Endosomal proteases facilitate the fusion of endosomes with vacuoles at the final step of the endocytotic pathway

The mechanism by which plasma membrane proteins are transported to vacuoles for degradation has not been well characterized in plants. To clarify how plasma membrane proteins are degraded, we monitored the endocytotic pathway in tobacco suspension-cultured BY-2 cells with a fluorescent endocytosis marker, FM4-64. Because of the efficient and rapid delivery of endosomes to the vacuoles, endosomes were scarcely detectable. Interestingly, we found that E-64d, an inhibitor of papain family proteases, caused the accumulation of a large number of endosomes in the cells under the sucrose-starved condition. This result indicates that E-64d attenuates the fusion of endosomes with vacuoles. We identified two papain homologues, which are localized in the endosomes, with a biotinylated inhibitor. We designated them as endosome-localized papains (ENPs). Immunofluorescent analysis revealed that vacuolar sorting receptor, a marker of prevacuolar compartment (PVC), was localized in the endosomes. This result and their acidic nature show that the endosomes correspond to PVC. These results suggest that ENPs facilitate the final step in the vacuolar trafficking pathway under the sucrose-starved condition. We further examined the effects of E-64d on two transgenic Arabidopsis plants that constitutively express a fusion protein composed of green fluorescent protein (GFP) and a plasma membrane protein (GFP-PIP2a or GFP-LTI6b). GFP fluorescence was observed on the plasma membrane of root cells in these transgenic plants. Treatment with E-64d induced the accumulation of GFP-fluorescent endosomes and inhibited the degradation of these fusion proteins. No GFP fluorescence was observed in vacuoles in E-64d-treated transgenic plants. Taken together, these results suggest that endosomal proteases are required for the fusion of endosomes with vacuoles at the final step in the endocytotic pathway for degradation of plasma membrane proteins in plants.     

Lipid Sorting by Ceramide Structure from Plasma Membrane to ER for the Cholera Toxin Receptor Ganglioside GM1

The glycosphingolipid GM1 binds cholera toxin (CT) on host cells and carries it retrograde from the plasma membrane (PM) through endosomes, the trans-Golgi (TGN), and the endoplasmic reticulum (ER) to induce toxicity. To elucidate how a membrane?lipid can specify trafficking in these pathways, we synthesized GM1 isoforms with alternate ceramide domains and imaged their trafficking in live cells.?Only GM1 with unsaturated acyl chains sorted efficiently from PM to TGN and ER. Toxin binding, which effectively crosslinks GM1 lipids, was dispensable, but membrane cholesterol and the lipid raft-associated proteins actin and flotillin were required. The results implicate a protein-dependent mechanism of lipid sorting by ceramide structure and provide a molecular explanation for the diversity?and specificity of retrograde trafficking by CT in?host cells.     

Trafficking of green fluorescent protein tagged-vesicular acetylcholine transporter to varicosities in a cholinergic cell line

Synaptic vesicle proteins are suggested to travel from the trans-Golgi network to active zones via tubulovesicular organelles, but the participation of different populations of endosomes in trafficking remains a matter of debate. Therefore, we generated a green fluorescent protein (GFP)-tagged version of the vesicular acetylcholine transporter (VAChT) and studied the localization of VAChT in organelles in the cell body and varicosities of living cholinergic cells. GFP-VAChT is distributed to both early and recycling endosomes in the cell body and is also observed to accumulate in endocytic organelles within varicosities of SN56 cells. GFP-VAChT positive organelles in varicosities are localized close to plasma membrane and are labeled with FM4-64 and GFP-Rab5, markers of endocytic vesicles and early endosomes, respectively. A GFP-VAChT mutant lacking a dileucine endocytosis motif (leucine residues 485 and 486 changed to alanine residues) accumulated at the plasma membrane in SN56 cells. This endocytosis-defective GFP-VAChT mutant is localized primarily at the somal plasma membrane and exhibits reduced neuritic targeting. Furthermore, the VAChT mutant did not accumulate in varicosities, as did VAChT. Our data suggest that clathrin-mediated internalization of VAChT to endosomes at the cell body might be involved in proper sorting and trafficking of VAChT to varicosities. We conclude that genesis of competent cholinergic secretory vesicles depends on multiple interactions of VAChT with endocytic proteins.     

