Golgi vesiculation induced by cholesterol occurs by a dynamin- and cPLA2-dependent mechanism

It was recently demonstrated that an increase in the cellular cholesterol level leads to vesiculation of the Golgi apparatus. This vesiculation affects the entire Golgi apparatus and is a reversible process. We have now started to elucidate the mechanism behind this cholesterol-induced vesiculation of the Golgi apparatus. Transient transfection of cells with dominant negative mutant constructs of dynamin 1 and 2 inhibited the vesiculation; expression of dynK44A in HeLa cells stably transfected with this construct had the same effect. However, the vesiculation seems to be independent of clathrin, as cholesterol-induced vesiculation still occurred following knock down of clathrin heavy chain in HeLa cells using RNA interference as well as in BHK cells where expression of antisense to clathrin heavy chain had been induced. Importantly, the cPLA2 inhibitor MAFP and the chelator BAPTA-AM that binds cytosolic Ca2+ inhibited the cholesterol-induced vesiculation, suggesting involvement of a cPLA2 that requires cytosolic Ca2+ for translocation to membranes. Furthermore, in response to an increased cellular cholesterol level, an EGFP-cPLA2 fusion protein translocated to the Golgi apparatus. Thus, our results demonstrate that the cholesterol-induced vesiculation of the Golgi apparatus is mediated by a cPLA2- and dynamin-dependent mechanism.     

Reconstitution of the Golgi reassembly process in semi-intact MDCK cells

The Golgi apparatus, which consists of stacks of cisternae during interphase, is fragmented or dispersed throughout the cytoplasm at the onset of mitosis. A sea sponge metabolite, ilimaquinone (IQ), causes Golgi membranes to vesiculate. And after its removal, the vesiculated membranes reassemble into stacks of cisternae in the perinuclear region. To study the mechanism of Golgi membrane dynamics during mitosis, we have reconstituted the reassembly process of IQ-induced vesiculated Golgi membranes in streptolysin O-permeabilized Mardin-Darby canine kidney (MDCK) cells. Monitoring the dynamics of Golgi membranes labeled with a green fluorescence protein (GFP)-tagged protein, we dissected the process into two elementary components: the reassembly of vesiculated Golgi membranes into punctate structures; and the subsequent reformation of these structures into stacks of cisternae near the nucleus. Using morphometric analysis, we studied the kinetics and biochemical requirements for the process, and revealed that an NEM-sensitive factor, cytoplasmic dynein, and GTP binding protein were involved in the Golgi reassembly.     

Cholesterol loading induces a block in the exit of VSVG from the TGN

Recent work from our laboratory demonstrated that increased cellular cholesterol content affects the structure of the Golgi apparatus. We have now investigated the functional consequences of the cholesterol-induced vesiculation of the Golgi apparatus and the role of actin for these changes. The results showed that cholesterol-induced vesiculation and dispersion of the Golgi apparatus is a reversible process and that reversal can be inhibited by cytochalasin D, an actin-disrupting reagent. Furthermore, electron microscopy revealed that jasplakinolide, which stabilizes actin filaments, prevented the dispersion, but not the vesiculation of the Golgi cisternae. Importantly, the different Golgi markers seemed to be separated even after vesiculation. To investigate whether transport through the different steps of the exocytic pathway was affected in cholesterol-treated cells, we visualized ER to plasma membrane transport by using ts045-VSVG-GFP. In COS-1 cells expressing ts045-VSVG-GFP increased cholesterol levels did not affect transport of VSVG into the vesiculated Golgi apparatus. However, increased levels of cholesterol resulted in retention of the nascent G protein in vesicles with the TGN-marker TGN46. Biotinylation of cell surface molecules to quantify arrival of VSVG at the plasma membrane confirmed that cholesterol treatment inhibited export of the VSVG protein. In conclusion, the data show that transport of VSVG into/through a vesiculated Golgi is feasible, but that cholesterol loading inhibits exit of VSVG from the vesicles containing TGN markers. Furthermore, the data illustrate the importance of actin filaments for Golgi structure.     

