Membrane Sorting Research Articles

Membrane trafficking in Drosophila wing and eye development.

It is clear that membrane transport is essential to the proper sorting and delivery of membrane bound receptors and ligands, and secreted signaling molecules. Molecular genetic studies in Drosophila are particularly well suited to studies of membrane transport in development. The conservation of cell signaling pathways and membrane transport molecules between Drosophila and other species makes the results obtained in these studies of general interest. In addition, the ability to generate gain- and loss-of-function genetic mutations of various strengths, and the ability to generate transgenic flies that direct protein expression to tissues during development are of particular advantage. Several recent papers suggest that interesting and novel roles for membrane transport processes will be uncovered by studying classically defined membrane transport proteins in developmental contexts. Together these studies suggest that regulation of membrane transport may represent an additional mechanism to regulate the strength of cell-cell signaling during development.

Free‐Flow Electrophoretic Analysis of Endosome Subpopulations of Rat Hepatocytes

Endosomes constitute a functionally, morphologically, and biochemically heterogeneous population of intracellular organelles that play a major role in sorting of incoming ligands, receptors, membrane, and lumenal content. This unit provides protocols for labeling and isolation of endosomes of polarized rat hepatocytes. By application of free-flow zone electrophoresis functional endosomal subcompartments involved in transports to lysosomes and transcytosis are resolved from each other. Methods to analyze the protein composition or acidification properties of these highly purified endosomes are also described.

Biosynthesis and Secretion of Pituitary Hormones: Dynamics and Regulation

Production and secretion of hormones by the pituitary involve highly orchestrated intracellular transport and sorting steps. Hormone precursors are routed through a series of compartments before being packaged in secretory granules. These highly dynamic carriers play crucial roles in both prohormone processing and peptide exocytosis. We have employed the ACTH-secreting AtT-20 cell line to study the membrane sorting events that confer functionality (prohormone activation and regulated exocytosis) to these secretory carriers. The unique ability of granules to promote prohormone processing is attributed to their acidic interior. Using a novel avidin-targeted fluorescence ratio imaging technique, we have found that the trans-Golgi of live AtT-20 cells maintains a mildly acidic (~pH 6.2) interior. Budding of secretory granules causes the lumen to acidify to <pH 6.0, which is both necessary and sufficient to trigger SPC3-mediated proteolytic conversion of proopiomelanocortin to ACTH. Investigation of the pH regulatory mechanism indicates that the trans-Golgi and secretory granules maintain different pH values by distinct sorting of key membrane transporters. Mathematical modeling of our data suggests that the decreasing pH values of organelles of the regulated secretory pathway is established by gradually increasing the density of active H + pumps from the ER to Golgi while concomitantly decreasing the H + permeability from ER to Golgi to secretory granules. An in vitro assay was developed to study the formation of processing-competent secretory granules from their processing-incompetent precursor trans-Golgi compartment. Our data suggest that ARF1-mediated sorting of proton pumps and leaks during early stages of granule formation confers processing competency to the resulting organelle. Once formed, these young granules continue to undergo membrane remodeling which results in dynamic changes in their exocytotic behavior. Two SNAREs, VAMP4 and synaptotagmin IV, enter newly formed granules but are removed from the maturing granule membrane by vesicle budding. Sorting of these proteins is correlated with the acquisition of Ca 2+ -triggered exocytosis and a decrease in unregulated exocytotic rate. Thus, biosynthesis and secretion of pituitary hormones are dynamically regulated by intracellular sorting events that govern the functions of their secretory carriers.

Basolateral membrane expression of the Kir 2.3 channel is coordinated by PDZ interaction with Lin-7/CASK complex.

