Lipids in endocytic membrane transport and sorting

Protein complexes associated to specific membrane lipids and protein-lipid domains contribute to regulate protein sorting and membrane dynamics in the endocytic pathway. It is also becoming apparent that different lipid territories are distributed along the pathway, and that some lipids segregate into specialised microdomains.     

Glycosphingolipids in membrane architecture

As part of a program to investigate the behavior and interactions of glycolipids in biological membranes we have synthesized spin-labeled derivatives of 2 families of carbohydrate-bearing ceramides (glycosphingolipids): simple neutral glycolipids and gangliosides. Galactosyl ceramide has been synthesized with the spin label at 3 different positions on the fatty acid chain. It has been studied in bilayers of various different lipids and lipid mixtures and compared to the corresponding phospholipid spin labels. Considerable similarity has been found between the behavior of galactosyl ceramide and phosphatidylcholine. These similarities include a negligible flip-flop rate, a flexibility gradient in the acyl chains, and exclusion from phosphatidylserine domains in the face of a Ca²⁺-induced lateral phase separation. Evidence for dramatic clustering of simple neutral glycolipids has not been found. Glycosphingolipids do seem to have the capacity to increase rigidity in fluid lipid bilayers. A general procedure has been developed for covalent attachment of a nitroxide spin label to the headgroup region of complex glycolipids such as gangliosides. Studies of beef brain gangliosides labeled in this manner and incorporated into bilayers of phosphatidylcholine indicate that the headgroup oligosaccharides are in rapid, random motion as opposed to being in any way immobilized. This headgroup mobility depends very little on the fluidity or rigidity of the bilayer. However, headgroup mobility decreases, perhaps as a result of cooperative headgroup interactions, with increasing bilayer concentration of unlabeled ganglioside.     

Caveolin-stabilized membrane domains as multifunctional transport and sorting devices in endocytic membrane traffic

Endocytosis comprises several routes of internalization. An outstanding question is whether the caveolar and endosomal pathways intersect. Following transport of the caveolar protein Caveolin-1 and two cargo complexes, Simian Virus 40 and Cholera toxin, in live cells, we uncovered a Rab5-dependent pathway in which caveolar vesicles are targeted to early endosomes and form distinct and stable membrane domains. In endosomes, the low pH selectively allowed the toxin to diffuse out of the caveolar domains into the surrounding membrane, while the virus remained trapped. Thus, we conclude that, unlike cyclic assembly and disassembly of coat proteins in vesicular transport, oligomeric complexes of caveolin-1 confer permanent structural stability to caveolar vesicles that transiently interact with endosomes to form subdomains and release cargo selectively by compartment-specific cues.     

Regulation of membrane transport through the endocytic pathway by rabGTPases.

Small GTP binding proteins of the rab family are associated with the cytoplasmic surface of compartments of the central vacuolar system. Several of them, including rab5, rab4 and rab11, are localized to early endocytic organelles where they regulate distinct events in the transferrin receptor pathway. Whereas rab5 is controlling transport to early endosomes, rab4 and rab11 are involved in the regulation of recycling back to the plasma membrane. How GTP-hydrolysis of rab bound GTP is related to the role of these proteins in endocytosis is not yet known, but quick progress is being made towards this goal through the identification of proteins regulating the activity of these rab proteins.     

Spatiotemporal dynamics of membrane remodeling and fusion proteins during endocytic transport

Organelles of the endolysosomal system undergo multiple fission and fusion events to combine sorting of selected proteins to the vacuole with endosomal recycling. This sorting requires a consecutive remodeling of the organelle surface in the course of endosomal maturation. Here we dissect the remodeling and fusion machinery on endosomes during the process of endocytosis. We traced selected GFP-tagged endosomal proteins relative to exogenously added fluorescently labeled α-factor on its way from the plasma membrane to the vacuole. Our data reveal that the machinery of endosomal fusion and ESCRT proteins has similar temporal localization on endosomes, whereas they precede the retromer cargo recognition complex. Neither deletion of retromer nor the fusion machinery with the vacuole affects this maturation process, although the kinetics seems to be delayed due to ESCRT deletion. Of importance, in strains lacking the active Rab7-like Ypt7 or the vacuolar SNARE fusion machinery, α-factor still proceeds to late endosomes with the same kinetics. This indicates that endosomal maturation is mainly controlled by the early endosomal fusion and remodeling machinery but not the downstream Rab Ypt7 or the SNARE machinery. Our data thus provide important further understanding of endosomal biogenesis in the context of cargo sorting.     

