Subunit interactions in the clathrin-coated vesicle vacuolar (H(+))-ATPase complex.

The vacuolar (H(+))-ATPases (or V-ATPases) are structurally related to the F(1)F(0) ATP synthases of mitochondria, chloroplasts and bacteria, being composed of a peripheral (V(1)) and an integral (V(0)) domain. To further investigate the arrangement of subunits in the V-ATPase complex, covalent cross-linking has been carried out on the V-ATPase from clathrin-coated vesicles using three different cross-linking reagents. Cross-linked products were identified by molecular weight and by Western blot analysis using polyclonal antibodies raised against individual V-ATPase subunits. In the intact V(1)V(0) complex, evidence for cross-linking of subunits C and E, D and F, as well as E and G by disuccinimidyl glutarate was obtained, while in the free V(1) domain, cross-linking of subunits H and E was also observed. Subunits C and E as well as D and E could be cross-linked by 1-ethyl-3-(dimethylaminopropyl)carbodiimide, while subunits a and E could be cross-linked by 4-(N-maleimido)benzophenone. It was further demonstrated that it is possible to treat the V-ATPase with potassium iodide and MgATP in such a way that while subunits A, B, and H are nearly quantitatively removed, significant amounts of subunits C, D, E, and F remain attached to the membrane, suggesting that one or more of these latter subunits are in contact with the V(0) domain. In addition, treatment of the V-ATPase with cystine, which modifies Cys-254 of the catalytic A subunit, results in dissociation of subunit H, suggesting communication between the catalytic nucleotide binding site and subunit H. Finally, the stoichiometry of subunits F, G, and H were determined by quantitative amino acid analysis. Based on these and previous observations, a new structural model of the V-ATPase from clathrin-coated vesicles is proposed.     

Targeting and mistargeting of plasma membrane adaptors in vitro

Targeting and recruitment of the plasma membrane (PM) clathrin-coated vesicle adaptor complexes has been studied using an in vitro system based on permeabilized acceptor cells and donor cytosol. Through the use of species- and/or tissue-specific antibodies, only newly recruited exogenous PM adaptors are visualized. Targeting of PM adaptors can be switched from the plasma membrane to a perinuclear compartment by GTP gamma S or excess calcium. Prior treatment with brefeldin A prevents GTP gamma S-induced mistargeting. Double-labeling immunofluorescence and immunogold EM indicate that the perinuclear PM adaptor binding compartment is late endosomal. We propose that receptors for PM adaptors cycle between the plasma membrane and an endosomal storage compartment. Normally the receptors would be switched on only at the plasma membrane, but both GTP gamma S and calcium are capable of reversing this switch. Intracellular sequestration of PM adaptor receptors may provide the cell with a mechanism for up-regulating endocytosis following a burst of exocytosis.     

In vivo phosphorylation of clathrin-coated vesicle proteins from rat reticulocytes

We have studied the in vivo phosphorylation of clathrin-coated vesicle proteins from rat reticulocytes. The major 32P-labeled polypeptides of clathrin-coated vesicles isolated from metabolically labeled cells were the the 165-, 100-110-, and 50-kDa polypeptides of the assembly protein, the clathrin beta-light chain, and to a lesser extent the clathrin alpha-light chain. The phosphorylation of the assembled (particulate) and unassembled (soluble) pools of clathrin and assembly protein was compared by immunoprecipitating the respective protein complexes from particulate and soluble cell fractions. Although all the phosphorylated polypeptides were present in both fractions, the extent of labeling was protein and fraction specific: the apparent specific activities of the assembly protein 50-kDa polypeptide and clathrin light chain were higher in the unassembled pool, whereas those of the 100-110-kDa polypeptides were higher in the assembled pool. The amino acids and polypeptide fragments labeled in vivo appeared similar to those labeled in vitro.     

A role for BARS at the fission step of COPI vesicle formation from Golgi membrane

The core complex of Coat Protein I (COPI), known as coatomer, is sufficient to induce coated vesicular-like structures from liposomal membrane. In the context of biological Golgi membrane, both palmitoyl-coenzyme A (p-coA) and ARFGAP1, a GTPase-activating protein (GAP) for ADP-Ribosylation Factor 1, also participate in vesicle formation, but how their roles may be linked remains unknown. Moreover, whether COPI vesicle formation from Golgi membrane requires additional factors also remains unclear. We now show that Brefeldin-A ADP-Ribosylated Substrate (BARS) plays a critical role in the fission step of COPI vesicle formation from Golgi membrane. This role of BARS requires its interaction with ARFGAP1, which is in turn regulated oppositely by p-coA and nicotinamide adenine dinucleotide, which act as cofactors of BARS. Our findings not only identify a new factor needed for COPI vesicle formation from Golgi membrane but also reveal a surprising mechanism by which the roles of p-coA and GAP are linked in this process.     