GGA2- and ubiquitin-dependent trafficking of Arn1, the ferrichrome transporter of Saccharomyces cerevisiae

The intracellular trafficking of Arn1, a ferrichrome transporter in Saccharomyces cerevisiae, is controlled in part by the binding of ferrichrome to the transporter. In the absence of ferrichrome, Arn1 is sorted directly from the Golgi to endosomes. Ferrichrome binding triggers the redistribution of Arn1 to the plasma membrane, whereas ferrichrome transport is associated with the cycling of Arn1 between the plasma membrane and endosomes. Here, we report that the clathrin adaptor Gga2 and ubiquitination by the Rsp5 ubiquitin ligase are required for trafficking of Arn1. Gga2 was required for Golgi-to-endosomal trafficking of Arn1, which was sorted from endosomes to the vacuole for degradation. Trafficking into the vacuolar lumen was dependent on ubiquitination by Rsp5, but ubiquitination was not required for plasma membrane accumulation of Arn1 in the presence of ferrichrome. Retrograde trafficking via the retromer complex or Snx4 was also not required for plasma membrane accumulation. High concentrations of ferrichrome led to higher levels of ubiquitination of Arn1, but they did not induce degradation. Without this ubiquitination, Arn1 remained on the plasma membrane, where it was active for transport. Arn1 was preferentially modified with polyubiquitin chains on a cluster of lysine residues at the amino terminus of the transporter.     

Phosphoinositides and membrane traffic at the trans-Golgi network

Cargo proteins moving along the secretory pathway are sorted at the TGN (trans-Golgi network) into distinct carriers for delivery to the plasma membrane or endosomes. Recent studies in yeast and mammals have shown that formation of these carriers is regulated by PtdIns(4)P. This phosphoinositide is abundant at the TGN and acts to recruit components required for carrier formation to the membrane. Other phosphoinositides are also present on the TGN, but the extent to which they regulate trafficking is less clear. Further characterization of phosphoinositide kinases and phosphatases together with identification of new TGN-associated phosphoinositide-binding proteins will reveal the extent to which different phosphoinositides regulate TGN trafficking, and help define the molecular mechanisms involved.     

The VEGFR2 receptor tyrosine kinase undergoes constitutive endosome-to-plasma membrane recycling

The VEGFR2 receptor tyrosine kinase regulates vascular physiology and animal development. The mechanism underlying VEGFR2 membrane trafficking is not well understood. Herein, we show that VEGFR2 undergoes membrane recycling in both vascular and non-vascular cells. In primary human endothelial cells, VEGFR2 normally distributes between the plasma membrane and early endosomes undergoing endocytosis and recycling. This pathway is independent of VEGFR tyrosine kinase activity and occurs constitutively, similar to other integral membrane proteins such as the transferrin receptor and β1 integrin. Expression of a VEGFR2-EGFP hybrid protein in non-vascular cells revealed plasma membrane and endosome distribution. The VEGF-A ligand stimulated phosphorylation of residue Y1175 on VEGFR2-EGFP which is a key hallmark of receptor activation. Live cell imaging and quantitative analysis showed that activated VEGFR2-EGFP displayed reduced mobility linked to endocytosis and recycling between the plasma membrane and endosomes. Total internal reflection microscopy and kinetics indicates that VEGFR2 undergoes recycling between the plasma membrane and peripheral endosomes proximal to the membrane bilayer. We thus provide evidence that the VEGFR2 receptor tyrosine kinase undertakes a constitutive recycling pathway between the peripheral endosomes and cell surface and this exists in both vascular and non-vascular cells.     

Membrane protein trafficking through the common apical endosome compartment of polarized Caco-2 cells.