Loss of Gap Junction Plaques and Inhibition of Intercellular Communication in Ilimaquinone-treated BICR-M1Rk and NRK Cells

To examine the mechanism(s) and pathways of gap junction formation and removal a novel and reversible inhibitor of protein secretion, ilimaquinone (IQ), was employed. IQ has been reported to cause the vesiculation of Golgi membranes, block protein transport at the cis-Golgi and depolymerize cytoplasmic microtubules. Connexin43 (Cx43) immunolabeling and dye microinjection experiments revealed that gap junction plaques were lost and intercellular communication was inhibited following IQ treatment for 1 hr in BICR-M1R_k rat mammary tumor cells and for 2 hr in normal rat kidney (NRK) cells. Gap junction plaques and intercellular communication recovered within 2 hr when IQ was removed. IQ, however, did not affect the distribution of zonula occludens-1, a protein associated with tight junctions. Western blot analysis revealed that the IQ-induced loss of gap junction plaques was accompanied by a limited reduction in the highly phosphorylated form of Cx43, previously shown to be correlated with gap junction plaques. The presence of IQ inhibited the formation of new gap junction plaques in BICR-M1R_k cells under conditions where preexisting gap junctions were downregulated by brefeldin A treatment. Treatment of BICR-M1R_k and NRK cells with other microtubule depolymerization agents did not inhibit plaque formation or promote rapid gap junction removal. These findings suggest that IQ disrupts intercellular communication by inhibiting the events that are involved in plaque formation and/or retention at the cell surface independent of its effects on microtubules. Our results also suggest that additional factors other than phosphorylation are necessary for Cx43 assembly into gap junction plaques. Received: 16 January 1996/Revised: 20 September 1996     

Microtubule independent vesiculation of Golgi membranes and the reassembly of vesicles into Golgi stacks

We have recently shown that ilimaquinone (IQ) causes the breakdown of Golgi membranes into small vesicles (VGMs for vesiculated Golgi membranes) and inhibits vesicular protein transport between successive Golgi cisternae (Takizawa et al., 1993). While other intracellular organelles, intermediate filaments, and actin filaments are not affected, we have found that cytoplasmic microtubules are depolymerized by IQ treatment of NRK cells. We provide evidence that IQ breaks down Golgi membranes regardless of the state of cytoplasmic microtubules. This is evident from our findings that Golgi membranes break down with IQ treatment in the presence of taxol stabilized microtubules. Moreover, in cells where the microtubules are first depolymerized by microtubule disrupting agents which cause the Golgi stacks to separate from one another and scatter throughout the cytoplasm, treatment with IQ causes further breakdown of these Golgi stacks into VGMs. Thus, IQ breaks down Golgi membranes independently of its effect on cytoplasmic microtubules. Upon removal of IQ from NRK cells, both microtubules and Golgi membranes reassemble. The reassembly of Golgi membranes, however, takes place in two sequential steps: the first is a microtubule independent process in which the VGMs fuse together to form stacks of Golgi cisternae. This step is followed by a microtubule-dependent process by which the Golgi stacks are carried to their perinuclear location in the cell. In addition, we have found that IQ has no effect on the structural organization of Golgi membranes at 16 degrees C. However, VGMs generated by IQ are capable of fusing and assembling into stacks of Golgi cisternae at 16 degrees C. This is in contrast to the cells recovering from BFA treatment where, after removal of BFA at 16 degrees C, resident Golgi enzymes fail to exit the ER, a process presumed to require the formation of vesicles. We propose that at 16 degrees C there may be general inhibition in the process of vesicle formation, whereas the process of vesicle fusion is not affected.     