The rate of bulk flow from the Golgi to the plasma membrane

A truncated analog of the backbone of sphingomyelin and glycolipids was synthesized. This truncated C8C8 ceramide was soluble in water (but was still able to cross cell membranes) and was utilized by the Golgi apparatus of living cells to produce water-soluble truncated phospholipids and glycolipids that were then secreted into the medium. Sphingomyelin is synthesized in a proximal (likely the cis) Golgi compartment. At 37 degrees C in CHO cells, the sphingomyelin analog is secreted with a half time of about 10 min. With this rate of bulk flow, no special signal is needed to pass through the Golgi to the plasma membrane. At 30 degrees C the half time of secretion of a lumenal ER marker is about 18 min, and that of the truncated sphingomyelin is about 14 min. Comparison of these rates sets an upper limit of about 4 min for half of the ER to be drained into the proximal Golgi at 30 degrees C.     

SH3-domain-containing proteins function at distinct steps in clathrin-coated vesicle formation

Several SH3-domain-containing proteins have been implicated in endocytosis by virtue of their interactions with dynamin; however, their functions remain undefined. Here we report the efficient reconstitution of ATP-, GTP-, cytosol- and dynamin-dependent formation of clathrin-coated vesicles in permeabilized 3T3-L1 cells. The SH3 domains of intersectin, endophilin I, syndapin I and amphiphysin II inhibit coated-vesicle formation in vitro through interactions with membrane-associated proteins. Most of the SH3 domains tested selectively inhibit late events involving membrane fission, but the SH3A domain of intersectin uniquely inhibits intermediate events leading to the formation of constricted coated pits. These results suggest that interactions between SH3 domains and their partners function sequentially in endocytic coated-vesicle formation.     

Inhibition of clathrin-coated vesicle acidification by duramycin

Clathrin-coated vesicles contain a proton translocating ATPase which operates in parallel with a chloride transporter (Xie, X.-S., Stone, D.K., and Racker, E. (1983) J. Biol. Chem. 258, 14834-14838). The polypeptide antibiotic, duramycin, has a dual inhibitory effect on clathrin-coated vesicle acidification. Low amounts of duramycin (5 micrograms/100 micrograms of protein) inhibit by 50% the proton translocation facilitated by chloride translocation. Under these conditions duramycin inhibits also 36Cl uptake when driven by either the electrogenic proton pump or by inward directed K+ movement in the presence of valinomycin. Higher amounts of duramycin (20 micrograms/100 micrograms of protein) are needed to inhibit by 50% the proton pump itself, as evidenced by reduced proton translocation facilitated by an outward potassium movement in the presence of valinomycin. In addition, the amount of duramycin needed to inhibit the proton pump corresponded well with the amount needed to inhibit the ouabain-insensitive, N-ethylmaleimide-sensitive ATPase activity of clathrin-coated vesicles.     

Regulation of SHIP2 function through plasma membrane interaction

A fundamental aspect of signalling concerns the precise cellular localization of the enzymes acting on phosphoinositides, particularly PtdIns(3,4,5)P₃. SHIP1/2 phosphatases, that dephosphorylate PtdIns(3,4,5)P₃ to PtdIns(3,4)P₂, have a series of interacting motives that favour protein:protein interactions. A large number of proteins, receptors, protein kinases, cytoskeletal and adaptor proteins have been shown to bind to SHIP1/2 thereby modulating their own function and localization. SHIP2 localization has been studied at endogenous level in a series of cell models (MEFs, COS-7 and HeLa cells). In cells maintained in serum, SHIP2 localization was shown to be perinuclear with some staining at the nuclear level as well. In response to EGF, SHIP2 has been shown to translocate to the periphery of the cells (i.e. plasma membranes). This effect was transient with a maximum at 15 min stimulation by EGF.     

Structural relationships between clathrin assembly proteins from the Golgi and the plasma membrane

We have established by peptide mapping and immunochemical analysis of purified clathrin assembly protein preparations from bovine brain, that the cluster of components of mol. wt 100-120 kd fall into four classes, which we term alpha, beta, beta' and gamma. The beta and beta' proteins are immunologically related and generate a series of common tryptic peptides. The same criteria reveal no such homologies between the alpha, beta(beta') and gamma polypeptides. The so-called HA-II assembly protein group contains equimolar amounts of alpha and beta class polypeptides, which are shown to interact with each other. In the HA-I group assembly protein complex gamma and beta' class polypeptides form a stoichiometric complex. Immunofluorescence microscopy reveals that the HA-I complex is specifically associated with clathrin-coated membranes in the Golgi region of cultured cells, whereas the HA-II complex appears to be restricted to coated pits on the plasma membrane. The data lead to the tentative conclusion that the clathrin assembly proteins are involved in the recognition of the intracellular targets by uncoated vesicles.     

