Caveolae, caveolin and caveolin-rich membrane domains: a signalling hypothesis

Caveolae, 50-100 nm invaginations that represent a subcompartment of the plasma membrane, have been known for many years, but their exact roles remain uncertain. The findings that the caveolae coat protein caveolin is a v-Src substrate and that G-protein-coupled receptors are present in caveolae have suggested a relationship between caveolae, caveolin and transmembrane signalling. The recent isolation of caveolin-rich membrane domains in which caveolin exists as a hetero-oligomeric complex with integral membrane proteins and known cytoplasmic signalling molecules provides support for this hypothesis. Compartmentalization of certain signalling molecules within caveolae could allow efficient and rapid coupling of activated receptors to more than one effector system.     

An intracellular motif of GLUT4 regulates fusion of GLUT4-containing vesicles

Background  

Insulin stimulates glucose uptake by adipocytes through increasing translocation of the glucose transporter GLUT4 from an intracellular compartment to the plasma membrane. Fusion of GLUT4-containing vesicles at the cell surface is thought to involve phospholipase D activity, generating the signalling lipid phosphatidic acid, although the mechanism of action is not yet clear.     

Membrane structure of caveolae and isolated caveolin-rich vesicles

 Caveolae are specialized invaginated domains of the plasma membrane. Using freeze-fracture electron microscopy, the shape of caveolae and the distribution of intramembrane particles (integral membrane proteins) were analyzed. The caveolar membrane is highly curved and forms flask-like invaginations with a diameter of 80–120 nm with an open porus of 30–50 nm in diameter. The fracture faces of caveolar membranes are nearly free of intramembrane particles. Protein particles in a circular arrangement surrounding the caveolar opening were found on plasma membrane fracture faces. For isolation of caveolin-enriched membrane vesicles, the method of Triton X-100 solubilization, as well as a detergent-free isolation method, was used. The caveolin-rich vesicles had an average size of between 100 and 200 nm. No striated coat could be detected on the surface of isolated caveolin-rich vesicles. Areas of clustered intramembrane particles were found frequently on membrane fracture faces of caveolin-rich vesicles. The shape of these membrane protein clusters is often ring-like with a diameter of 30–50 nm. Membrane openings were found to be present in the caveolin-rich membrane vesicles, mostly localized in the areas of the clustered membrane proteins. Immunogold labeling of caveolin showed that the protein is a component within the membrane protein clusters and is not randomly distributed on the membrane of caveolin-rich vesicles. Accepted: 16 September 1998     

Pantophysin is a phosphoprotein component of adipocyte transport vesicles and associates with GLUT4-containing vesicles

Pantophysin, a protein related to the neuroendocrine-specific synaptophysin, recently has been identified in non-neuronal tissues. In the present study, Northern blots showed that pantophysin mRNA was abundant in adipose tissue and increased during adipogenesis of 3T3-L1 cells. Immunoblot analysis of subcellular fractions showed pantophysin present exclusively in membrane fractions and relatively evenly distributed in the plasma membrane and internal membrane fractions. Sucrose gradient ultracentrifugation demonstrated that pantophysin and GLUT4 exhibited overlapping distribution profiles. Furthermore, immunopurified GLUT4 vesicles contained pantophysin, and both GLUT4 and pantophysin were depleted from this vesicle population following treatment with insulin. Additionally, a subpopulation of immunopurified pantophysin vesicles contained insulin-responsive GLUT4. Consistent with the interaction of synaptophysin with vesicle-associated membrane protein 2 in neuroendocrine tissues, pantophysin associated with vesicle-associated membrane protein 2 in adipocytes. Furthermore, in [(32)P]orthophosphate-labeled cells, pantophysin was phosphorylated in the basal state. This phosphorylation was unchanged in response to insulin; however, insulin stimulated the phosphorylation of a 77-kDa protein associated with alpha-pantophysin immunoprecipitates. Although the functional role of pantophysin in vesicle trafficking is unclear, its presence on GLUT4 vesicles is consistent with the emerging role of soluble N-ethylmaleimide-sensitive protein receptor (SNARE) factor complex and related proteins in regulated vesicle transport in adipocytes. In addition, pantophysin may provide a marker for the analysis of other vesicles in adipocytes.     