Lectin-gold cytochemistry of the Golgi apparatus in rabbit luteal cells, with special emphasis on the formation of a lysosomal-type membrane

In rabbit luteal cells embedded in glycolmethacrylate and stained with PTA at low pH highly glycosylated membrane patches can be observed after vesiculation of the trans-Golgi network. As these membranes could be prelysosomal, their sialic acid content was investigated by post-embedding labeling with Limax flavus agglutinin (LFA)/fetuin-Au. Additional labeling of the Golgi apparatus was performed with Wheat germ agglutinin (WGA)/ovomucoid Au, Ricinus communis agglutininI (RCAI)/Au and Helix pomatia agglutinin (HPA)/Au. The sections were then counterstained with PTA at low pH, which allows a clear distinction between the elements of the trans-Golgi network (G2-G1) and the saccules of the stack (g). With WGA, LFA and RCAI the trans-Golgi network was observed to be clearly more reactive than the stack. After vesiculation most intense labeling was found over the highly glycosylated vacuolar membranes derived from the G2-element. The limiting membrane of lysosomes, the MvB's and the plasma membrane also reacted strongly. Colloidal gold particles were also found over the membranes of the vacuoles derived from G1. The Golgi stack showed a lower reactivity and label for all three lectins could be found over three to four saccules of the stack (g3-g4). The matrix of the lysosomes was slightly labeled. Labeling with HPA was absent from the trans saccules and was consistently found in the cis and cis-most (g4-g5) saccules of the stack. Some cytoplasmic vesicles near the cell border were also labeled. With our procedure the Golgi apparatus can easily be detected and it is apparent that in rabbit luteal cells the highest lectin reactivity is found in the trans-Golgi network.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reconstitution of vesiculated Golgi membranes into stacks of cisternae: requirement of NSF in stack formation

We have developed an in vitro system to study the biochemical events in the fusion of ilimaquinone (IQ) induced vesiculated Golgi membranes (VGMs) into stacks of cisternae. The Golgi complex in intact normal rat kidney cells (NRK) is vesiculated by treatment with IQ. The cells are washed to remove the drug and then permeabilized by a rapid freeze-thaw procedure. VGMs of 60 nm average diameter assemble into stacks of Golgi cisternae by a process that is temperature dependent, requires ATP and a high speed supernatant from cell extract (cytosol), as revealed by immunofluorescence and electron microscopy. The newly assembled stacks are functionally active in vesicular protein transport and contain processing enzymes that carry out Golgi specific modifications of glycoproteins. The fusion of VGMs requires NSF, a protein known to promote fusion of transport vesicles with the target membrane in the exocytic and endocytic pathways. Immunoelectron microscopy using Golgi specific anti-mannosidase II antibody reveals that VGMs undergo sequential changes in their morphology, whereby they first fuse to form larger vesicles of 200-300-nm average diameter which subsequently extend into tubular elements and finally assemble into stacks of cisternae.     

A Golgi-related structure remains after the brefeldin A-induced formation of an ER-Golgi hybrid compartment.

Brefeldin A (BFA) has previously been shown to block protein transport from the endoplasmic reticulum (ER), to cause the redistribution of Golgi components to the ER, and to change profoundly the morphology of the Golgi apparatus. In order to quantitate the effects of this drug on the morphology of the ER and the Golgi apparatus in HeLa cells, the numerical, surface and volume densities of these organelles were determined by stereological means. We found that in cells treated with BFA (5 micrograms/ml) clusters of vesicles and tubules, often located near transitional elements of the ER, replaced the Golgi apparatus. The numerical density of these clusters in cells treated with BFA for 30 min or 4.5 h is similar to that of Golgi complexes and Golgi-related clusters in control cells. The surface density of the vesicles and tubules contained in these clusters is about 50% of that represented by Golgi elements in control cells. Concomitantly, a corresponding increase in the surface density of the ER-Golgi hybrid compartment was observed. This hybrid compartment contained Golgi-specific enzymes effecting modifications of N-linked oligosaccharides and the transfer of O-linked sugars. Antibodies recognizing different subcompartments of the Golgi apparatus or the intermediate compartment, labeled vesicles and tubules of the Golgi-related clusters. Applying low doses of BFA allowed for the dissection of the disassembly of the Golgi apparatus into at least two phases. At very low doses (10-20 ng/ml) the numerical density of vesicles in the clusters increased up to 4-fold above control, while the surface density did not markedly change, suggesting that vesiculation of the Golgi cisternae had occurred. Fusion of Golgi elements with the ER seemed to occur only at doses of BFA higher than 20 ng/ml. Contrary to observations on other cell types, removal of BFA from HeLa cell cultures resulted in a rather slow reformation (1-2 h) of the Golgi complex, which allowed us to observe several intermediate stages in this process. During this time period an ER was restored which no longer contained Golgi-specific O-glycosylation functions. Our results demonstrate that BFA does not simply cause the disappearance of the Golgi apparatus by fusion with the ER, but instead clusters of vesicles and tubules remain that contain Golgi-specific markers.     