Isolation and reconstitution of the clathrin-coated vesicle proton translocating complex

Clathrin-coated vesicles contain a proton translocating ATPase which is insensitive to azide but inhibited by N-ethylmaleimide. The ATP hydrolytic subunit of this proton pump has been solubilized, partially purified, and reconstituted into H+-ATPase-depleted coated vesicle membranes (Xie, X.-S., Stone, D.K., and Racker, E. (1984) J. Biol. Chem. 259, 11676-11678). In this communication we report that the entire proton transporting complex has been solubilized and purified 200-fold. The complex, when reconstituted into brain lipid liposomes, catalyzes azide-resistant, N-ethylmaleimide-sensitive H+ transport manifested as both generation of a pH gradient and an electrical gradient. The complex has an apparent molecular mass of 530 kDa.     

Regulation of the clathrin-coated vesicle cycle by reversible phosphorylation

Reversible phosphorylation has long been an attractive mechanism to control cycles of coat assembly and disassembly during clathrin-mediated endocytosis. Many of the coat proteins are phosphorylated in vivo and in vitro. Our work has focused on the role of phosphorylation of the mu2 subunit of AP-2 (adaptor protein 2), which appears to be necessary for efficient cargo recruitment. Studies to probe the regulation of mu2 phosphorylation demonstrated that clathrin is a specific activator of the mu2 kinase, and, in permeabilized cells, cargo sequestration, driven by exogenously added clathrin, results in elevated levels of m2 phosphorylation. Furthermore, phosphorylated mu2 is mainly associated with assembled clathrin in vivo and its steady-state level is strongly reduced in cells depleted of clathrin heavy chain. Our results imply a central role for clathrin in the regulation of cargo selection via modulation of phospho-mu2 levels. This is therefore a novel regulatory role for clathrin that is independent of its structural role and that provides elegant spatial control of AP-2 and cargo interactions, ensuring that AP-2 is only activated at the correct cellular location and in the correct functional context. Ongoing studies are exploring further the roles of reversible phosphorylation in the coated vesicle cycle.     

G protein betagamma complex translocation from plasma membrane to Golgi complex is influenced by receptor gamma subunit interaction

On activation of a receptor the G protein betagamma complex translocates away from the receptor on the plasma membrane to the Golgi complex. The rate of translocation is influenced by the type of gamma subunit associated with the G protein. Complementary approaches--imaging living cells expressing fluorescent protein tagged G proteins and assaying reconstituted receptors and G proteins in vitro--were used to identify mechanisms at the basis of the translocation process. Translocation of Gbetagamma containing mutant gamma subunits with altered prenyl moieties showed that the differences in the prenyl moieties were not sufficient to explain the differential effects of geranylgeranylated gamma5 and farnesylated gamma11 on the translocation process. The translocation properties of Gbetagamma were altered dramatically by mutating the C terminal tail region of the gamma subunit. The translocation characteristics of these mutants suggest that after receptor activation, Gbetagamma retains contact with a receptor through the gamma subunit C terminal domain and that differential interaction of the activated receptor with this domain controls Gbetagamma translocation from the plasma membrane.     

Receptors compete for adaptors found in plasma membrane coated pits.

An affinity matrix of LDL receptor cytoplasmic tails binds the HA-II 100/50/16 kd complexes found in plasma membrane coated pits. Other receptors (or their cytoplasmic domains), which are localized in coated pits during endocytosis, inhibit this binding. This includes an 8 residue peptide containing tyrosine, corresponding to the cytoplasmic portion of a mutant influenza haemagglutinin. In contrast, the equivalent peptide lacking tyrosine (like the tail of the native haemagglutinin, a protein excluded from coated pits) does not compete. These results imply that the HA-II complex has a recognition site for a common signal, probably involving a tyrosine residue, carried by the LDL receptor and competing receptors also found in plasma membrane coated pits. The HA-II complex therefore fulfils the role of an 'adaptor', the name proposed for the structural units which mediate the binding of clathrin to receptors in coated vesicles. Another related complex, the HA-I adaptor, which is restricted to Golgi coated pits, probably does not recognize the 'tyrosine signal' on the LDL receptor tail. The HA-I adaptor is likely to contain a recognition site for a different signal carried by receptors, e.g. the mannose-6-phosphate receptor, which are found in Golgi coated pits.     

