Golgi Membrane Fusion Research Articles

Structure, dynamics and interactions of p47, a major adaptor of the AAA ATPase, p97.

p47 is a major adaptor molecule of the cytosolic AAA ATPase p97. The principal role of the p97-p47 complex is in regulation of membrane fusion events. Mono-ubiquitin recognition by p47 has also been shown to be crucial in the p97-p47-mediated Golgi membrane fusion events. Here, we describe the high-resolution solution structures of the N-terminal UBA domain and the central domain (SEP) from p47. The p47 UBA domain has the characteristic three-helix bundle fold and forms a highly stable complex with ubiquitin. We report the interaction surfaces of the two proteins and present a structure for the p47 UBA-ubiquitin complex. The p47 SEP domain adopts a novel fold with a betabetabetaalphaalphabeta secondary structure arrangement, where beta4 pairs in a parallel fashion to beta1. Based on biophysical studies, we demonstrate a clear propensity for the self-association of p47. Furthermore, p97 N binding abolishes p47 self-association, revealing the potential interaction surfaces for recognition of other domains within p97 or the substrate.

In Vitro Fusion of Plant Golgi Membranes Can Be Influenced by Divalent Cations

The fusogenic activity of plant Golgi membranes was studied in a cell-free system by assaying lipid mixing and content leakages of fluorescence probes. Golgi membranes from mung bean (Vigna radiata L.) hypocotyl cells fused to liposomes in the absence of any cytosolic proteins and nucleotides. It was demonstrated that the fusion was mediated by integral membrane protein(s), and was influenced by divalent cations (mm). Mg(2+), Ca(2+), and Mn(2+) ions enhanced the lipid mixing by reducing repulsive forces between membranes. In the content leakage assay, Mg(2+) ions also showed a stimulative effect. However, other divalent cations were inhibitory. It is suggested that the fusion system of Golgi membranes comprises at least two components: one that mediates the formation of fusion intermediates prior to pore opening, and one that mediates the subsequent processes. The latter must be sensitive to divalent cations at millimolar concentrations. The fusion of Golgi and biological membranes was induced by divalent cations. We speculated about the biological role of the fusion system studied here.

Phospholipid species act as modulators in p97/p47-mediated fusion of Golgi membranes.

The ATPase p97 in complex with p47 participates in Golgi cisternae rebuilding after mitosis. In a Golgi-liposome assay, the complex triggered a phosphatidylethanolamine (PE)-promoted fusion. Here we show for the first time that fusion between mitotic Golgi membranes induced by adding cytosol or purified p97/p47 is modulated by PE present in Golgi membranes. Using model membranes, we demonstrate a PE-dependent recruitment of p97/p47 to membranes, causing dramatic conformational rearrangements and favoring protein-lipid interactions. Previously buried hydrophobic sites become exposed in a controlled manner, which leads to the penetration of (a) domain(s) of the complex into lipid bilayers, facilitated by a PE-dependent increase in headgroup spacing. In contrast, when facing phosphatidylcholine (PC) the complex clusters extensively. This implies that in the presence of PC protein-protein interactions rather than fusion-promoting protein-lipid interactions occur. Importantly, PE-mediated changes in secondary and tertiary structures are exclusively observed when p97 is complexed with p47, which is a prerequisite for membrane fusion. We therefore propose that at physiological conditions PE-induced conformational changes in p97/p47 are relevant in triggering this activity.

Ubiquitin Recognition and Chaperoning

The yeast transcription factor SPT23 is a homolog of the mammalian transcription factor nuclear factor-κB (NF-κB). In its immature form, SPT23 is a 120-kD protein tethered to the membrane of the endoplasmic reticulum (ER). The processing of p120 seems to involve the following: (i) ubiquitination and proteolytic cleavage to a mature 90-kD (p90) form, and (ii) the function of a protein complex consisting of CDC4--a protein involved in the post-mitotic fusion of Golgi membranes--and Udf1 and Npl4, which are thought to be involved in ubiquitin-dependent protein degradation and nuclear transport, respectively. However, the mechanism of SPT23 activation is largely unresolved. Rape et al. have found that p120 SPT23 must homodimerize at the ER membrane, as the first step in maturation. Yeast two-hybrid assays showed that the minimal region that conferred homodimerization was the immunoglobulin (Ig)-like-plexins-transcription factors (IPT) domain, and that IPT domains could associate with each other, suggesting that an IPT-IPT interaction was necessary and sufficient for SPT23 homodimerization. One of the SPT23 monomers became ubiquitinated by the ubiquitin ligase RSP5. The proteasome proteolytically cleaved the stalk that tethers SPT23 to the ER membrane. However, the cleaved SPT23, now p90, remained stably associated with the unprocessed monomer, as demonstrated by washing with a gradient of low-to-high salt concentrations. The removal of mature p90 from the immature monomer required the ATP-dependent activity of CDC48, which could discriminate the ubiquitinated p90 from p120. Additionally, the translocation of p90 to the nucleus was also CDC48-dependent, suggesting that CDC48 may act as a ubiquitin-selective chaperone protein. M. Rape, T. Hoppe, I. Gorr, M. Kalocay, H. Richly, S. Jentsch, Mobilization of processed, membrane-tethered SPT23 transcription factor by CDC48 UFD1/NPL4 , a ubiquitin-selective chaperone. Cell 107 , 667-677 (2001). [Online Journal]