Ilimaquinone inhibits gap-junctional communication prior to Golgi fragmentation and block in protein transport

Brefeldin A and ilimaquinone are compounds known to affect Golgi structure and function. In particular, the transport of proteins is blocked either at the level of exit from endoplasmic reticulum (brefeldin) or at cis-Golgi (ilimaquinone). Brefeldin caused a slow decrease in gap-junctional communication and a slow loss of all phosphorylated forms of connexin43 in hamster and rat fibroblasts, while ilimaquinone caused an abrupt decrease in gap-junctional communication and rapid loss of only the slowest migrating phosphorylated connexin43 band (P2). Ilimaquinone caused these effects prior to any significant Golgi fragmentation, especially in hamster fibroblasts. Concurrently, ilimaquinone minimally affected protein secretion, while brefeldin caused an instantaneous decrease. These results show that ilimaquinone inhibits gap-junctional communication in connexin43-expressing cells by a mechanism not dependent on Golgi fragmentation or block in protein transport.     

Antibodies to the Golgi complex and the rough endoplasmic reticulum

Rabbits were immunized with membrane fractions from either the Golgi complex or the rough endoplasmic reticulum (RER) by injection into the popliteal lymph nodes. The antisera were then tested by indirect immunofluorescence on tissue culture cells or frozen, thin sections of tissue. There were may unwanted antibodies to cell components other than the RER or the Golgi complex, and these were removed by suitable absorption steps. These steps were carried out until the pattern of fluorescent labeling was that expected for the Golgi complex or RER. Electron microscopic studies, using immunoperoxidase labeling of normal rat kidney (NRK) cells, showed that the anti-Golgi antibodies labeled the stacks of flattened cisternae that comprise the central feature of the Golgi complex, many of the smooth vesicles around the stacks, and a few coated vesicles. These antibodies were directed, almost entirely, against a single polypeptide with an apparent molecular weight of 135,000. The endoplasmic reticulum (ER) in NRK cells is an extensive, reticular network that pervades the entire cell cytoplasm and includes the nuclear membrane. The anit-RER antibodies labeled this structure alone at the light and electron microscopic levels. They were largely directed against four polypeptides with apparent molecular weights of 29,000, 58,000, 66,000, and 91,000. Some examples are presented, using immunofluorescence microscopy, where these antibodies have been used to study the Golgi complex and RER under a variety of physiological and experimental condition . For biochemical studies, these antibodies should prove useful in identifying the origin of isolated membranes, particularly those from organelles such as the Golgi complex, which tend to lose their characteristic morphology during isolation.     

A role for clathrin in reassembly of the Golgi apparatus

The Golgi apparatus is a highly dynamic organelle whose organization is maintained by a proteinaceous matrix, cytoskeletal components, and inositol phospholipids. In mammalian cells, disassembly of the organelle occurs reversibly at the onset of mitosis and irreversibly during apoptosis. Several pharmacological agents including nocodazole, brefeldin A (BFA), and primary alcohols (1-butanol) induce reversible fragmentation of the Golgi apparatus. To dissect the mechanism of Golgi reassembly, rat NRK and GH3 cells were treated with 1-butanol, BFA, or nocodazole. During washout of 1-butanol, clathrin, a ubiquitous coat protein implicated in vesicle traffic at the trans-Golgi network and plasma membrane, and abundant clathrin coated vesicles were recruited to the region of nascent Golgi cisternae. Knockdown of endogenous clathrin heavy chain showed that the Golgi apparatus failed to reform efficiently after BFA or 1-butanol removal. Instead, upon 1-butanol washout, it maintained a compact, tight morphology. Our results suggest that clathrin is required to reassemble fragmented Golgi elements. In addition, we show that after butanol treatment the Golgi apparatus reforms via an initial compact intermediate structure that is subsequently remodeled into the characteristic interphase lace-like morphology and that reassembly requires clathrin.     