Hypertonic sucrose inhibition of endocytic transport suggests multiple early endocytic compartments

Incubation of animal cells with hypertonic sucrose and polyethylene glycol (PEG) 1,000 renders endosomes sensitive in situ to hypotonic shock (Okada and Rechsteiner, 1982). We found that: 1) in vitro endosomes were osmotically insensitive; and 2) hypertonic sucrose inhibited transport from very early endosomes to lysosomes. Endocytic vesicles were labeled by incubating Chinese hamster ovary (CHO) cells for 1-10 min at 37 degrees C with horseradish peroxidase (HRP) and/or fluorescein isothiocyanate-conjugated dextran (FITC-dextran). Cell fractions prepared in 0.25 M sucrose were hypotonically shocked by dilution with 5 mM Na phosphate buffer, pH 6.7, to a final sucrose concentration of 0.05 M. After hypotonic shock, endocytized HRP and FITC-dextran pelleted with membrane while lysosomal hydrolases did not. The HRP activity in the pellet was latent, suggesting that endosomes were resistant to osmotic shock. Uptake in the presence of hypertonic sucrose had little effect on the subsequent osmotic sensitivity of the endosomes. Uptake in the presence of hypertonic sucrose and PEG 1,000 rendered endosomes fragile to cell homogenization. Unexpectedly, the inclusion of hypertonic sucrose in the uptake and chase media inhibited the appearance of HRP in lysosomes. HRP internalized during a 10-min uptake appeared as if it were present in two physically distinct compartments, one accessible to transport inhibition by exogenous sucrose ("very early" endosomes) and the other not ("early" endosomes). After a brief uptake (1-3 min), postincubation of CHO cells in 0.25 M sucrose-containing media completely blocked transport of internalized HRP to lysosomes. This blockage could be partially relieved by cointernalization of invertase with HRP. These results suggest that transport between multiple early endosome populations is sensitive to intraorganellar osmotic conditions.     

Cdc42 controls secretory and endocytic transport to the basolateral plasma membrane of MDCK cells

Cdc42 is a Rho-family GTPase that in yeast is important in establishing polarized bud growth. Here we show that Cdc42 is also essential in establishing and maintaining polarity in epithelial cells. Functional deletion of Cdc42 in Madin-Darby canine kidney (MDCK) cells results in the selective depolarization of basolateral membrane proteins; the polarity of apical proteins remains unaffected. This phenotype does not reflect major alterations in the actin cytoskeleton, but rather results from the selective inhibition of membrane traffic to the basolateral plasma membrane in both the endocytic and the secretory pathways. Thus, Cdc42 plays a critical part in epithelial-cell polarity, by, unexpectedly, regulating the fidelity of membrane transport.     

Role of membrane organization and membrane domains in endocytic lipid trafficking

Lipid compositions vary greatly among organelles, and specific sorting mechanisms are required to establish and maintain these distinct compositions. In this review, we discuss how the biophysical properties of the membrane bilayer and the chemistry of individual lipid molecules play a role in the intracellular trafficking of the lipids themselves, as well as influencing the trafficking of transmembrane proteins. The large diversity of lipid head groups and acyl chains lead to a variety of weak interactions, such as ionic and hydrogen bonding at the lipid/water interfacial region, hydrophobic interactions, and van-der-Waals interactions based on packing density. In simple model bilayers, these weak interactions can lead to large-scale phase separations, but in more complex mixtures, which mimic cell membranes, such phase separations are not observed. Nevertheless, there is growing evidence that domains (i.e., localized regions with non-random lipid compositions) exist in biological membranes, and it is likely that the formation of these domains are based on interactions similar to those that lead to phase separations in model systems. Sorting of lipids appears to be based in part on the inclusion or exclusion of certain types of lipids in vesicles or tubules as they bud from membrane organelles.     