Expression and compartmentalization of caveolin in adipose cells: coordinate regulation with and structural segregation from GLUT4

Native rat adipocytes and the mouse adipocyte cell line, 3T3-L1, possess transport vesicles of apparently uniform composition and size which translocate the tissue-specific glucose transporter isoform, GLUT4, from an intracellular pool to the cell surface in an insulin- sensitive fashion. Caveolin, the presumed structural protein of caveolae, has also been proposed to function in vesicular transport. Thus, we studied the expression and subcellular distribution of caveolin in adipocytes. We found that rat fat cells express the highest level of caveolin protein of any tissue studied, and caveolin is also expressed at high levels in cardiac muscle, another tissue possessing insulin responsive GLUT4 translocation. Both proteins are absent from 3T3-L1 fibroblasts and undergo a dramatic coordinate increase in expression upon differentiation of these cells into adipocytes. However, unlike GLUT4 in rat adipocytes not exposed to insulin, the majority of caveolin is present in the plasma membrane. In native rat adipocytes, intracellular GLUT4 and caveolin reside in vesicles practically indistinguishable by their size and buoyant density in sucrose gradients, and both proteins show insulin-dependent translocation to the cell surface. However, by immunoadsorption of GLUT4-containing vesicles with anti-GLUT4 antibody, we show that these vesicles have no detectable caveolin, and therefore, this protein is present in a distinct vesicle population. Thus, caveolin has no direct structural relation to the organization of the intracellular glucose transporting machinery in fat cells.     

GLUT4 overexpression or deficiency in adipocytes of transgenic mice alters the composition of GLUT4 vesicles and the subcellular localization of GLUT4 and insulin-responsive aminopeptidase

The majority of GLUT4 is sequestered in unique intracellular vesicles in the absence of insulin. Upon insulin stimulation GLUT4 vesicles translocate to, and fuse with, the plasma membrane. To determine the effect of GLUT4 content on the distribution and subcellular trafficking of GLUT4 and other vesicle proteins, adipocytes of adipose-specific, GLUT4-deficient (aP2-GLUT4-/-) mice and adipose-specific, GLUT4-overexpressing (aP2-GLUT4-Tg) mice were studied. GLUT4 amount was reduced by 80-95% in aP2-GLUT4-/- adipocytes and increased approximately 10-fold in aP2-GLUT4-Tg adipocytes compared with controls. Insulin-responsive aminopeptidase (IRAP) protein amount was decreased 35% in aP2-GLUT4-/- adipocytes and increased 45% in aP2-GLUT4-Tg adipocytes. VAMP2 protein was also decreased by 60% in aP2-GLUT4-/- adipocytes and increased 2-fold in aP2-GLUT4-Tg adipocytes. IRAP and VAMP2 mRNA levels were unaffected in aP2-GLUT4-Tg, suggesting that overexpression of GLUT4 affects IRAP and VAMP2 protein stability. The amount and subcellular distribution of syntaxin4, SNAP23, Munc-18c, and GLUT1 were unchanged in either aP2-GLUT4-/- or aP2-GLUT4-Tg adipocytes, but transferrin receptor was partially redistributed to the plasma membrane in aP2-GLUT4-Tg adipocytes. Immunogold electron microscopy revealed that overexpression of GLUT4 in adipocytes increased the number of GLUT4 molecules per vesicle nearly 2-fold and the number of GLUT4 and IRAP-containing vesicles per cell 3-fold. In addition, the proportion of cellular GLUT4 and IRAP at the plasma membrane in unstimulated aP2-GLUT4-Tg adipocytes was increased 4- and 2-fold, respectively, suggesting that sequestration of GLUT4 and IRAP is saturable. Our results show that GLUT4 overexpression or deficiency affects the amount of other GLUT4-vesicle proteins including IRAP and VAMP2 and that GLUT4 sequestration is saturable.     