The basolateral membrane sorting determinant of an inwardly rectifying potassium channel, Kir 2.3, is comprised of a unique arrangement of trafficking motifs containing tandem, conceivably overlapping, biosynthetic targeting and PDZ-based signals. In the present study, we elucidate a mechanism by which a PDZ interaction coordinates one step in a basolateral membrane sorting program. In contrast to apical missorting of channels lacking the entire sorting domain, deletion of the PDZ binding motif caused channels to accumulate into an endosomal compartment. Here, we identify a new human ortholog of a Caenorhabditis elegans PDZ protein, hLin-7b, that interacts with the COOH-terminal tail of Kir 2.3 in renal epithelia. hLin-7b associates with the channel as a part of a multimeric complex on the basolateral membrane similar to a basolateral membrane complex in C. elegans vulva progenitor cells. Coexpression of hLin-7b with Kir 2.3 dramatically increases channel activity by stabilizing plasma membrane expression. The discovery identifies one component of the sorting machinery and provides evidence for a retention mechanism in a hierarchical basolateral trafficking program.

Membrane sorting in the endocytic and phagocytic pathway of Dictyostelium discoideum

To study sorting in the endocytic pathway of a phagocytic and macropinocytic cell, monoclonal antibodies to membrane proteins of Dictyostelium discoideum were generated. Whereas the p25 protein was localized to the cell surface, p80 was mostly present in intracellular endocytic compartments as observed by immunofluorescence as well as immunoelectron microscopy analysis. The p80 gene was identified and encodes a membrane protein presumably involved in copper transport. Expression of chimeric proteins revealed that the cytoplasmic domain of p80 was sufficient to cause constitutive endocytosis and localization of the protein to endocytic compartments. Dileucine- and tyrosine-based endocytic signals described previously in mammalian systems were also capable of targeting chimera to endocytic compartments. In phagocytosing cells no membrane sorting was observed during formation of the phagosome. Both p25 and p80 were incorporated non-selectively in nascent phagosomes, and then retrieved shortly after phagosome closure. Our results emphasize the fact that very active membrane traffic takes place in phagocytic and macropinocytic cells. This is coupled with precise membrane sorting to maintain the specific composition of endocytic compartments.

Targeting of Shiga Toxin B-Subunit to Retrograde Transport Route in Association with Detergent-resistant Membranes

In HeLa cells, Shiga toxin B-subunit is transported from the plasma membrane to the endoplasmic reticulum, via early endosomes and the Golgi apparatus, circumventing the late endocytic pathway. We describe here that in cells derived from human monocytes, i.e., macrophages and dendritic cells, the B-subunit was internalized in a receptor-dependent manner, but retrograde transport to the biosynthetic/secretory pathway did not occur and part of the internalized protein was degraded in lysosomes. These differences correlated with the observation that the B-subunit associated with Triton X-100-resistant membranes in HeLa cells, but not in monocyte-derived cells, suggesting that retrograde targeting to the biosynthetic/secretory pathway required association with specialized microdomains of biological membranes. In agreement with this hypothesis we found that in HeLa cells, the B-subunit resisted extraction by Triton X-100 until its arrival in the target compartments of the retrograde pathway, i.e., the Golgi apparatus and the endoplasmic reticulum. Furthermore, destabilization of Triton X-100-resistant membranes by cholesterol extraction potently inhibited B-subunit transport from early endosomes to the trans-Golgi network, whereas under the same conditions, recycling of transferrin was not affected. Our data thus provide first evidence for a role of lipid asymmetry in membrane sorting at the interface between early endosomes and the trans-Golgi network.

Acute regulation of NHE3 by protein kinase A requires a multiprotein signal complex