Distinct AAA-ATPase p97 complexes function in discrete steps of nuclear assembly.

Although nuclear envelope (NE) assembly is known to require the GTPase Ran, the membrane fusion machinery involved is uncharacterized. NE assembly involves formation of a reticular network on chromatin, fusion of this network into a closed NE and subsequent expansion. Here we show that p97, an AAA-ATPase previously implicated in fusion of Golgi and transitional endoplasmic reticulum (ER) membranes together with the adaptor p47, has two discrete functions in NE assembly. Formation of a closed NE requires the p97-Ufd1-Npl4 complex, not previously implicated in membrane fusion. Subsequent NE growth involves a p97-p47 complex. This study provides the first insights into the molecular mechanisms and specificity of fusion events involved in NE formation.

Actin microfilaments facilitate the retrograde transport from the Golgi complex to the endoplasmic reticulum in mammalian cells.

The morphology and subcellular positioning of the Golgi complex depend on both microtubule and actin cytoskeletons. In contrast to microtubules, the role of actin cytoskeleton in the secretory pathway in mammalian cells has not been clearly established. Using cytochalasin D, we have previously shown that microfilaments are not involved in the endoplasmic reticulum-Golgi membrane dynamics. However, it has been reported that, unlike botulinum C2 toxin and latrunculins, cytochalasin D does not produce net depolymerization of actin filaments. Therefore, we have reassessed the functional role of actin microfilaments in the early steps of the biosynthetic pathway using C2 toxin and latrunculin B. The anterograde endoplasmic reticulum-to-Golgi transport monitored with the vesicular stomatitis virus-G protein remained unaltered in cells treated with cytochalasin D, latrunculin B or C2 toxin. Conversely, the brefeldin A-induced Golgi membrane fusion into the endoplasmic reticulum, the Golgi-to-endoplasmic reticulum transport of a Shiga toxin mutant form, and the subcellular distribution of the KDEL receptor were all impaired when actin microfilaments were depolymerized by latrunculin B or C2 toxin. These findings, together with the fact that COPI-coated and uncoated vesicles contain beta/gamma-actin isoforms, indicate that actin microfilaments are involved in the endoplasmic reticulum/Golgi interface, facilitating the retrograde Golgi-to-endoplasmic reticulum membrane transport, which could be mediated by the orchestrated movement of transport intermediates along microtubule and microfilament tracks.

A complex of mammalian ufd1 and npl4 links the AAA-ATPase, p97, to ubiquitin and nuclear transport pathways.

The AAA-ATPase, p97/Cdc48p, has been implicated in many different pathways ranging from membrane fusion to ubiquitin-dependent protein degradation. Binding of the p47 complex directs p97 to act in the post-mitotic fusion of Golgi membranes. We now describe another binding complex comprising mammalian Ufd1 and Npl4. Yeast Ufd1p is required for ubiquitin-dependent protein degradation whereas yeast Npl4p has been implicated in nuclear transport. In rat liver cytosol, Ufd1 and Npl4 form a binary complex, which exists either alone or bound to p97. Ufd1/Npl4 competes with p47 for binding to p97 and so inhibits Golgi membrane fusion. This suggests that it is involved in another cellular function catalysed by p97, the most likely being ubiquitin-dependent events during mitosis. The fact that the binding of p47 and Ufd1/Npl4 is mutually exclusive suggests that these protein complexes act as adapters, directing a basic p97 activity into different cellular pathways.

An NSF function distinct from ATPase-dependent SNARE disassembly is essential for Golgi membrane fusion.