Disruption of endocytic transport by transthyretin aggregates

The cytotoxicity of amyloidogenic proteins such as transthyretin (TTR) has implications for neurodegeneration and other pathologies, but is not well understood. In the current study, potential effects of misfolded, aggregated TTRs (agTTR) upon a major cell membrane function—endocytosis—were assessed. Internalization of transferrin (Tf), a ligand whose receptor-mediated endocytosis is well characterized, was analyzed in different cell types after treatment with agTTR. The results indicate disruption of Tf endocytosis: 20–25% inhibition by agTTR relative to the same concentrations of normal soluble TTR, or relative to another control protein, albumin (p < 0.05 for agTTR relative to controls). No statistically significant difference was observed for cell surface Tf binding between agTTR-treated and control cells. This is the first evidence for endocytic disruption by agTTR, and presents a novel cytotoxicity mechanism that may account for previously reported inhibitory effects of amyloidogenic TTR on neuronal growth.     

The ins and outs of endocytic transport

A fusion of cutting-edge research in cell biology, developmental biology and immunology made the recent workshop on Membrane Dynamics in Endocytosis an outstanding success. Members of an increasingly diverse community converged upon the small town of Sant Feliu de Guixols on the coast of Spain, between September 17-22, 2005, to discuss common themes emerging from their studies on membrane transport. Organized by Margaret Robinson (Cambridge, UK) and Howard Riezman (Geneva, Switzerland), the meeting covered diverse topics that highlighted essential roles for endocytosis during cell growth, development and parasitic invasion.     

Biogenesis of transport intermediates in the endocytic pathway.

Evidence is accumulating that membrane traffic between organelles can be achieved by different types of intermediates. Small (< 100 nm) and short-lived vesicles mediate transport from the plasma membrane or the trans-Golgi network to endosomes, and formation of these vesicles depends on specific adapter complexes. In contrast, transport from early to late endosomes is achieved by relatively large (approximately 0.5 microm), long-lived and multivesicular intermediates, and their biogenesis depends on endosomal COP-I proteins. Here, we review recent work on the formation of these different transport intermediates, and we discuss, in particular, coat proteins, sorting signals contained in cargo molecules and the emerging role of lipid in vesicle biogenesis.     

Evidence for two endocytic transport pathways in plant cells

Intracellular trafficking of endocytic vesicles in eukaryotes varies with the nature of the cargo molecules and the targeted organelle, and proceeds through an intricate network of internal endosomal compartments. However, the path for fluid-phase endocytosis (FPE), the internalization of external solutes from the apoplast via plasmalemma generated vesicles, remains unresolved despite some indication of a direct transport route to the vacuole. To test this hypothesis, we made use of the membrane-impermeable Na-dependent fluorescent marker Coro-Na in combination with the fluorescent membrane marker FM 4-64 and confocal laser scanning microscopy. When protoplasts from sweet lime juice cells were incubated in Na-free solution, FM 4-64, Coro-Na, and 200 mM sucrose, two distinct types of labeled vesicles were evident. A set of vesicles (1 μm in diameter) was intensely labeled with Coro-Na and to a lesser extent with FM 4-64, whereas the second type of 1–7 μm structures appeared exclusively labeled with FM 4-64. These data demonstrate the parallel functioning of two endocytic pathways in plant cells. In one system, a set of small endocytic vesicles merge with the endosome, whereas a separate set of vesicles fuse to form larger vesicles independent from the endosome. Although it is likely that both vesicle systems eventually contribute to solutes reaching the vacuole, given their size (1–7 μm), and based on previous observations of endocytic vesicle formation protruding from the plasmalemma and merging with the vacuole, we conclude that these latter vesicles constitute the primary FPE vesicle system.     

EHD proteins: key conductors of endocytic transport

Regulation of endocytic transport is controlled by an elaborate network of proteins. Rab GTP-binding proteins and their effectors have well-defined roles in mediating specific endocytic transport steps, but until recently less was known about the four mammalian dynamin-like C-terminal Eps15 homology domain (EHD) proteins that also regulate endocytic events. In recent years, however, great strides have been made in understanding the structure and function of these unique proteins. Indeed, a growing body of literature addresses EHD protein structure, interactions with binding partners, functions in mammalian cells, and the generation of various new model systems. Accordingly, this is now an opportune time to pause and review the function and mechanisms of action of EHD proteins, and to highlight some of the challenges and future directions for the field.     

