mitotically regulated stacking factor. We now present evidence that GRASP65 is directly involved in stacking Golgi cisternae. GRASP65 is the major phosphorylation target in rat liver Golgi membranes of two mitotic kinases, cdc2-cyclin B and polo-like kinases, which alone will unstack Golgi membranes, generating single cisternae. Mitotic cells microinjected with antibodies to GRASP65 fail to form proper Golgi stacks after cell division. Beads coated with GRASP65 homodimers form extensive aggregates consistent with the formation of trans oligomers. These can be disaggregated using purified cdc2-cyclin B1 and polo-like kinases, and re-aggregated after dephosphorylation of GRASP65. Together, these data demonstrate that GRASP65 has the properties required to bind surfaces together in a mitotically regulated manner.     

A GRASP55-rab2 effector complex linking Golgi structure to membrane traffic.

Membrane traffic between the endoplasmic reticulum (ER) and Golgi apparatus and through the Golgi apparatus is a highly regulated process controlled by members of the rab GTPase family. The GTP form of rab1 regulates ER to Golgi transport by interaction with the vesicle tethering factor p115 and the cis-Golgi matrix protein GM130, also part of a complex with GRASP65 important for the organization of cis-Golgi cisternae. Here, we find that a novel coiled-coil protein golgin-45 interacts with the medial-Golgi matrix protein GRASP55 and the GTP form of rab2 but not other Golgi rab proteins. Depletion of golgin-45 disrupts the Golgi apparatus and causes a block in secretory protein transport. These results demonstrate that GRASP55 and golgin-45 form a rab2 effector complex on medial-Golgi essential for normal protein transport and Golgi structure.     

GRASP65 and GRASP55 Sequentially Promote the Transport of C-terminal Valine-bearing Cargos to and through the Golgi Complex

The Golgi matrix proteins GRASP65 and GRASP55 have recognized roles in maintaining the architecture of the Golgi complex, in mitotic progression and in unconventional protein secretion whereas, surprisingly, they have been shown to be dispensable for the transport of commonly used reporter cargo proteins along the secretory pathway. However, it is becoming increasingly clear that many trafficking machineries operate in a cargo-specific manner, thus we have investigated whether GRASPs may control the trafficking of selected classes of cargo. We have taken into consideration the C-terminal valine-bearing receptors CD8α and Frizzled4 that we show bind directly to the PSD95-DlgA-zo-1 (PDZ) domains of GRASP65 and GRASP55. We demonstrate that both GRASPs are needed sequentially for the efficient transport to and through the Golgi complex of these receptors, thus highlighting a novel role for the GRASPs in membrane trafficking. Our results open new perspectives for our understanding of the regulation of surface expression of a class of membrane proteins, and suggests the causal mechanisms of a dominant form of autosomal human familial exudative vitreoretinopathy that arises from the Frizzled4 mutation involving its C-terminal valine.     

The Role of GRASP65 in Golgi Cisternal Stacking and Cell Cycle Progression

In vitro assays identified the Golgi peripheral protein GRASP65 as a Golgi stacking factor that links adjacent Golgi cisternae by forming mitotically regulated trans‐oligomers. These conclusions, however, require further confirmation in the cell. In this study, we showed that the first 112 amino acids at the N‐terminus (including the first PDZ domain, PDZ1) of the protein are sufficient for oligomerization. Systematic electron microscopic analysis showed that the expression of non‐regulatable GRASP65 mutants in HeLa cells enhanced Golgi stacking in interphase and inhibited Golgi fragmentation during mitosis. Depletion of GRASP65 by small interference RNA (siRNA) reduced the number of cisternae in the Golgi stacks; this reduction was rescued by expressing exogenous GRASP65. These results provided evidence and a molecular mechanism by which GRASP65 stacks Golgi cisternal membranes. Further experiments revealed that inhibition of mitotic Golgi disassembly by expressing non‐regulatable GRASP65 mutants did not affect equal partitioning of the Golgi membranes into the daughter cells. However, it delayed mitotic entry and suppressed cell growth; this effect was diminished by dispersing the Golgi apparatus with Brefeldin A treatment prior to mitosis, suggesting that Golgi disassembly at the onset of mitosis plays a role in cell cycle progression.     