The precise biochemical role of N-ethylmaleimide-sensitive factor (NSF) in membrane fusion mediated by SNARE proteins is unclear. To provide further insight into the function of NSF, we have introduced a mutation into mammalian NSF that, in Drosophila dNSF-1, leads to temperature-sensitive neuroparalysis. This mutation is like the comatose mutation and renders the mammalian NSF temperature sensitive for fusion of postmitotic Golgi vesicles and tubules into intact cisternae. Unexpectedly, at the temperature that is permissive for membrane fusion, this mutant NSF binds to, but cannot disassemble, SNARE complexes and exhibits almost no ATPase activity. A well-charaterized NSF mutant containing an inactivating point mutation in the catalytic site of its ATPase domain is equally active in the Golgi-reassembly assay. These data indicate that the need for NSF during postmitotic Golgi membrane fusion may be distinct from its ATPase-dependent ability to break up SNARE pairs.

Transport between cis and medial Golgi Cisternae Requires the Function of the Ras-related Protein Rab6

The small GTP-binding protein Rab6, a member of the Ras superfamily, is localized on the membranes of the Golgi apparatus and the trans Golgi network. Recent studies revealed that the Rab6 protein might be involved in the transit of proteins through the Golgi complex. In this report we demonstrate the essential function of the Rab6 protein in a distinct step of reconstituted Golgi transport. Polyclonal antibodies and Fab fragments directed against the C-terminal part of the Rab6 protein inhibit transport between the cis and the medial Golgi cisternae. Inhibition also occurred when a trans-dominant mutant form of the Rab6 protein (N126I) was added to the reconstituted transport. Furthermore, Rab6 antibodies inhibit uncoupled fusion of Golgi membranes. From these data we conclude that Rab6 is involved in a process related to membrane fusion at the cisternal membranes of the Golgi apparatus and therefore is needed for the consumption of Golgi-derived vesicles by their target membranes.

In vitro fusion of rabbit liver Golgi membranes with liposomes.

Fusion of Golgi membranes isolated from rabbit liver with liposomes was studied by lipid mixing of fluorescent lipid analogues and internal content mixing and by electron microscopic observation of transfer of horseradish peroxidase from liposomes into Golgi membranes. A monoclonal antibody was used to confirm fusion of Golgi membranes but not other contaminating vesicles. Fusion was rapid and efficient, reaching about 20% of the maximum after a 5-min incubation using small or large unilamellar dioleoylphosphatidylcholine vesicles. The fusion was dependent on temperature, decreasing at lower temperatures, and becoming nearly zero below 10 degrees C. The addition of ATP, GTP, cytosolic factors, or N-ethylmaleimide did not affect fusion. Treatments of Golgi membranes with 0.1 M Na2CO3 or 1 M KCl did not cause any changes in fusion. However, treatment with proteases inhibited fusion. These results suggest that Golgi integral membrane protein(s) are involved in fusion. Changing the medium to an isoosmotic substance, sucrose, in place of KCl or NaCl inhibited fusion. The binding assay of fluorescent liposomes to Golgi membranes showed that lowering the temperature or replacing salts with sucrose did not affect binding. However, treatment of Golgi membranes with proteases inhibited binding. Addition of phosphatidylserine or phosphatidylethanolamine to dioleoylphosphatidylcholine liposomes caused a 2-fold increase in binding and fusion. Fusion between Golgi membranes by themselves did not occur. These results provide some information on the mechanism of intracellular vesicular transport.

Properties of a GTP sensitive microdomain in rough microsomes

Stripped rough microsomes (SRM) fuse when incubated with physiological concentrations of GTP and MgCl 2. In order to examine further to what extent such fusions are associated with other membrane functions of rough endoplasmic reticulum, we have evaluated the role of cytosolically exposed peptide constituents of SRM in fusion, and the possible relationship of GTP/MgCl 2-induced fusion in protein transport across endoplasmic reticulum (ER) membranes, and in ER-Golgi interactions. Controlled proteolytic digestion of SRM led to the loss of fusion capability at 15 μg/ml trypsin - a concentration which maintained the latency of intraluminal mannose-6-phosphatase. Hence, a cytosolically exposed protein(s) regulated fusion. Based on ribonuclease-induced ribosome capping experiments, it was further concluded that the cytosolic oriented protein(s) was sequestered beneath the ribosome. As co-translational cell free translocation of placental lactogen across SRM was similar in control membranes compared to those rendered incapable of fusing, it was concluded that the fusion phenomenon may not be related to translocation. Under conditions promoting homologous fusion of SRM or Golgi membranes, mixtures of the two membranes showed no heterologous membrane fusion as assessed morphologically or by the transport of newly synthesized membrane glycoprotein. These experiments attest to the specificity of cytosolically exposed protein(s) in regulating nucleotide/divalent cation-induced membrane fusion.