Golgi-membrane dynamics are cytoskeleton dependent: A study on Golgi stack movement induced by brefeldin A

Summary Brefeldin A (BFA) induces a major aggregation of the Golgi apparatus (GA) in root cells followed by a complete, but reversible, vesiculation of the Golgi stacks which form two or more BFA compartments in the cytosol. This effect is monitored by the immunofluorescence of a Golgi antigen stained with a monoclonal antibody JIM 84, and by transmission electron microscopy. Depolymerisation of the microtubule cytoskeleton after oryzalin or colchicine treatment does not disturb the three dimensional organisation of the GA in control cells and does not affect any BFA induced Golgi stack movements. After disruption of the actin cytoskeleton with cytochalasin D many aggregates of Golgi stacks can be observed in root cells and these are sensitive to BFA treatment, forming multiple BFA compartments. N-ethyl-maleimide has no effect on the organisation of the GA in control roots but totally inhibits the action of BFA. Thus, it appears that spatial organisation of the GA and the BFA induced Golgi stack movements are actin dependent whilst BFA induced vesiculation of the GA is a structurally separate event.     

Effects of activated ADP-ribosylation factors on Golgi morphology require neither activation of phospholipase D1 nor recruitment of coatomer

Nine mutations in the switch I and switch II regions of human ADP-ribosylation factor 3 (ARF3) were isolated from loss-of-interaction screens, using two-hybrid assays with three different effectors. We then analyzed the ability of the recombinant proteins to (i) bind guanine nucleotides, (ii) activate phospholipase D1 (PLD1), (iii) recruit coatomer (COP-I) to Golgi-enriched membranes, and (iv) expand and vesiculate Golgi in intact cells. Correlations of activities in these assays were used as a means of testing specific hypotheses of ARF action, including the role of PLD1 activation in COP-I recruitment, the role of COP-I in Golgi vesiculation caused by expression of the dominant activating mutant [Q71L]ARF3, and the need for PLD1 activation in Golgi vesiculation. Because we were able to find at least one example of a protein that has lost each of these activities with retention of the others, we conclude that activation of PLD1, recruitment of COP-I to Golgi, and vesiculation of Golgi in cells are functionally separable processes. The ability of certain mutants of ARF3 to alter Golgi morphology without changes in PLD1 activity or COP-I binding is interpreted as evidence for at least one additional, currently unidentified, effector for ARF action at the Golgi.     

Golgi-disturbing agents

 Pharmacological agents have proven useful for gaining fundamental insights into the biology of the Golgi apparatus. This review summarizes pertinent and recent work on the effects on this organelle of monensin, brefeldin A, bafilomycin, ilimaquinone, okadaic acid, retinoic acid, and nocodazole. The molecular targets of monensin, brefeldin A, ilimaquinone, and retinoic acid remain to be elucidated whereas those for bafilomycin (vacuolar H⁺-ATPase), okadaic acid (serine/threonine phosphatases types 1, 2a, and 2b), and nocodazole (microtubules) are reasonably well understood. The molecular target of brefeldin has not been defined, but has been suggested to involve guanine nucleotide exchange proteins acting on ADP-ribosylation factor 1. Whether a defined molecular target can be found for monensin must be questioned since its main action consists in exchanging protons for Na⁺ which leads to osmotic swelling of post-Golgi endosomal structures and Golgi subcompartments by virtue of its membrane-associated effect as a cationophore. Brefeldin A was one of the most thoroughly investigated Golgi-disturbing agents and proved instrumental in unraveling retrograde flow mechanisms in the secretory pathways. Okadaic acid attracted interest for its properties mimicking mitotic fragmentation of the Golgi apparatus. Nocodazole was instrumental in establishing the cytoskeletal anchoring of the Golgi apparatus close to the microtubular organizing center. Accepted: 29 September 1997     