Structural Insight into Golgi Membrane Stacking by GRASP65 and GRASP55 Proteins

The stacking of Golgi cisternae involves GRASP65 and GRASP55. The oligomerization of the N-terminal GRASP domain of these proteins, which consists of two tandem PDZ domains, is required to tether the Golgi membranes. However, the molecular basis for GRASP assembly is unclear. Here, we determined the crystal structures of the GRASP domain of GRASP65 and GRASP55. The structures reveal similar homotypic interactions: the GRASP domain forms a dimer in which the peptide-binding pockets of the two neighboring PDZ2 domains face each other, and the dimers are further connected by the C-terminal tail of one GRASP domain inserting into the binding pocket of the PDZ1 domain in another dimer. Biochemical analysis suggests that both types of contacts are relatively weak but are needed in combination for GRASP-mediated Golgi stacking. Our results unveil a novel mode of membrane tethering by GRASP proteins and provide insight into the mechanism of Golgi stacking.     

GRASP65 controls Golgi position and structure during G2/M transition by regulating the stability of microtubules

The mammalian Golgi apparatus is organized in the form of a ribbon‐like structure positioned near the centrosome. Despite its multimodular organization, the Golgi complex is characterized by a prominent structural plasticity, which is crucial during essential physiological processes, such as the G2 phase of the cell cycle, during which the Golgi ribbon must be “unlinked” into isolated stacks to allow progression into mitosis. Here we show that the Golgi‐associated protein GRASP65, which is well known for its role in Golgi stacking and ribbon formation, is also required for the organization of the microtubule cytoskeleton. GRASP65 is not involved in microtubule nucleation or anchoring. Instead, it is required for the stabilization of newly nucleated microtubules, leading to their acetylation and clustering of Golgi stacks. Ribbon formation and microtubule stabilization are both regulated by JNK/ERK‐mediated phosphorylation of S274 of GRASP65, suggesting that this protein can coordinate the Golgi structure with microtubule organization. In agreement with an important role, tubulin acetylation is strongly reduced during the G2 phase of the cell cycle, allowing the separation of the Golgi stacks. Thus, our data reveal a fundamental role of GRASP65 in the integration of different stimuli to modulate Golgi structure and microtubule organization during cell division.     

GRASP55 regulates Golgi ribbon formation

Recent work indicates that mitogen-activated protein kinase kinase (MEK)1 signaling at the G2/M cell cycle transition unlinks the contiguous mammalian Golgi apparatus and that this regulates cell cycle progression. Here, we sought to determine the role in this pathway of Golgi reassembly protein (GRASP)55, a Golgi-localized target of MEK/extracellular signal-regulated kinase (ERK) phosphorylation at mitosis. In support of the hypothesis that GRASP55 is inhibited in late G2 phase, causing unlinking of the Golgi ribbon, we found that HeLa cells depleted of GRASP55 show a fragmented Golgi similar to control cells arrested in G2 phase. In the absence of GRASP55, Golgi stack length is shortened but Golgi stacking, compartmentalization, and transport seem normal. Absence of GRASP55 was also sufficient to suppress the requirement for MEK1 in the G2/M transition, a requirement that we previously found depends on an intact Golgi ribbon. Furthermore, mimicking mitotic phosphorylation of GRASP55 by using aspartic acid substitutions is sufficient to unlink the Golgi apparatus in a gene replacement assay. Our results implicate MEK1/ERK regulation of GRASP55-mediated Golgi linking as a control point in cell cycle progression.     