By raising monoclonal antibodies to the apical surface of Caco-2 cells we have identified a membrane protein (p100) that internalizes and recycles constitutively between the apical plasma membrane and endosomes in the apical cytoplasm. By applying tracers bound to the transferrin receptor, which internalizes and recycles back to the basolateral border, we demonstrate that the apical endosomes containing p100 include a subset of multivesticular bodies (MVB), which are also accessible to proteins arriving from the basolateral endosome. Tracers bound to EGF receptors and alpha-2-macroglobulin, which internalize from the basolateral border and are degraded, probably in lysosomes, also pass through the p100-containing MVB. These studies therefore suggest that the apical cytoplasm of Caco-2 cells contains a population of MVB capable of receiving membrane proteins trafficking in from both apical and basolateral borders and then routing them to a variety of cell surface and intracellular destinations. The differential distribution of apical and basolateral tracers within the 50-nm-diameter tubules connected to these p100-positive apical MVB suggests that the destination of proteins trafficking from the MVB back to apical and basolateral surfaces is determined by the tubules to which they gain access.     

Intracellular Distribution of Human T-Cell Leukemia Virus Type 1 Gag Proteins Is Independent of Interaction with Intracellular Membranes

Retrovirus Gag proteins are synthesized on free ribosomes, and are sufficient to govern the assembly and release of virus particles. Like type C retroviruses, human T-cell leukemia virus type 1 (HTLV-1) assembles and buds at the plasma membrane. After immunofluorescence staining, HTLV-1 Gag proteins appear as punctuated intracellular clusters, which suggests that they are associated either with intracellular membranes or with the plasma membrane. However, colocalization experiments using a panel of markers demonstrated that Gag proteins were not associated with the membranes involved in the secretory or endocytosis pathway. Small amounts of Gag proteins were detected at the plasma membrane and colocalized with the envelope glycoproteins. Moreover, Gag proteins were excluded from streptolysin-O permeabilized cells and in this respect behaved like cytoplasmic proteins. This suggests that the trafficking of HTLV-1 Gag proteins through the cytoplasm of the host cell is independent of any cell membrane system.     

Cholesterol level regulates endosome motility via Rab proteins

The role of cholesterol in the regulation of endosome motility was investigated by monitoring the intracellular trafficking of endocytosed folate receptors (FRs) labeled with fluorescent folate conjugates. Real-time fluorescence imaging of HeLa cells transfected with green fluorescent protein-tubulin revealed that FR-containing endosomes migrate along microtubules. Moreover, microinjection with antibodies that inhibit microtubule-associated motor proteins demonstrated that dynein and kinesin I participate in the delivery of FR-containing endosomes to the perinuclear area and plasma membrane, respectively. Further, single-particle tracking analysis revealed bidirectional motions of FR endosomes, mediated by dynein and kinesin motors associated with the same endosome. These experimental tools allowed us to use FR-containing endosomes to evaluate the impact of cholesterol on intracellular membrane trafficking. Lowering plasma membrane cholesterol by metabolic depletion or methyl-β-cyclodextrin extraction was found to both increase FR-containing endosome motility and change endosome distribution from colocalization with Rab7 to colocalization with Rab4. These data provide evidence that cholesterol regulates intracellular membrane trafficking via modulation of the distribution of low molecular weight G-proteins that are adaptors for microtubule motors.     

Association of myosin I alpha with endosomes and lysosomes in mammalian cells

Myosin Is, which constitute a ubiquitous monomeric subclass of myosins with actin-based motor properties, are associated with plasma membrane and intracellular vesicles. Myosin Is have been proposed as key players for membrane trafficking in endocytosis or exocytosis. In the present paper we provide biochemical and immunoelectron microscopic evidence indicating that a pool of myosin I alpha (MMIalpha) is associated with endosomes and lysosomes. We show that the overproduction of MMIalpha or the production of nonfunctional truncated MMIalpha affects the distribution of the endocytic compartments. We also show that truncated brush border myosin I proteins, myosin Is that share 78% homology with MMIalpha, promote the dissociation of MMIalpha from vesicular membranes derived from endocytic compartments. The analysis at the ultrastructural level of cells producing these brush border myosin I truncated proteins shows that the delivery of the fluid phase markers from endosomes to lysosomes is impaired. MMIalpha might therefore be involved in membrane trafficking occurring between endosomes and lysosomes.     

