Insulin stimulates the translocation of the glucose transporter GLUT4 from intracellular vesicles to the plasma membrane. In the present study we have conducted a comprehensive proteomic analysis of affinity-purified GLUT4 vesicles from 3T3-L1 adipocytes to discover potential regulators of GLUT4 trafficking. In addition to previously identified components of GLUT4 storage vesicles including the insulin-regulated aminopeptidase insulin-regulated aminopeptidase and the vesicle soluble N-ethylmaleimide factor attachment protein (v-SNARE) VAMP2, we have identified three new Rab proteins, Rab10, Rab11, and Rab14, on GLUT4 vesicles. We have also found that the putative Rab GTPase-activating protein AS160 (Akt substrate of 160 kDa) is associated with GLUT4 vesicles in the basal state and dissociates in response to insulin. This association is likely to be mediated by the cytosolic tail of insulinregulated aminopeptidase, which interacted both in vitro and in vivo with AS160. Consistent with an inhibitory role of AS160 in the basal state, reduced expression of AS160 in adipocytes using short hairpin RNA increased plasma membrane levels of GLUT4 in an insulin-independent manner. These findings support an important role for AS160 in the insulin regulated trafficking of GLUT4.Glucose transport into mammalian muscle and fat cells is an important step in insulin action and is critical for the maintenance of glucose homeostasis within the body (1). In mammalian muscle and fat cells, insulin stimulation activates a phosphorylation cascade, which in turn causes intracellular vesicles that contain the glucose transporter GLUT4, 4 to translocate to the plasma membrane (PM) and fuse (2, 3). In the basal state GLUT4 is distributed between the endosomal system, the trans-Golgi network (TGN), and a GLUT4 storage vesicle (GSV) compartment that is highly insulin-responsive (4 -6).The protein kinase Akt is activated in response to insulin and plays a critical role in GLUT4 translocation (1, 7). However, the link between the insulin signaling pathway and GLUT4 translocation is not fully understood. The insulin-dependent movement of GLUT4 vesicles to the PM is an Akt-independent process, and this is followed by an Aktdependent step likely involving the docking and fusion of vesicles with the PM (7-9). The mechanism by which Akt controls the docking and fusion of GLUT4 vesicles with the PM is not known. However, it was previously shown that a Rab GTPase-activating protein (RabGAP) known as AS160 is phosphorylated by Akt in response to insulin (10). How AS160 functions in GLUT4 trafficking and its cognate Rab proteins are not known. The role of a variety of Rab proteins in GLUT4 trafficking including Rab3d, Rab4, Rab5, and Rab11 has been examined (11-16). However, although these Rab proteins may participate in some aspects of GLUT4 trafficking, no compelling evidence for specific involvement in the insulin-regulated trafficking of GLUT4 has been found.In this study we describe four key findings that add to our understanding of GLUT4 traffic...
Insulin stimulates glucose transport in fat and muscle cells by triggering exocytosis of the glucose transporter GLUT4. To define the intracellular trafficking of GLUT4, we have studied the internalization of an epitope-tagged version of GLUT4 from the cell surface. GLUT4 rapidly traversed the endosomal system en route to a perinuclear location. This perinuclear GLUT4 compartment did not colocalize with endosomal markers (endosomal antigen 1 protein, transferrin) or TGN38, but showed significant overlap with the TGN target (t)-soluble N-ethylmaleimide-sensitive factor attachment protein receptors (SNAREs) Syntaxins 6 and 16. These results were confirmed by vesicle immunoisolation. Consistent with a role for Syntaxins 6 and 16 in GLUT4 trafficking we found that their expression was up-regulated significantly during adipocyte differentiation and insulin stimulated their movement to the cell surface. GLUT4 trafficking between endosomes and trans-Golgi network was regulated via an acidic targeting motif in the carboxy terminus of GLUT4, because a mutant lacking this motif was retained in endosomes. We conclude that GLUT4 is rapidly transported from the cell surface to a subdomain of the trans-Golgi network that is enriched in the t-SNAREs Syntaxins 6 and 16 and that an acidic targeting motif in the C-terminal tail of GLUT4 plays an important role in this