Structural Basis for the Interaction between the Golgi Reassembly-stacking Protein GRASP65 and the Golgi Matrix Protein GM130

GM130 and GRASP65 are Golgi peripheral membrane proteins that play a key role in Golgi stacking and vesicle tethering. However, the molecular details of their interaction and their structural role as a functional unit remain unclear. Here, we present the crystal structure of the PDZ domains of GRASP65 in complex with the GM130 C-terminal peptide at 1.96-Å resolution. In contrast to previous findings proposing that GM130 interacts with GRASP65 at the PDZ2 domain only, our crystal structure of the complex indicates that GM130 binds to GRASP65 at two distinct sites concurrently and that both the PDZ1 and PDZ2 domains of GRASP65 participate in this molecular interaction. Mutagenesis experiments support these structural observations and demonstrate that they are required for GRASP65-GM130 association.     

dGRASP localization and function in the early exocytic pathway in Drosophila S2 cells

The de novo model for Golgi stack biogenesis predicts that membrane exiting the ER at transitional ER (tER) sites contains and recruits all the necessary molecules to form a Golgi stack, including the Golgi matrix proteins, p115, GM130, and GRASP65/55. These proteins leave the tER sites faster than Golgi transmembrane resident enzymes, suggesting that they act as a template nucleating the formation of the Golgi apparatus. However, the localization of the Golgi matrix proteins at tER sites is only shown under conditions where exit from the ER is blocked. Here, we show in Drosophila S2 cells, that dGRASP, the single Drosophila homologue of GRASP65/55, localizes both to the Golgi membranes and the tER sites at steady state and that the myristoylation of glycine 2 is essential for the localization to both compartments. Its depletion for 96 h by RNAi gave an effect on the architecture of the Golgi stacks in 30% of the cells, but a double depletion of dGRASP and dGM130 led to the quantitative conversion of Golgi stacks into clusters of vesicles and tubules, often featuring single cisternae. This disruption of Golgi architecture was not accompanied by the disorganization of tER sites or the inhibition of anterograde transport. This shows that, at least in Drosophila, the structural integrity of the Golgi stacks is not required for efficient transport. Overall, dGRASP exhibits a dynamic association to the membrane of the early exocytic pathway and is involved in Golgi stack architecture.     

Caspase-mediated cleavage of the stacking protein GRASP65 is required for Golgi fragmentation during apoptosis

The mammalian Golgi complex is comprised of a ribbon of stacked cisternal membranes often located in the pericentriolar region of the cell. Here, we report that during apoptosis the Golgi ribbon is fragmented into dispersed clusters of tubulo-vesicular membranes. We have found that fragmentation is caspase dependent and identified GRASP65 (Golgi reassembly and stacking protein of 65 kD) as a novel caspase substrate. GRASP65 is cleaved specifically by caspase-3 at conserved sites in its membrane distal COOH terminus at an early stage of the execution phase. Expression of a caspase-resistant form of GRASP65 partially preserved cisternal stacking and inhibited breakdown of the Golgi ribbon in apoptotic cells. Our results suggest that GRASP65 is an important structural component required for maintenance of Golgi apparatus integrity.     

Dynamics of Golgi matrix proteins after the blockage of ER to Golgi transport

When the ER to Golgi transport is blocked by a GTP-restricted mutant of Sar1p (H79G) in NRK-52E cells, most Golgi resident proteins are transported back into the ER. In contrast, the cis-Golgi matrix proteins GM130 and GRASP65 are retained in punctate cytoplasmic structures, namely Golgi remnants. Significant amounts of the medial-Golgi matrix proteins golgin-45, GRASP55 and giantin are retained in the Golgi remnants, but a fraction of these proteins relocates to the ER. Golgin-97, a candidate trans-Golgi network matrix protein, is retained in Golgi remnant-like structures, but mostly separated from GM130 and GRASP65. Interestingly, most Sec13p, a COPII component, congregates into larger cytoplasmic clusters soon after the microinjection of Sar1p(H79G), and these move to accumulate around the Golgi apparatus. Sec13p clusters remain associated with Golgi remnants after prolonged incubation. Electron microscopic analysis revealed that Golgi remnants are clusters of larger vesicles with smaller vesicles, many of which are coated. GM130 is mainly associated with larger vesicles and Sec13p with smaller coated vesicles. The Sec13p clusters disperse when p115 binding to the Golgi apparatus is inhibited. These results suggest that cis-Golgi matrix proteins resist retrograde transport flow and stay as true residents in Golgi remnants after the inhibition of ER to Golgi transport.     