V-type ATPase is involved in biogenesis of GLUT4 vesicles

Proton pumps participate in several aspects of endocytic protein trafficking. However, their involvement specifically in the GLUT4 pathway has been a matter of great controversy. Here, we report that incubation of 3T3-L1 adipocytes with specific inhibitors of V-type ATPase, concanamycin A and bafilomycin A1, inhibits insulin-regulated glucose transport and results in accumulation of GLUT4 in heavy, rapidly sedimenting intracellular membranes. Correspondingly, the amount of small responsive GLUT4 vesicles in concanamycin A- and bafilomycin A1-treated cells is decreased. We conclude that these drugs block translocation of GLUT4 in adipose cells by inhibiting formation of small insulin-responsive vesicles on donor intracellular membranes. At the same time, proton pump inhibitors do not affect insulin-dependent translocation of preexisting vesicles or GLUT4 sorting in recycling endosomes. On the contrary, wortmannin acutely inhibits insulin-dependent translocation of the preexisting vesicles but has no effect on vesicle formation.     

Insulin signaling: GLUT4 vesicles exit via the exocyst

The localization of the GTP-binding protein TC10 to lipid raft microdomains has been suggested to play a role in the stimulation of GLUT4 translocation. The exocyst has now been identified as a downstream target for TC10, directing GLUT4-containing vesicles to the site of fusion.     

Biogenesis of insulin-responsive GLUT4 vesicles is independent of brefeldin A-sensitive trafficking

Insulin stimulates translocation of GLUT4 from an intracellular compartment to the plasma membrane in adipocytes. As a significant amount of GLUT4 is localised to the TGN, independently of the biosynthetic pathway, one possibility is that trafficking via the TGN is important in either intracellular sequestration or insulin-dependent movement to the cell surface. In this study we have used immuno-electron microscopy to show that GLUT4 is localised to AP-1 vesicles in the TGN region in 3T3-L1 adipocytes. To dissect the role of this trafficking pathway we used brefeldin A (BFA) to disrupt AP-1 association with membranes. Despite a reorganisation of GLUT4 compartments following BFA treatment, the intracellular sequestration of GLUT4, and its insulin-dependent movement to the cell surface, was unaffected. BFA increased the half time of reversal of insulin-stimulated glucose transport from 17 to 30 min but did not prevent complete reversal. Furthermore, following reversal re-stimulation of glucose transport activity by insulin was not compromised. We conclude that under basal conditions GLUT4 cycles between the TGN and endosomes via the AP-1 pathway. However, neither this pathway, nor any other BFA-sensitive pathway, appears to play a major role in insulin-dependent recruitment of GLUT4 to the cell surface.     

Acyl-coenzyme A dehydrogenases are localized on GLUT4-containing vesicles via association with insulin-regulated aminopeptidase in a manner dependent on its dileucine motif

Insulin-regulated aminopeptidase (IRAP, also termed vp165) is known to be localized on the GLUT4-containing vesicles and to be recruited to the plasma membrane after stimulation with insulin. The cytoplasmic region of IRAP contains two dileucine motifs and acidic regions, one of which (amino acid residues 55-82) is reportedly involved in retention of GLUT4-containing vesicles. The region of IRAP fused with glutathione-S-transferase [GST-IRAP(55-82)] was incubated with lysates from 3T3-L1 adipocytes, leading to identification of long-chain, medium-chain, and short-chain acyl-coenzyme A dehydrogenases (ACDs) as the proteins associated with IRAP. The association was nearly abolished by mutation of the dileucine motif of IRAP. Immunoblotting of fractions prepared from sucrose gradient ultracentrifugation and vesicles immunopurified with anti-GLUT4 antibody revealed these ACDs to be localized on GLUT4-containing vesicles. Furthermore, 3-mercaptopropionic acid and hexanoyl-CoA, inhibitors of long-chain and medium-chain ACDs, respectively, induced dissociation of long-chain acyl-coenzyme A dehydrogenase and/or medium-chain acyl-coenzyme A dehydrogenase from IRAP in vitro as well as recruitment of GLUT4 to the plasma membrane and stimulation of glucose transport activity in permeabilized 3T3-L1 adipocytes. These findings suggest that ACDs are localized on GLUT4-containing vesicles via association with IRAP in a manner dependent on its dileucine motif and play a role in retention of GLUT4-containing vesicles to an intracellular compartment.     