Biochemical and cellular experiments in fibroblasts have established the requirement for a member of the PDZ motif Na(+)/H(+) exchanger regulatory factor family of proteins (NHERF and NHERF2) in cAMP-mediated phosphorylation and inhibition of NHE3 activity. NHERF interacts with the actin cytoskeleton through the scaffolding protein ezrin to target a multiprotein signal complex to the plasma membrane. Recent experiments have focused on elements of this model. First, using specific antibodies, NHERF was identified in the renal proximal tubule, where it colocalized with ezrin and NHE3. NHERF2 was seen in glomeruli, the renal vasculature, and collecting duct cells, where it colocalized with ROMK. This distinct nephron localization suggests different physiologic roles for NHERF and NHERF2. Second, the signal-complex model of protein kinase A regulation of NHE3 developed in fibroblasts has been extended to epithelial cells by the development of a dominant-negative opossum kidney cell line expressing an ezrin binding domain-deficient truncation of NHERF. Preliminary studies indicate that these cells have normal basal Na+/H+ exchanger activity but a blunted inhibitory response to cAMP. Third, biochemical, biophysical, and cell experiments have indicated that NHERF binds to itself in a head-to-head configuration, raising the possibility that dimerization may alter the availability of active NHERF. The potential role of the NHERF proteins in the kidney has been expanded by recent studies indicating their involvement in the membrane targeting, trafficking, sorting, and regulation of a range of other transporters, receptors, and signaling proteins. NHERF and related PDZ-containing proteins may serve as adapters for regulation of renal transporters.

Cell-specific basolateral membrane sorting of the human liver Na(+)-dependent bile acid cotransporter.

The human Na(+)-taurocholate cotransporting polypeptide (Ntcp) is located exclusively on the basolateral membrane of hepatocyte, but the mechanisms underlying its membrane sorting domain have not been fully elucidated. In the present study, a green fluorescent protein-fused human NTCP (NTCP-GFP) was constructed using the polymerase chain reaction and was stably transfected into Madin-Darby canine kidney (MDCK) and Caco-2 cells. Taurocholate uptake studies and confocal microscopy demonstrated that the polarity of basolateral surface expression of NTCP-GFP was maintained in MDCK cells but was lost in Caco-2 cells. Nocodazole (33 microM), an agent that causes microtubular depolymerization, partially disrupted the basolateral localization of NTCP-GFP by increasing apical surface expression to 33.5% compared with untreated cells (P < 0.05). Brefeldin A (BFA; 1-2 microM) disrupted the polarized basolateral localization of NTCP, but monensin (1.4 microM) had no affect on NTCP-GFP localization. In addition, low-temperature shift (20 degrees C) did not affect the polarized basolateral surface sorting of NTCP-GFP and repolarization of this protein after BFA interruption. In summary, these data suggest that the polarized basolateral localization of human NTCP is cell specific and is mediated by a novel sorting pathway that is BFA sensitive and monensin and low-temperature shift insensitive. The process may also involve microtubule motors.

Membrane traffic in myelinating oligodendrocytes

In the central nervous system (CNS), the myelin sheath is synthesised by oligodendrocytes as a specialised subdomain of an extended plasma membrane, reminiscent of the segregated membrane domains of polarised cells. Myelination takes place within a relatively short period of time and oligodendrocytes must have adapted membrane sorting and transport mechanisms to achieve such a high rate of myelin synthesis and to maintain the unique organisation of the myelin membrane. In adult life, maintenance of the functional myelin sheath requires a carefully orchestrated balance of myelin synthesis and turnover. Imbalance in these processes may cause dys- or demyelination and disease. This review summarises what is currently known about myelin protein trafficking and mistrafficking in oligodendrocytes. We also present data demonstrating distinct transport pathways for myelin structural proteins and the expression of SNARE proteins in differentiating oligodendrocytes. Myelinating glial cells may well serve as a model system for studying general aspects of membrane trafficking and organisation of membrane domains.

The Dynamin-dependent, Arrestin-independent Internalization of 5-Hydroxytryptamine 2A (5-HT2A) Serotonin Receptors Reveals Differential Sorting of Arrestins and 5-HT2A Receptors during Endocytosis