Transport of a fluorescent phosphatidylcholine analog from the plasma membrane to the Golgi apparatus

We have examined the internalization and degradation of a fluorescent analog of phosphatidylcholine after its insertion into the plasma membrane of cultured Chinese hamster fibroblasts. 1-acyl-2-(N-4- nitrobenzo-2-oxa-1,3-diazole)-aminocaproyl phosphatidylcholine (C6-NBD- PC) was incorporated into the cell surface by liposome-cell lipid transfer at 2 degrees C. The fluorescent lipid remained localized at the plasma membrane as long as the cells were kept at 2 degrees C; however, when the cells were warmed to 37 degrees C, internalization of some of the fluorescent lipid occurred. Most of the internalized C6-NBD- PC accumulated in the Golgi apparatus although a small amount was found randomly distributed throughout the cytoplasm in punctate fluorescent structures. Internalization of the fluorescent lipid at 37 degrees C was blocked by the presence of inhibitors of endocytosis. Incubation of cells containing C6-NBD-PC at 37 degrees C resulted in a rapid degradation of the fluorescent lipid. This degradation occurred predominantly at the plasma membrane. The degradation of C6-NBD-PC resulted in the release of NBD-fatty acid into the medium. We have compared the internalization of the fluorescent lipid with that of a fluorescent protein bound to the cell surface. Both fluorescent lipid and protein remained at the plasma membrane at 2 degrees C and neither were internalized at 37 degrees C in the presence of inhibitors of endocytosis. However, when incubated at 37 degrees C under conditions that permit endocytosis, the two fluorescent species appeared at different intracellular sites. Our data suggest that there is no transmembrane movement of C6-NBD-PC and that the fluorescent probe reflects the internalization of the outer leaflet of the plasma membrane lipid bilayer. The results are consistent with the Golgi apparatus as being the primary delivery site of phospholipid by bulk membrane movement from the plasma membrane.     

Coupling between vesicle shape and the non-homogeneous lateral distribution of membrane constituents in Golgi bodies

In this work, a hypothesis is presented that could explain the non-homogeneous lateral distribution of membrane components in Golgi vesicles. It is shown that the non-homogeneous lateral distribution of membrane components and the specific flattened shape of Golgi vesicles are strongly coupled. In agreement with experimental evidence, it is indicated that some of the membrane components may be concentrated mainly on the curved bulbous rims of the Golgi vesicles, while the other components are distributed predominantly in their flat central part.     

Reconstitution of clathrin-coated pit budding from plasma membranes

Receptor-mediated endocytosis begins with the binding of ligand to receptors in clathrin-coated pits followed by the budding of the pits away from the membrane. We have successfully reconstituted this sequence in vitro. Highly purified plasma membranes labeled with gold were obtained by incubating cells in the presence of anti-LDL receptor IgG-gold at 4 degrees C, attaching the labeled cells to a poly-L-lysine-coated substratum at 4 degrees C and then gently sonicating them to remove everything except the adherent membrane. Initially the gold label was clustered over flat, clathrin-coated pits. After these membranes were warmed to 37 degrees C for 5-10 min in the presence of buffer that contained cytosol extract, Ca2+, and ATP, the coated pits rounded up and budded from the membrane, leaving behind a membrane that was devoid of LDL gold. Simultaneous with the loss of the ligand, the clathrin triskelion and the AP-2 subunits of the coated pit were also lost. These results suggest that the budding of a coated pit to form a coated vesicle occurs in two steps: (a) the spontaneous rounding of the flat lattice into a highly invaginated coated pit at 37 degrees C; (b) the ATP, 150 microM Ca2+, and cytosolic factors(s) dependent fusion of the adjoining membrane segments at the neck of the invaginated pit.     

Exit of newly synthesized membrane proteins from the trans cisterna of the Golgi complex to the plasma membrane

The intracellular location at which the G protein of vesicular stomatitis virus accumulated when transport was blocked at 20 degrees C has been studied by biochemical, cytochemical, and immunocytochemical methods. Our results indicated that the viral G protein was blocked in that cisterna of the Golgi stack which stained for acid phosphatase. At 20 degrees C this trans cisterna became structurally altered by the accumulation of G protein. This alteration was characterized by extensive areas of membrane buds which were covered by a cytoplasmic coat. These coated structures were of two kinds--those that labeled with anti-clathrin antibodies and those that did not. The clathrin-coated pits consistently did not label with anti-G antibodies. Upon warming infected cells to 32 degrees C, G protein appeared on the surface within minutes. Concomitantly, the trans cisterna lost its characteristic structural organization. Double-labeling experiments were performed in which G protein localization was combined with staining for horseradish peroxidase, which had been taken up from the extracellular medium by endocytosis. The results suggest that the trans cisterna was distinct from the endosome compartment and that the latter was not an obligatory station in the route taken by G protein to the cell surface.