Possible implication of Golgi-nucleating function for the centrosome

The Golgi apparatus breaks down at mitosis, resulting in the dispersal of Golgi-resident proteins. In NRK cells, however, subsets of both TGN38 and golgin-97, but not ManII and GM130, remained associated with the centrosome throughout the cell cycle. This centrosome association of TGN38 and golgin-97 was not disrupted by treatment with brefeldin A, additional inducers of retrograde trafficking and inhibitors of either kinases or protein phosphatases. Anchoring of the Golgi apparatus within the juxtanuclear region depends on microtubules; the association of TGN38 and golgin-97 subsets with the centrosome, however, was insensitive to nocodazole treatment. Drugs such as PDMP, which block Golgi dispersal both by nocodazole, despite microtubule depolymerization, and by inducers of retrograde trafficking, strengthened the microtubule-nucleating activity of the centrosome. These observations cumulatively suggest the centrosome is implicated in nucleation of the Golgi apparatus through interactions with Golgi-resident proteins, such as TGN38 and golgin-97.     

Presence of an immunologically-defined class of peri-Golgi vesicles in cultured mammalian cells

Immunsera of mice injected with clathrin-depleted coated vesicle membranes, purified from rat liver, revealed a preferential labeling of some perinuclear structures by immunofluorescence microscopy on NRK cells. Subsequent production of 4 monoclonal antibodies was achieved. The antigen was strictly located in the Golgi area of the cell but was not an intrinsic element of the Golgi complex. The restricted location of the structures excluded these were lysosomes which appeared more dispersed in these cells. After nocodazole treatment the material was found dispersed in the cytoplasm. This provided a means of distinguishing the antigen from clathrin-coated structures and Golgi intrinsic elements. Immunolocalization at the electron microscope level confirmed the data obtained at the light level. Some peroxidase reaction product was rarely associated with Golgi elements, but predominantly stained small neighboring Golgi vesicles (50 nm diameter), as well as tubulo-elongated structures and some large (500 nm) irregular-shaped vesicles. A 32 kDa molecular weight antigen was characterized by immunopurification from NRK cells metabolically labeled with 35S-Met. This 32 kDa antigen appeared as part of a higher multimolecular membrane component of 300 kDa. A 170 kDa and a 70 kDa components were immunodetected in a semi-purified membrane fraction from rat liver, demonstrating that the antigen was a minor but very antigenic contaminant of the coated vesicle preparation used as immunogen. In conclusion, the labeled peri-Golgi structures may be part of the newly characterized trans-Golgi network and/or of the reticular/vesicular endosomal, prelysosomal structure recently described.     

Localization of Mannose, TV-Acetylglucosamine and Galactose in the Golgi Apparatus, Plasma Membranes and Cell Walls of Scenedesmus acuminatus

The localization of lectin binding sites in the Golgi apparatus,plasma membranes and cell walls of Scenedesmus acuminatus wasinvestigated by cytochemical electron microscopy. The lectinsused were concanavalin A (Con A), peanut agglutinin (PNA) andwheat germ agglutinin (WGA), all labeled with gold. Con A-goldparticles were deposited not on the Golgi apparatus, but onthe outer cell-wall layer. PNA-gold and WGA-gold particles weredeposited on distal Golgi cisternae and vesicles derived fromthe Golgi apparatus. Entire cell-wall layers were evenly labeledby PNA-gold. The plasma membrane and cytoplasmic regions closeto the plasma membrane were labeled with WGA-gold. The processingof oligosaccharide in the Golgi apparatus, plasma membranesand cell walls of Scenedesmus acuminatus is discussed in referenceto that reported for animal cells. (Received March 5, 1987; Accepted July 18, 1987)     