5-Hydroxytryptamine 2A (5-HT2A) receptors, a major site of action of clozapine and other atypical antipsychotic medications, are, paradoxically, internalized in vitro and in vivo by antagonists and agonists. The mechanisms responsible for this paradoxical regulation of 5-HT2A receptors are unknown. In this study, the arrestin and dynamin dependences of agonist- and antagonist-mediated internalization were investigated in live cells using green fluorescent protein (GFP)-tagged 5-HT2A receptors (SR2-GFP). Preliminary experiments indicated that GFP tagging of 5-HT2A receptors had no effect on either the binding affinities of several ligands or agonist efficacy. Likewise, both the native receptor and SR2-GFP were internalized via endosomes in vitro. Experiments with a dynamin dominant-negative mutant (dynamin K44A) demonstrated that both agonist- and antagonist-induced internalization were dynamin-dependent. By contrast, both the agonist- and antagonist-induced internalization of SR2-GFP were insensitive to three different arrestin (Arr) dominant-negative mutants (Arr-2 V53D, Arr-2-(319-418), and Arr-3-(284-409)). Interestingly, 5-HT2A receptor activation by agonists, but not antagonists, induced greater Arr-3 than Arr-2 translocation to the plasma membrane. Importantly, the agonist-induced internalization of 5-HT2A receptors was accompanied by differential sorting of Arr-2, Arr-3, and 5-HT2A receptors into distinct plasma membrane and intracellular compartments. The agonist-induced redistribution of Arr-2 and Arr-3 into intracellular vesicles and plasma membrane compartments distinct from those involved in 5-HT2A receptor internalization implies novel roles for Arr-2 and Arr-3 independent of 5-HT2A receptor internalization and desensitization.

A myosin I is involved in membrane recycling from early endosomes.

Geometry-based mechanisms have been proposed to account for the sorting of membranes and fluid phase in the endocytic pathway, yet little is known about the involvement of the actin-myosin cytoskeleton. Here, we demonstrate that Dictyostelium discoideum myosin IB functions in the recycling of plasma membrane components from endosomes back to the cell surface. Cells lacking MyoB (myoA(-)/B(-), and myoB(-) cells) and wild-type cells treated with the myosin inhibitor butanedione monoxime accumulated a plasma membrane marker and biotinylated surface proteins on intracellular endocytic vacuoles. An assay based on reversible biotinylation of plasma membrane proteins demonstrated that recycling of membrane components is severely impaired in myoA/B null cells. In addition, MyoB was specifically found on magnetically purified early pinosomes. Using a rapid-freezing cryoelectron microscopy method, we observed an increased number of small vesicles tethered to relatively early endocytic vacuoles in myoA(-)/B(-) cells, but not to later endosomes and lysosomes. This accumulation of vesicles suggests that the defects in membrane recycling result from a disordered morphology of the sorting compartment.

Signal complex regulation of renal transport proteins: NHERF and regulation of NHE3 by PKA.

The activity of the sodium/hydrogen exchanger 3 (NHE3) isoform of the sodium/hydrogen exchanger in the brush-border membrane of the renal proximal tubule is tightly regulated. Recent biochemical and cellular experiments have established the essential requirement for a new class of regulatory factors, sodium/hydrogen exchanger regulatory factor (NHERF) and NHERF-like proteins, in cAMP-mediated inhibition of NHE3 activity. NHERF is the first PSD-95/Dlg/ZO-1 (PDZ) motif-containing protein localized to apical membranes and appears to facilitate cAMP-dependent protein kinase A (PKA) phosphorylation of NHE3 by interacting with the cytoskeleton to target a multiprotein complex to the brush-border membrane. Other recent experiments have indicated that NHERF also regulates the activity of other renal transport proteins, suggesting that the signal complex model of signal transduction in the kidney may be more common than presently appreciated. This article reviews studies on the regulation of NHE3 by NHERF, PKA, and ezrin and introduces the concept of regulation of renal transporters by signal complexes. Although not the primary focus of this review, recent studies have indicated a role for NHERF in membrane targeting, trafficking, and sorting of transporters, receptors, and signaling proteins. Thus NHERF and related PDZ-containing proteins appear to be essential adapters for regulation of renal transporters in the mammalian kidney that maintain salt and water balance.

Cell cycle maintenance and biogenesis of the Golgi complex.