process. INTRODUCTIONInsulin stimulates glucose uptake in muscle and fat cells by triggering translocation of the glucose transporter GLUT4 from an intracellular compartment to the cell surface (Bryant et al., 2002). The intracellular localization of GLUT4 in adipocytes includes the endosomal system, trans-Golgi network (TGN), cytoplasmic tubulovesicular elements and the cell surface, suggesting a complex intracellular trafficking itinerary (Slot et al., 1991b;Martin et al., 2000a). Although previous studies have indicated a role for endosomes in GLUT4 trafficking (Slot et al., 1991b;Livingstone et al., 1996) the precise role of the TGN is not clear. Several observations suggest an important role for the TGN in GLUT4 trafficking. First, there is a significant amount of GLUT4 in the TGN area in insulin-responsive cells (Slot et al., 1991a,b;Ralston and Ploug, 1996;Wang et al., 1996;Slot et al., 1997;Ploug et al., 1998;Martin et al., 2000a). Second, ϳ60% of the entire GLUT4 pool is localized to atrial natriuretic factorcontaining secretory granules in atrial cardiomyocytes and this seems to be due to recycling of GLUT4 through the TGN area (Slot et al., 1997). Third, there is significant overlap between GLUT4 and proteins known to traffic between the TGN and endosomes, including the cation-dependent mannose 6-phosphate receptor (Martin et al., 2000a), the cation-independent mannose 6-phosphate receptor (Kandror and Pilch, 1996), and adaptor-related protein complex-1 (Gillingham et al., 1999;Martin et al., 2000b These data suggest that the TGN contributes to the trafficking of GLUT4, adding a further layer of complexity to understanding the insulin-regulated movement ...
Previously we described clathrin-coated buds on tubular early endosomes that are distinct from those at the plasma membrane and the trans-Golgi network. Here we show that these clathrincoated buds, like plasma membrane clathrin-coated pits, contain endogenous dynamin-2. To study the itinerary that is served by endosome-derived clathrin-coated vesicles, we used cells that overexpressed a temperature-sensitive mutant of dynamin-1 (dynamin-1 G273D ) or, as a control, dynamin-1 wild type. In dynamin-1 G273D -expressing cells, 29 -36% of endocytosed transferrin failed to recycle at the nonpermissive temperature and remained associated with tubular recycling endosomes. Sorting of endocytosed transferrin from fluid-phase endocytosed markers in early endosome antigen 1-labeled sorting endosomes was not inhibited. Dynamin-1 G273D associated with accumulated clathrin-coated buds on extended tubular recycling endosomes. Brefeldin A interfered with the assembly of clathrin coats on endosomes and reduced the extent of transferrin recycling in control cells but did not further affect recycling by dynamin-1 G273D -expressing cells. Together, these data indicate that the pathway from recycling endosomes to the plasma membrane is mediated, at least in part, by endosome-derived clathrin-coated vesicles in a dynamindependent manner.
Dynamin is a GTPase enzyme involved in membrane constriction and fission during endocytosis. Phospholipid binding via its pleckstrin homology domain maximally stimulates dynamin activity. We developed a series of surface-active small-molecule inhibitors, such as myristyl trimethyl ammonium bromide (MiTMAB) and octadecyltrimethyl ammonium bromide (OcTMAB), and we now show MiTMAB targets the dynamin-phospholipid interaction. MiT-MAB inhibited dynamin GTPase activity, with a K i of 940 Ϯ 25 nM. It potently inhibited receptor-mediated endocytosis (RME) of transferrin or epidermal growth factor (EGF) in a range of cells without blocking EGF binding, receptor number, or autophosphorylation. RME inhibition was rapidly reversed after washout. The rank order of potency for a variety of MiTMAB analogs on RME matched the rank order for dynamin inhibition, suggesting dynamin recruitment to the membrane is a primary cellular target. MiTMAB also inhibited synaptic vesicle endocytosis in rat brain nerve terminals (synaptosomes) without inducing depolarization or morphological defects. Therefore, the drug rapidly and reversibly blocks multiple forms of endocytosis with no acute cellular damage. The unique mechanism of action of MiTMAB provides an important tool to better understand dynamin-mediated membrane trafficking events in a variety of cells.
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