以消散场成像和单微粒跟踪技术揭示GLUT4囊泡和分泌囊泡的不同动态过程

葡萄糖转运子蛋白4(glucose transporter 4,GLUT4)在维持体内葡萄糖动态平衡的过程中起着至关重要的作用。GLUT4贮存囊泡(GLUT4 storage vesicle,GSV)和神经内分泌细胞中的分泌囊泡含有许多相同的蛋白。研究证明这些蛋白调节了分泌囊泡的胞内转运过程,但是GLUT4囊泡和分泌囊泡是否具有相同的胞内动态过程还未阐明。文章以3T3-L1纤维原细胞中的GSV和神经内分泌细胞PC12细胞中的分泌囊泡:致密核心大囊泡(large dense core vesicle,LDCV)为研究对象,使用消散场显微成像技术和单微粒跟踪技术直观观察了活体细胞内单个GSV和LDCV的三维运动轨迹。通过以适当方程拟合单个囊泡的均方位移曲线,发现两种囊泡都具有三种运动模式。定量分析显示作自由扩散运动和方向性扩散运动的GSV数量明显多于LDCV。对比GSV和LDCV的三维扩散系数,发现GSV的扩散系数中值为7.2×10-4μm2/s,而LDCV的扩散系数中值仅为1.94×10-4μm2/s。这一结果说明GSV的活动性远大于LDCV,提示GSV的胞内转运过程涉及不同的分子机制。     

Akt2 phosphorylates Synip to regulate docking and fusion of GLUT4-containing vesicles

We have identified an unusual potential dual Akt/protein kinase B consensus phosphorylation motif in the protein Synip (RxKxRS(97)xS(99)). Surprisingly, serine 97 is not appreciably phosphorylated, whereas serine 99 is only a specific substrate for Akt2 but not Akt1 or Akt3. Although wild-type Synip (WT-Synip) undergoes an insulin-stimulated dissociation from Syntaxin4, the Synip serine 99 to phenylalanine mutant (S99F-Synip) is resistant to Akt2 phosphorylation and fails to display insulin-stimulated Syntaxin4 dissociation. Furthermore, overexpression of WT-Synip in 3T3L1 adipocytes had no effect on insulin-stimulated recruitment of glucose transporter 4 (GLUT4) to the plasma membrane, whereas overexpression of S99F-Synip functioned in a dominant-interfering manner by preventing insulin-stimulated GLUT4 recruitment and plasma membrane fusion. These data demonstrate that insulin activation of Akt2 specifically regulates the docking/fusion step of GLUT4-containing vesicles at the plasma membrane through the regulation of Synip phosphorylation and Synip-Syntaxin4 interaction.     

The adipocyte plasma membrane caveolin functional/structural organization is necessary for the efficient endocytosis of GLUT4

It is well established that insulin stimulation of glucose uptake requires the translocation of intracellular localized GLUT4 protein to the cell surface membrane. This plasma membrane-redistributed GLUT4 protein was partially co-localized with caveolin as determined by confocal fluorescent microscopy but was fully excluded from lipid rafts based upon Triton X-100 extractability. Cholesterol depletion with methyl-beta-cyclodextrin, filipin, or cholesterol oxidase resulted in an insulin-independent increase in the amount of plasma membrane-localized GLUT4 that was fully reversible by cholesterol replenishment. This basal accumulation of cell surface GLUT4 occurred due to an inhibition of GLUT4 endocytosis. However, this effect was not specific since cholesterol extraction also resulted in a dramatic inhibition of clathrin-mediated endocytosis as assessed by transferrin receptor internalization. To functionally distinguish between caveolin- and clathrin-dependent endocytic processes, we took advantage of a dominant-interfering caveolin 1 mutant (Cav1/S80E) that specifically disrupts caveolae organization. Expression of Cav1/S80E, but not the wild type (Cav1/WT) or Cav1/S80A mutant, inhibited cholera toxin B internalization without any significant effect on transferrin receptor endocytosis. In parallel, Cav1/S80E expression increased the amount of plasma membrane-localized GLUT4 protein in an insulin-independent manner. Although Cav1/S80E also decreased GLUT4 endocytosis, the extent of GLUT4 internalization was only partially reduced ( approximately 40%). In addition, expression of Cav1/WT and Cav1/S80A enhanced GLUT4 endocytosis by approximately 20%. Together, these data indicate that the endocytosis of GLUT4 requires clathrin-mediated endocytosis but that the higher order structural organization of plasma membrane caveolin has a significant influence on this process.     