Morphological localization of a major lysosomal membrane glycoprotein in the endocytic membrane system

We have raised specific polyclonal immunoglobulin G (IgG) against a major lysosomal membrane sialoglycoprotein (LGP107) taken from rat liver and have prepared a conjugate of its Fab' fragment with horseradish peroxidase (HRP-anti LGP107 Fab') as a probe for the subcellular antigen. Electron immunocytochemistry in primary cultured rat hepatocytes showed that LGP107 resided primarily within lysosomes and was associated with luminal amorphous materials as well as limiting membranes. In addition, LGP107 was shown to be substantially distributed throughout the endocytic vacuolar system. The glycoprotein was found clustered in coated pits at the cell surface and localized along the surrounding membranes in endocytic vesicles. When cultured cells were exposed to HRP-anti LGP107 Fab', the antibody which was bound to its antigen within the coated pits was internalized via a system of endocytic vesicles and transported to lysosomes. During 20 min of incubation at 37 degrees C, the HRP tracer appeared at an early stage in small vesicles and moved progressively to larger vesicles, including multivesicular bodies. After 1 h, the tracer could be clearly seen in lysosomes heterogeneous in shape and size. The existence of LGP107 in endocytic compartments and the uptake of anti LGP107 antibody by hepatocytes were not blocked by prior treatment of the cells with cycloheximide and excess amounts of anti LGP107 IgG. These data suggest that LGP107 circulates between the cell surface and lysosomes through the endocytic membrane traffic in hepatocytes.     

Hrs and endocytic sorting of ubiquitinated membrane proteins

Endocytosed receptors are either recycled to the plasma membrane or trapped within intralumenal vesicles of multi-vesicular bodies for subsequent degradation in lysosomes. How the cell is able to sort receptors in endosomes has so far been largely unknown. The hepatocyte growth factor regulated tyrosine kinase substrate, Hrs, is an essential protein that has been implicated in cell signalling and intracellular membrane trafficking. Very recently, several reports have demonstrated a role for Hrs in endocytic sorting of ubiquitinated membrane proteins. Here, we review current knowledge about how Hrs recognises ubiquitinated cargo that is destined for lysosomal degradation, and how Hrs may act as a key regulator of the molecular machinery involved in receptor sorting and multivesicular body formation.     

Glucosylceramide modulates membrane traffic along the endocytic pathway

Glycosphingolipids are endocytosed and targeted to the Golgi apparatus, but are mistargeted to lysosomes in numerous sphingolipidoses. Substrate reduction therapy utilizes imino sugars to inhibit glucosylceramide synthase and potentially abrogate the effects of storage. Gaucher disease is a hereditary deficiency in glucocerebrosidase leading to glucosylceramide accumulation; however, Gaucher fibroblasts exhibited normal Golgi transport of lactosylceramide. To better understand the effects of glycosphingolipid accumulation on intracellular trafficking and the use of imino sugar inhibitors, we studied sphingolipid endocytosis in fibroblast and macrophage models for Gaucher disease. Treatment of fibroblasts or RAW macrophages with conduritol B epoxide, an inhibitor of lysosomal glucocerebrosidase, resulted in a change in the endocytic targeting of lactosylceramide from the Golgi to the lysosomes. Co-treatment of macrophages with conduritol B-epoxide and 12-25 microM N-butyldeoxygalactonojirimycin, an inhibitor of glycosphingolipid biosynthesis, prevented the mistargeting of lactosylceramide to the lysosomes and restored trafficking to the Golgi. Surprisingly, higher doses (>25 microM) of NB-DGJ induced targeting of lactosylceramide to the lysosomes, even in the absence of conduritol B-epoxide. These data demonstrate that both increases and decreases in glucosylceramide levels can dramatically alter the endocytic targeting of lactosylceramide and suggest a role for glucosylceramide in regulation of membrane transport.