The biogenesis of the Golgi ribbon: the roles of membrane input from the ER and of GM130

The Golgi complex in mammalian cells forms a continuous ribbon of interconnected stacks of flat cisternae. We show here that this distinctive architecture reflects and requires the continuous input of membranes from the endoplasmic reticulum (ER), in the form of pleiomorphic ER-to-Golgi carriers (EGCs). An important step in the biogenesis of the Golgi ribbon is the complete incorporation of the EGCs into the stacks. This requires the Golgi-matrix protein GM130, which continuously cycles between the cis-Golgi compartments and the EGCs. On acquiring GM130, the EGCs undergo homotypic tethering and fusion, maturing into larger and more homogeneous membrane units that appear primed for incorporation into the Golgi stacks. In the absence of GM130, this process is impaired and the EGCs remain as distinct entities. This induces the accumulation of tubulovesicular membranes, the shortening of the cisternae, and the breakdown of the Golgi ribbon. Under these conditions, however, secretory cargo can still be delivered to the Golgi complex, although this occurs less efficiently, and apparently through transient and/or limited continuities between the EGCs and the Golgi cisternae.     

The role of GRASP55 in Golgi fragmentation and entry of cells into mitosis

GRASP55 is a Golgi-associated protein, but its function at the Golgi remains unclear. Addition of full-length GRASP55, GRASP55-specific peptides, or an anti-GRASP55 antibody inhibited Golgi fragmentation by mitotic extracts in vitro, and entry of cells into mitosis. Phospho-peptide mapping of full-length GRASP55 revealed that threonine 225 and 249 were mitotically phosphorylated. Wild-type peptides containing T225 and T249 inhibited Golgi fragmentation and entry of cells into mitosis. Mutant peptides containing T225E and T249E, in contrast, did not affect Golgi fragmentation and entry into mitosis. These findings reveal a role of GRASP55 in events leading to Golgi fragmentation and the subsequent entry of cell into mitosis. Surprisingly, however, under our experimental conditions, >85% knockdown of GRASP55 did not affect the overall organization of Golgi organization in terms of cisternal stacking and lateral connections between stacks. Based on our findings we suggest that phosphorylation of GRASP55 at T225/T249 releases a bound component, which is phosphorylated and necessary for Golgi fragmentation. Thus, GRASP55 has no role in the organization of Golgi membranes per se, but it controls their fragmentation by regulating the release of a partner, which requires a G2-specific phosphorylation at T225/T249.     

A role for the vesicle tethering protein, p115, in the post-mitotic stacking of reassembling Golgi cisternae in a cell-free system.

During telophase, Golgi cisternae are regenerated and stacked from a heterogeneous population of tubulovesicular clusters. A cell-free system that reconstructs these events has revealed that cisternal regrowth requires interplay between soluble factors and soluble N-ethylmaleimide (NEM)-sensitive fusion protein (NSF) attachment protein receptors (SNAREs) via two intersecting pathways controlled by the ATPases, p97 and NSF. Golgi reassembly stacking protein 65 (GRASP65), an NEM-sensitive membrane-bound component, is required for the stacking process. NSF-mediated cisternal regrowth requires a vesicle tethering protein, p115, which we now show operates through its two Golgi receptors, GM130 and giantin. p97-mediated cisternal regrowth is p115-independent, but we now demonstrate a role for p115, in conjunction with its receptors, in stacking p97 generated cisternae. Temporal analysis suggests that p115 plays a transient role in stacking that may be upstream of GRASP65-mediated stacking. These results implicate p115 and its receptors in the initial alignment and docking of single cisternae that may be an important prerequisite for stack formation.