Aldolase mediates the association of F-actin with the insulin-responsive glucose transporter GLUT4.

To identify potential proteins interacting with the insulin-responsive glucose transporter (GLUT4), we generated fusion proteins of glutathione S-transferase (GST) and the final 30 amino acids from GLUT4 (GST-G4) or GLUT1 (GST-G1). Incubation of these carboxyl-terminal fusion proteins with adipocyte cell extracts revealed a specific interaction of GLUT4 with fructose 1, 6-bisphosphate aldolase. In the presence of aldolase, GST-G4 but not GST-G1 was able to co-pellet with filamentous (F)-actin. This interaction was prevented by incubation with the aldolase substrates, fructose 1,6-bisphosphate or glyceraldehyde 3-phosphate. Immunofluorescence confocal microscopy demonstrated a significant co-localization of aldolase and GLUT4 in intact 3T3L1 adipocytes, which decreased following insulin stimulation. Introduction into permeabilized 3T3L1 adipocytes of fructose 1,6-bisphosphate or the metabolic inhibitor 2-deoxyglucose, two agents that disrupt the interaction between aldolase and actin, inhibited insulin-stimulated GLUT4 exocytosis without affecting GLUT4 endocytosis. Furthermore, microinjection of an aldolase-specific antibody also inhibited insulin-stimulated GLUT4 translocation. These data suggest that aldolase functions as a scaffolding protein for GLUT4 and that glucose metabolism may provide a negative feedback signal for the regulation of glucose transport by insulin.     

Induction of p18INK4c and its predominant association with CDK4 and CDK6 during myogenic differentiation.

Terminal cell differentiation involves permanent withdrawal from the cell division cycle. The inhibitors of cyclin-dependent kinases (CDKs) are potential molecules functioning to couple cell cycle arrest and cell differentiation. In murine C2C12 myoblast cells, G1 CDK enzymes (CDK2, CDK4, and CDK6) associate with four CDK inhibitors: p18INK4c, p19INK4d, p21, and p27Kip1. During induced myogenesis, p21 and its associated CDK proteins underwent an initial increase followed by a decrease as cells became terminally differentiated. The level of p27 protein gradually increased, but the amount of total associated CDK proteins remained unchanged. p19 protein decreased gradually during differentiation, as did its associated CDK4 protein. In contrast, p18 protein increased 50-fold, from negligible levels in proliferating myoblasts to clearly detectable levels within 8-12 h of myogenic induction. This initial rise was followed by a precipitous increase between 12 and 24 h postinduction, with p18 protein finally accumulating to its highest level in terminally differentiated cells. Induction of p18 correlated with increased and sequential complex formation--first increasing association with CDK6 and then with CDK4 over the course of myogenic differentiation. All of the CDK6 and half of the CDK4 were complexed with p18 in terminally differentiated C2C12 cells as well as in adult mouse muscle tissue. Finally, kinase activity of CDK2 and CDK4 decreases as C2C12 cells differentiate, whereas the CDK6 kinase activity is low in both proliferating myoblasts and differentiated myotubes. Our results indicate that p18 may play a critical role in causing and/or maintaining permanent cell cycle arrest associated with mature muscle formation.     