Endoplasmic reticulum–endosome contact increases as endosomes traffic and mature

The endosomal pathway is responsible for plasma membrane cargo uptake, sorting, and, in many cases, lysosome targeting. Endosome maturation is complex, requiring proper spatiotemporal recruitment of factors that regulate the size, maturity, and positioning of endosomal compartments. In animal cells, it also requires trafficking of endosomes on microtubules. Recent work has revealed the presence of contact sites between some endosomes and the endoplasmic reticulum (ER). Although these contact sites are believed to have multiple functions, the frequency, dynamics, and physical attributes of these contacts are poorly understood. Here we use high-resolution three-dimensional electron microscopy to reveal that ER tubules wrap around endosomes and find that both organelles contact microtubules at or near membrane contact sites. As endosomes traffic, they remain bound to the ER, which causes the tubular ER to rearrange its structure around dynamic endosomes at contact sites. Finally, as endosomes transition through steps of maturation, they become more tightly associated with the ER. The major implication of these results is that endosomes mature and traffic while coupled to the ER membrane rather than in isolation.     

Oligomerization of dopamine transporters visualized in living cells by fluorescence resonance energy transfer microscopy

To examine the oligomeric state and trafficking of the dopamine transporter (DAT) in different compartments of living cells, human DAT was fused to yellow (YFP) or cyan fluorescent protein (CFP). YFP-DAT and CFP-DAT were transiently and stably expressed in porcine aortic endothelial (PAE) cells, human embryonic kidney (HEK) 293 cells, and an immortalized dopaminergic cell line 1RB3AN27. Fluorescence microscopic imaging of cells co-expressing YFP-DAT and CFP-DAT revealed fluorescence resonance energy transfer (FRET) between CFP and YFP, which is consistent with an intermolecular interaction of DAT fusion proteins. FRET signals were detected between CFP- and YFP-DAT located at the plasma membrane and in intracellular membrane compartments. Phorbol esters or amphetamine induced the endocytosis of YFP/CFP-DAT to early and recycling endosomes, identified by Rab5, Rab11, Hrs and EEA.1 proteins. Interestingly, however, DAT was mainly excluded from Rab5- and Hrs-containing microdomains within the endosomes. The strongest FRET signals were measured in endosomes, indicative of efficient oligomerization of internalized DAT. The intermolecular DAT interactions were confirmed by co-immunoprecipitation. A DAT mutant that was retained in the endoplasmic reticulum (ER) after biosynthesis was used to show that DAT is oligomeric in the ER. Moreover, co-expression of an ER-retained DAT mutant and wild-type DAT resulted in the retention of wild-type DAT in the ER. These data suggest that DAT oligomers are formed in the ER and then are constitutively maintained both at the cell surface and during trafficking between the plasma membrane and endosomes.     

Sterol, protein and lipid trafficking in Chinese hamster ovary cells with Niemann-Pick type C1 defect

We studied the trafficking of sterols, lipids and proteins in Niemann-Pick type C (NPC) cells. The NPC is an inherited disorder involving the accumulation of sterol and lipids in modified late-endosome/lysosome-like storage organelles. Most sterol accumulation studies in NPC cells have been carried out using low-density lipoprotein (LDL) as the sterol source, and it has been shown that sterol efflux from late endosomes is impaired in NPC cells. In this study, we used a fluorescent sterol analog, dehydroergosterol, which can be quickly and efficiently delivered to the plasma membrane. Thus, we were able to study the trafficking kinetics of the non-LDL-derived sterol pool, and we found that dehydroergosterol accumulates in the storage organelles over the course of several hours in NPC cells. We also found that dialkylindocarbocyanine lipid-mimetic analogs that recycle efficiently from early endosomes in wild-type cells are targeted to late endosomal organelles in NPC cells, and transferrin receptors recycle slowly and inefficiently in NPC cells. These data are consistent with multiple trafficking defects in both early and late endosomes in NPC cells.     