Endosome to Golgi transport of ricin is regulated by cholesterol

We have here studied the role of cholesterol in transport of ricin from endosomes to the Golgi apparatus. Ricin is endocytosed even when cells are depleted for cholesterol by using methyl-beta-cyclodextrin (m beta CD). However, as here shown, the intracellular transport of ricin from endosomes to the Golgi apparatus, measured by quantifying sulfation of a modified ricin molecule, is strongly inhibited when the cholesterol content of the cell is reduced. On the other hand, increasing the level of cholesterol by treating cells with mbetaCD saturated with cholesterol (m beta CD/chol) reduced the intracellular transport of ricin to the Golgi apparatus even more strongly. The intracellular transport routes affected include both Rab9-independent and Rab9-dependent pathways to the Golgi apparatus, since both sulfation of ricin after induced expression of mutant Rab9 (mRab9) to inhibit late endosome to Golgi transport and sulfation of a modified mannose 6-phosphate receptor (M6PR) were inhibited after removal or addition of cholesterol. Furthermore, the structure of the Golgi apparatus was affected by increased levels of cholesterol, as visualized by pronounced vesiculation and formation of smaller stacks. Thus, our results indicate that transport of ricin from endosomes to the Golgi apparatus is influenced by the cholesterol content of the cell.     

A heterotrimeric G protein, G alpha i-3, on Golgi membranes regulates the secretion of a heparan sulfate proteoglycan in LLC-PK1 epithelial cells

A heterotrimeric G alpha i subunit, alpha i-3, is localized on Golgi membranes in LLC-PK1 and NRK epithelial cells where it colocalizes with mannosidase II by immunofluorescence. The alpha i-3 was found to be localized on the cytoplasmic face of Golgi cisternae and it was distributed across the whole Golgi stack. The alpha i-3 subunit is found on isolated rat liver Golgi membranes by Western blotting and G alpha i-3 on the Golgi apparatus is ADP ribosylated by pertussis toxin. LLC-PK1 cells were stably transfected with G alpha i-3 on an MT-1, inducible promoter in order to overexpress alpha i-3 on Golgi membranes. The intracellular processing and constitutive secretion of the basement membrane heparan sulfate proteoglycan (HSPG) was measured in LLC-PK1 cells. Overexpression of alpha i-3 on Golgi membranes in transfected cells retarded the secretion of HSPG and accumulated precursors in the medial-trans-Golgi. This effect was reversed by treatment of cells with pertussis toxin which results in ADP-ribosylation and functional uncoupling of G alpha i-3 on Golgi membranes. These results provide evidence for a novel role for the pertussis toxin sensitive G alpha i-3 protein in Golgi trafficking of a constitutively secreted protein in epithelial cells.     

Acute perturbations in Golgi organization impact de novo sphingomyelin synthesis

The mammalian Golgi apparatus is composed of multiple stacks of cisternal membranes organized laterally into a ribbon-like structure, with close apposition of trans Golgi regions with specialized endoplasmic reticulum (ER) membranes. These contacts may be the site of ceramide transfer from its site of synthesis (ER) to sphingomyelin (SM) synthase through ceramide transfer protein (CERT). CERT extracts ceramide from the ER and transfers it to Golgi membranes but the role of overall Golgi structure in this process is unknown. We show here that localization of CERT in puncta around the Golgi complex requires both ER- and Golgi-binding domains of CERT. To examine how Golgi structure contributes to SM synthesis, we treated cells with Golgi-perturbing drugs and measured newly synthesized SM. Interestingly, disruption of Golgi morphology with nocodazole, but not ilimaquinone inhibited SM synthesis. Decreased localization of CERT with a Golgi marker correlated with decreased SM synthesis. We propose that some Golgi structural perturbations interfere with efficient ceramide trafficking through CERT, and thus SM synthesis. The organization of the mammalian Golgi ribbon together with CERT may promote specific ER-Golgi interactions for efficient delivery of ceramide for SM synthesis.