Tankyrase is a golgi-associated mitogen-activated protein kinase substrate that interacts with IRAP in GLUT4 vesicles

The poly(ADP-ribose) polymerase tankyrase was originally described as a telomeric protein whose catalytic activity was proposed to regulate telomere function. Subsequent studies revealed that most tankyrase is actually extranuclear, but a discordant pattern of cytoplasmic targeting was reported. Here we used fractionation and immunofluorescence to show in 3T3-L1 fibroblasts that tankyrase is a peripheral membrane protein associated with the Golgi. We further colocalized tankyrase with GLUT4 storage vesicles in the juxtanuclear region of adipocytes. Consistent with this colocalization, we found that tankyrase binds specifically to a resident protein of GLUT4 vesicles, IRAP (insulin-responsive amino peptidase). The binding of tankyrase to IRAP involves the ankyrin repeats of tankyrase and a defined sequence ((96)RQSPDG(101)) in the IRAP cytosolic domain (IRAP(1-109)). Tankyrase is a novel signaling target of mitogen-activated protein kinase (MAPK); it is stoichiometrically phosphorylated upon insulin stimulation. Phosphorylation enhances the poly(ADP-ribose) polymerase activity of tankyrase but apparently does not mediate the acute effect of insulin on GLUT4 targeting. Taken together, tankyrase is a novel target of MAPK signaling in the Golgi, where it is tethered to GLUT4 vesicles by binding to IRAP. We speculate that tankyrase may be involved in the long term effect of the MAPK cascade on the metabolism of GLUT4 vesicles.     

Phosphatidylinositol 4-kinase is a component of glucose transporter (GLUT 4)-containing vesicles.

We recently developed a procedure for immunoisolating insulin-responsive membrane vesicles that contain the muscle/fat glucose transporter isoform, GLUT 4, from rat adipocytes. Utilizing this methodology, we are analyzing the components of these vesicles to gain an understanding of how they are regulated by insulin. In this report we identify a phosphatidylinositol (PtdIns) 4-kinase as a constituent of glucose transporter vesicles (GTVs). This kinase has the biochemical and immunological properties of a type II PtdIns 4-kinase as classified by Endeman et al. (Endemann, G., Dunn, S. N., and Cantley, L. C. (1987) Biochemistry 26, 6845-6852). A monoclonal antibody, 4C5G, which specifically inhibits the type II PtdIns 4-kinase, suppresses 80% of the GTV-PtdIns 4-kinase activity. In addition, the GTVs-PtdIns 4-kinase is maximally activated by the nonionic detergent Triton X-100, at a concentration of 0.2% and is inhibited by adenosine with a Ki of approximately 20-30 microM. We find that the GTVs do not contain any PtdIns4P 5-kinase or diacylglycerol kinase activities, whereas these activities were detected in the plasma membrane. An analysis of the subcellular distribution of PtdIns 4-kinase activity in the rat adipocyte shows that there are similar levels of activity in GTVs, plasma membranes, and the high and low density microsomal fractions, whereas the mitochondria- and nuclei-containing fractions have less than 5% of the activity seen in other fractions. Low density microsomes were subfractionated by sucrose density gradient centrifugation and PtdIns 4-kinase activity was found to correlate closely with the distribution of membrane protein, indicating that the activity is equally distributed throughout this heterogenous population of membranes. PtdIns 4-kinase activity measured in GTVs, plasma membranes, and low density microsomes, was not affected by prior treatment of the intact adipocytes with 35 nM insulin. We postulate that while the GTV-PtdIns 4-kinase is not regulated by insulin, it may play a role in defining the fusogenic properties necessary to mediate membrane movement between the GTVs, plasma membranes, and microsomes.     

Bi-directional transport of GLUT4 vesicles near the plasma membrane of primary rat adipocytes

Insulin stimulates glucose uptake into adipocytes by mobilizing intracellular membrane vesicles containing GLUT4 proteins to the plasma membrane. Here we applied time-lapse total internal reflection fluorescence microscopy to study moving parameters and characters of exogenously expressed GLUT4 vesicles in basal, insulin and nocodazole treated primary rat adipocytes. Our results showed that microtubules were essential for long-range transport of GLUT4 vesicles but not obligatory for GLUT4 distribution in rat adipocytes. Insulin reduced the mobility of the vesicles, made them tethered/docked to the PM and finally had constitutive exocytosis. Moreover, long-range bi-directional movements of GLUT4 vesicles were visualized for the first time by TIRFM. It is likely that there are interactions between insulin signaling and microtubules, to regulating GLUT4 translocation in rat adipocytes.