From sorting endosomes to exocytosis: association of Rab4 and Rab11 GTPases with the Fc receptor, FcRn, during recycling

A longstanding question in cell biology is how is the routing of intracellular organelles within cells regulated? Although data support the involvement of Rab4 and Rab11 GTPases in the recycling pathway, the function of Rab11 in particular is uncertain. Here we have analyzed the association of these two Rab GTPases with the Fc receptor, FcRn, during intracellular trafficking. This Fc receptor is both functionally and structurally distinct from the classical Fcgamma receptors and transports immunoglobulin G (IgG) within cells. FcRn is therefore a recycling receptor that sorts bound IgG from unbound IgG in sorting endosomes. In the current study we have used dual color total internal reflection fluorescence microscopy (TIRFM) and wide-field imaging of live cells to analyze the events in human endothelial cells that are involved in the trafficking of FcRn positive (FcRn(+)) recycling compartments from sorting endosomes to exocytic sites at the plasma membrane. Our data are consistent with the following model for this pathway: FcRn leaves sorting endosomes in Rab4(+)Rab11(+) or Rab11(+) compartments. For Rab4(+)Rab11(+) compartments, Rab4 depletion occurs by segregation of the two Rab proteins into discrete domains that can separate. The Rab11(+)FcRn(+) vesicle or tubule subsequently fuses with the plasma membrane in an exocytic event. In contrast to Rab11, Rab4 is not involved in exocytosis.     

NgCAM and VAMP2 reveal that direct delivery and dendritic degradation maintain axonal polarity

Neurons are polarized cells of extreme scale and compartmentalization. To fulfill their role in electrochemical signaling, axons must maintain a specific complement of membrane proteins. Despite being the subject of considerable attention, the trafficking pathway of axonal membrane proteins is not well understood. Two pathways, direct delivery and transcytosis, have been proposed. Previous studies reached contradictory conclusions about which of these mediates delivery of axonal membrane proteins to their destination, in part because they evaluated long-term distribution changes and not vesicle transport. We developed a novel strategy to selectively label vesicles in different trafficking pathways and determined the trafficking of two canonical axonal membrane proteins, neuron–glia cell adhesion molecule and vesicle-associated membrane protein-2. Results from detailed quantitative analyses of transporting vesicles differed substantially from previous studies and found that axonal membrane proteins overwhelmingly undergo direct delivery. Transcytosis plays only a minor role in axonal delivery of these proteins. In addition, we identified a novel pathway by which wayward axonal proteins that reach the dendritic plasma membrane are targeted to lysosomes. These results redefine how axonal proteins achieve their polarized distribution, a crucial requirement for elucidating the underlying molecular mechanisms.     

A Highlights from MBoC Selection: α-Arrestins Aly1 and Aly2 Regulate Intracellular Trafficking in Response to Nutrient Signaling

Extracellular signals regulate trafficking events to reorganize proteins at the plasma membrane (PM); however, few effectors of this regulation have been identified. β-Arrestins relay signaling cues to the trafficking machinery by controlling agonist-stimulated endocytosis of G-protein–coupled receptors. In contrast, we show that yeast α-arrestins, Aly1 and Aly2, control intracellular sorting of Gap1, the general amino acid permease, in response to nutrients. These studies are the first to demonstrate association of α-arrestins with clathrin and clathrin adaptor proteins (AP) and show that Aly1 and Aly2 interact directly with the γ-subunit of AP-1, Apl4. Aly2-dependent trafficking of Gap1 requires AP-1, which mediates endosome-to-Golgi transport, and the nutrient-regulated kinase, Npr1, which phosphorylates Aly2. During nitrogen starvation, Npr1 phosphorylation of Aly2 may stimulate Gap1 incorporation into AP-1/clathrin-coated vesicles to promote Gap1 trafficking from endosomes to the trans-Golgi network. Ultimately, increased Aly1-/Aly2-mediated recycling of Gap1 from endosomes results in higher Gap1 levels within cells and at the PM by diverting Gap away from trafficking pathways that lead to vacuolar degradation. This work defines a new role for arrestins in membrane trafficking and offers insight into how α-arrestins coordinate signaling events with protein trafficking.     