How organelle identity is established and maintained, and how organelles divide and partition between daughter cells, are central questions of organelle biology. For the membrane-bound organelles of the secretory and endocytic pathways [including the endoplasmic reticulum (ER), Golgi complex, lysosomes, and endosomes], answering these questions has proved difficult because these organelles undergo continuous exchange of material. As a result, many "resident" proteins are not localized to a single site, organelle boundaries overlap, and when interorganellar membrane flow is interrupted, organelle structure is altered. The existence and identity of these organelles, therefore, appears to be a product of the dynamic processes of membrane trafficking and sorting. This is particularly true for the Golgi complex, which resides and functions at the crossroads of the secretory pathway. The Golgi receives newly synthesized proteins from the ER, covalently modifies them, and then distributes them to various final destinations within the cell. In addition, the Golgi recycles selected components back to the ER. These activities result from the Golgi's distinctive membranes, which are organized as polarized stacks (cis to trans) of flattened cisternae surrounded by tubules and vesicles. Golgi membranes are highly dynamic despite their characteristic organization and morphology, undergoing rapid disassembly and reassembly during mitosis and in response to perturbations in membrane trafficking pathways. How Golgi membranes fragment and disperse under these conditions is only beginning to be clarified, but is central to understanding the mechanism(s) underlying Golgi identity and biogenesis. Recent work, discussed in this review, suggests that membrane recycling pathways operating between the Golgi and ER play an indispensable role in Golgi maintenance and biogenesis, with the Golgi dispersing and reforming through the intermediary of the ER both in mitosis and in interphase when membrane cycling pathways are disrupted.

Sorting of Membrane and Fluid at the Apical Pole of Polarized Madin-Darby Canine Kidney Cells

When fluid-phase markers are internalized from opposite poles of polarized Madin-Darby canine kidney cells, they accumulate in distinct apical and basolateral early endosomes before meeting in late endosomes. Recent evidence suggests that significant mixing of apically and basolaterally internalized membrane proteins occurs in specialized apical endosomal compartments, including the common recycling endosome and the apical recycling endosome (ARE). The relationship between these latter compartments and the fluid-labeled apical early endosome is unknown at present. We report that when the apical recycling marker, membrane-bound immunoglobulin A (a ligand for the polymeric immunoglobulin receptor), and fluid-phase dextran are cointernalized from the apical poles of Madin-Darby canine kidney cells, they enter a shared apical early endosome (</=2.5 min at 37 degrees C) and are then rapidly segregated from one another. The dextran remains in the large supranuclear EEA1-positive early endosomes while recycling polymeric immunoglobulin receptor-bound immunoglobulin A is delivered to a Rab11-positive subapical recycling compartment. This latter step requires an intact microtubule cytoskeleton. Receptor-bound transferrin, a marker of the basolateral recycling pathway, has limited access to the fluid-rich apical early endosome but is excluded from the subapical elements of the Rab11-positive recycling compartment. We propose that the term ARE be used to describe the subapical Rab11-positive compartment and that the ARE is distinct from both the transferrin-rich common recycling endosome and the fluid-rich apical early endosome.

Definition of distinct compartments in polarized Madin-Darby canine kidney (MDCK) cells for membrane-volume sorting, polarized sorting and apical recycling.

Previous studies of fibroblasts have demonstrated that recycling of endocytic receptors occurs through a default mechanism of membrane-volume sorting. Epithelial cells require an additional level of polar membrane sorting, but there are conflicting models of polar sorting, some suggesting that it occurs in early endosomes, others suggesting it occurs in a specialized apical recycling endosome (ARE). The relationship between endocytic sorting to the lysosomal, recycling and transcytotic pathways in polarized cells was addressed by characterizing the endocytic itineraries of LDL, transferrin (Tf) and IgA, respectively, in polarized Madin-Darby canine kidney (MDCK) cells. Quantitative analyses of 3-dimensional images of living and fixed polarized cells demonstrate that endocytic sorting occurs sequentially. Initially internalized into lateral sorting endosomes, Tf and IgA are jointly sorted from LDL into apical and medical recycling endosomes, in a manner consistent with default sorting of membrane from volume. While Tf is recycled to the basolateral membrane from recycling endosomes, IgA is sorted to the ARE prior to apical delivery. Quantifications of the efficiency of sorting of IgA from Tf between the recycling endosomes and the ARE match biochemical measurements of transepithelial protein transport, indicating that all polar sorting occurs in this step. Unlike fibroblasts, rab11 is not associated with Tf recycling compartments in either polarized or glass-grown MDCK cells, rather it is associated with the compartments to which IgA is directed after sorting from Tf. These results complicate a suggested homology between the ARE and the fibroblast perinuclear recycling compartment and provide a framework that justifies previous conflicting models of polarized sorting.