Terminal glycosylation in rat hepatic Golgi fractions: heterogeneous locations for sialic acid and galactose acceptors and their transferases

Endogenous acceptors for N- acetylglucosamine (GlcNAc), galactose (Gal) or sialic acid (NeuAc) transfer were labeled to high activities when purified hepatic Golgi fractions were incubated with the corresponding radiolabeled nucleotide sugar in the absence of detergent. The in vitro conditions which were optimal for the endogenous glycosylation of GlcNAc and Gal acceptors (Mn 2+, ATP) also promoted fusion within a subset of Golgi membranes. Electron microscope radioautography revealed that the majority of NeuAc acceptors were associated with unfused Golgi membranes, whereas the majority of Gal acceptors were localized to fused membranes. GlcNAc acceptors were approximately equally distributed between fused and unfused membranes. Under conditions in which Golgi membrane fusion was absent (− Mn 2+), only NeuAc transfer was active. The majority of endogenous NeuAc acceptors were consequently assigned to the more trans regions of the hepatic Golgi apparatus as concluded from a combination of radioautography (NeuAc transfer) and acid NADPase cytochemistry (reactive medial and trans Golgi saccules). The distribution of NeuAc and Gal transferases was assessed after Percoll gradient centrifugation of disrupted Golgi fractions. The median density of NeuAc transferase was lower than that of Gal transferase. The studies are indicative of distinct Golgi components harboring the majority of acceptors and enzymes for terminal glycosylation.

Membrane fusion and glycosylation in the rat hepatic Golgi apparatus.

When purified Golgi fractions were incubated with UDP-[3H]galactose in the absence of Triton-X-100, radioactivity was incorporated into an endogenous lipid and several peptide acceptors. Electron microscope analysis of Golgi fractions incubated in the endogenous galactosyl transferase assay medium revealed extensive fusion of Golgi saccules. Systematic removal of constituents in the galactosyl transferase assay medium showed enhanced (minus beta-mercaptoethanol) or reduced (minus ATP, minus sodium cacodylate buffer or minus MnCl2) fusion of Golgi membranes compared to the complete medium, Stereologic analysis revealed a correlation between membrane fusion and galactosyl transferase activity (r = 0.99, P less than 0.001). Electron microscope radioautography was carried out after incubation of Golgi fractions with UDP-[3H]galactose. Silver grains were not observed over trans elements of Golgi but were revealed mainly over large fused saccules with the number of silver grains being proportionate to membrane fusion (r = 0.92, P less than 0.001). Bilayer destabilization at points of Golgi membrane fusion may act to translocate galactose across the Golgi membrane and thereby provide a fusion regulated substrate for terminal glycosylation.

Insights into the Secretory Pathway, the Mechanism of Terminal Glycosylation and Intracellular Peptide Hormone Receptors from Studies on Hepatic Golgi Fractions

Recent studies on purified subcellular fractions of hepatic Golgi apparatus have provided insight into the functioning of the Golgi apparatusin vivo.The hepatocyte is the site of synthesis of most circulating plasma proteins. On a total protein basis, purified Golgi fractions revealed mainly secretory content (albumin, transferrin and other plasma proteins) as major constituents. After anin vivoinjection of radiolabeled leucine, newly synthesized secretory protein followed a temporal route fromcistotransregions of Golgi apparatus before appearance in the plasma. This route was revealed by studies on disrupted Golgi fractions enriched in disparate regions of the Golgi apparatus.The terminal glycosylation of secretory glcyoproteins (e.g. transferrin) can be studied by observing the transfer of UDP-(3H)-galactose to endogenous acceptors within Golgi fractions. Transfer was shown to occur to a glycolipid (dolichyl galactosyl phosphate) probably on the cytosolic aspect of the Golgi membrane. Translocation of the labeled galactose across the membrane coincided with fusion of Golgi sacculesin vitro. It is felt that during the process of Golgi membrane fusion, inverted lipid- micellar membrane structures translocate the dolichyl galactosyl phosphate from a cytosolic to a luminal orientation. Luminally oriented dolichyl galactosyl phosphate would then serve as substrate for galactose transfer to intraluminal glycopeptide acceptors via intraluminal galactosyl transferase enzyme.