Assembly and trafficking of heterotrimeric G proteins

To be activated by cell surface G protein-coupled receptors, heterotrimeric G proteins must localize at the cytoplasmic surface of plasma membranes. Moreover, some G protein subunits are able to traffic reversibly from the plasma membrane to intracellular locations upon activation. This current topic will highlight new insights into how nascent G protein subunits are assembled and how they arrive at plasma membranes. In addition, recent reports have increased our knowledge of activation-induced trafficking of G proteins. Understanding G protein assembly and trafficking will lead to a greater understanding of novel ways that cells regulate G protein signaling.     

Trafficking of immunoglobulin receptors in epithelial cells:signals and cellular factors

A typical feature of epithelial cells is the polarized distribution of their respective plasma membrane proteins. Apical and basolateral proteins can be sorted both in the trans-Golgi network and endosomes, or in both locations. Inclusion into basolateral carriers in the TGN requires the presence of distinct cytoplasmic determinants, which also appear to be recognized in endosomes. Inactivation of the basolateral sorting information leads to the efficient apical delivery, probably due to the unmasking of a recessive apical signal. Factors associated with the cytosolic face of organelles probably not only recognize these signals to mediate the inclusion of the proteins into the correct transport vesicles, but also target the carriers to the corresponding plasma membrane domain. Our interest has focused on analyzing at the molecular level how epithelial MDCK cells generate and maintain a polarized phenotype, taking advantage of immunoglobulin receptors to study the biosynthetic and endocytic pathways and the corresponding sorting events.     

SNAP25, but not syntaxin 1A, recycles via an ARF6-regulated pathway in neuroendocrine cells

Soluble N-ethylmaleimide-sensitive fusion protein attachment protein receptor (SNARE) proteins mediate cellular membrane fusion events and provide a level of specificity to donor-acceptor membrane interactions. However, the trafficking pathways by which individual SNARE proteins are targeted to specific membrane compartments are not well understood. In neuroendocrine cells, synaptosome-associated protein of 25 kDa (SNAP25) is localized to the plasma membrane where it functions in regulated secretory vesicle exocytosis, but it is also found on intracellular membranes. We identified a dynamic recycling pathway for SNAP25 in PC12 cells through which plasma membrane SNAP25 recycles in approximately 3 h. Approximately 20% of the SNAP25 resides in a perinuclear recycling endosome-trans-Golgi network (TGN) compartment from which it recycles back to the plasma membrane. SNAP25 internalization occurs by constitutive, dynamin-independent endocytosis that is distinct from the dynamin-dependent endocytosis that retrieves secretory vesicle constituents after exocytosis. Endocytosis of SNAP25 is regulated by ADP-ribosylation factor (ARF)6 (through phosphatidylinositol bisphosphate synthesis) and is dependent upon F-actin. SNAP25 endosomes, which exclude the plasma membrane SNARE syntaxin 1A, merge with those derived from clathrin-dependent endocytosis containing endosomal syntaxin 13. Our results characterize a robust ARF6-dependent internalization mechanism that maintains an intracellular pool of SNAP25, which is compatible with possible intracellular roles for SNAP25 in neuroendocrine cells.     

Membrane Organization and Dynamics in Cell Polarity

The establishment and maintenance of cell polarity is important to a wide range of biological processes ranging from chemotaxis to embryogenesis. An essential feature of cell polarity is the asymmetric organization of proteins and lipids in the plasma membrane. In this article, we discuss how polarity regulators such as small GTP-binding proteins and phospholipids spatially and kinetically control vesicular trafficking and membrane organization. Conversely, we discuss how membrane trafficking contributes to cell polarization through delivery of polarity determinants and regulators to the plasma membrane.Cell polarity is essential in most if not all eukaryotes for their development and physiological functions at the tissue and organism level. Although there are significant differences in gross morphology and function among various tissues and organisms, at the cellular level, the establishment and maintenance of cell polarity tend to follow common themes.A basic feature of cell polarity is the asymmetric organization of the plasma membrane (see McCaffrey and Macara 2009; Nelson 2009). This is mostly achieved through membrane trafficking along cytoskeleton tracks under the control of signaling molecules. In general, membrane trafficking occurs through sequential budding, transport, and fusion of vesicles from donor membranes to acceptor membranes (for recent reviews, see Bonifacino and Glick 2004; Cai et al. 2007). During budding, protein complexes interact with phospholipids to induce membrane curvature and generate vesicular carriers that capture different cargos from the donor compartments. After vesicles form, they are delivered to their acceptor compartments, most often along the cytoskeletons. Vesicle fusion at the acceptor membrane is mediated by the assembly of SNARE (soluble N-ethylmaleimide-sensitive fusion protein attachment protein receptors) complexes. Before membrane fusion, proteins or protein complexes tether the vesicles to the acceptor membranes and likely promote SNARE assembly. The Arf and Rab family of small GTPases are localized to different membrane compartments and regulate various stages of membrane trafficking.Polarized distribution of proteins at the plasma membrane often results from a balance of vesicle delivery and fusion with the plasma membrane (“exocytosis”), two-dimensional spread through the plasma membrane (“diffusion”), and internalization and membrane recycling (“endocytosis”). There are two main layers of regulation that control polarized protein transport and incorporation to the plasma membrane. The first involves sorting at the trans-Golgi network (TGN) and endosomal compartments, such as the recycling endosomes. Protein sorting involves recognition of sorting signals in the cargo proteins by the adaptor protein (AP) complexes. There are a number of different AP complexes, and each is localized to different membrane compartments and captures distinct sets of cargo proteins before targeting to their correct destination. Protein sorting before delivery to different domains of the plasma membrane has been best characterized in epithelial cells, which have distinctive basolateral and apical domains separated by junctional complexes. This layer of regulation has been discussed in a recent review (Mellman and Nelson 2008) and is further discussed by Nelson (Nelson 2009), so it will not be discussed further here. The second layer of regulation of membrane protein polarization is through the polarized tethering and docking of vesicles at specific domains of the plasma membrane (Fig. 1). Tethering proteins (i.e., the exocyst) target secretory vesicles to specific domains of the plasma membrane and SNARE assembly eventually drives membrane fusion. Proteins at the plasma membrane can be retrieved back into the cell via endocytosis. These proteins are internalized via clathrin-coated pits, and transported through different endosomal compartments either for degradation in the lysosomes or for recycling back to the plasma membrane. The endosomal compartment that mediates the transport of internalized plasma membrane proteins back to the cell surface is called the “recycling endosome.” Recycling endosomes are major sources of cargo destined to the plasma membrane for exocytosis in many types of cells.Open in a separate windowFigure 1.Membrane trafficking to the plasma membrane. Schematic of the endocytic and exocytic routes involving trans-Golgi network (TGN), endosomal compartments, and the plasma membrane. During exocytosis, cargo leaves the TGN or recycling endosomes in vesicular carriers to the plasma membrane. Once on the membrane, proteins can be internalized and transported to early endosomes, and then either travel through late endosomes to the lysosome to be degraded or return to the plasma membrane through the recycling endosomes. Early endosomes may serve as sorting stations for the next stages of cargo transport.Signaling molecules such as the Rho family of small GTPases spatially and kinetically regulate membrane trafficking during cell polarization (see McCaffrey and Macara 2009; Slaughter et al. 2009). Reversely, vesicular trafficking is required for the polarized deposition and accrual of these regulators. In the first part of this article, we examine the membrane organization and dynamics of cell polarity, focusing on the polarized tethering and docking of vesicles at the plasma membrane. We highlight key components and regulators of polarized exocytosis including the exocyst, small GTPases, and phospholipids. We also use different organisms and systems to show analogous mechanisms during cell polarization. In the second part of this article, we focus on the aforementioned reciprocal effects of cell polarity and membrane trafficking using two representative examples, one from yeast (Cdc42 polarization) and one in mammalian epithelial cells (E-cadherin trafficking).