Membrane trafficking and processing in Paramecium

Cellular membranes are made in a cell's biosynthetic pathway and are composed of similar biochemical constituents. Nevertheless, they become differentiated as membrane components are sorted into different membrane-limited compartments. We summarize the morphological and immunological similarities and differences seen in the membranes of the various interacting compartments in the single-celled organism, Paramecium. Besides the biosynthetic pathway, membranes of the regulated secretory pathway, endocytic pathway, and phagocytic pathway are highlighted. Paramecium is a multipolarized cell in the sense that several different pools of membrane-limited compartments are targeted for exocytosis at very specific sites at the cell surface. Thus, the method used by this cell to sort and package its membrane subunits into different compartments, the processes used to transport these compartments to specific locations at the plasma membrane and to other intracellular fusion sites, the processes of membrane retrieval, and the processes of membrane docking and fusion are reviewed. Paramecium has provided an excellent model for studying the complexities of membrane trafficking in one cell using both morphological and immunocytochemical techniques. This cell also promises to be a useful model for studying aspects of the molecular biology of membrane sorting, retrieval, transport, and fusion.

Utilization of the indirect lysosome targeting pathway by lysosome-associated membrane proteins (LAMPs) is influenced largely by the C-terminal residue of their GYXXphi targeting signals.

A systematic study was conducted on the requirements at the C-terminal position for the targeting of LAMPs to lysosomes, examining the hypothesis that a bulky hydrophobic residue is required. Mutations deleting or replacing the C-terminal valine with G, A, C, L, I, M, K, F, Y, or W were constructed in a reporter protein consisting of the lumenal/extracellular domain of avian LAMP-1 fused to the transmembrane and cytoplasmic domains of LAMP-2b. The steady-state distribution of each mutant form in mouse L-cells was assessed by quantitative antibody binding assays and immunofluorescence microscopy; efficiency of internalization from the plasma membrane and delivery to the lysosome were also estimated. It is found that (a) only C-terminal V, L, I, M, and F mediated efficient targeting to lysosomes, demonstrating the importance hydrophobicity and an optimal size of the C-terminal residue in targeting; (b) efficiency of lysosomal targeting generally correlated with efficiency of internalization; and (c) mutant forms that did not target well to lysosomes showed unique distributions in cells rather than simply default accumulation in the plasma membrane. Interactions of the targeting signals with adaptor subunits were measured using a yeast two-hybrid assay. The results are consistent with the hypothesis that trafficking of LAMP forms in cells through the indirect pathway is determined by the affinities of their targeting signals, predominantly for the mu2 and mu3 adaptors involved at plasma membrane and endosomal cellular sorting sites, respectively.

A periplasmic location is essential for the role of the ApbE lipoprotein in thiamine synthesis in Salmonella typhimurium.

ApbE is a lipoprotein in Salmonella typhimurium, and mutants unable to make this protein have a reduced ability to make thiamine (vitamin B(1)) and require it as a supplement for optimal growth in minimal glucose medium. Polyclonal antibodies specific to ApbE were used to determine that wild-type ApbE is located exclusively in the inner membrane. The periplasmic, monotopic topology of ApbE was determined by using computer-based hydrophobicity plots, LacZ and PhoA gene fusions, and proteinase protection experiments. This extracellular location of ApbE is required for its function, since a cytoplasmic form (ApbE(cyto)) did not allow an apbE mutant to grow in the absence of thiamine. A periplasmic form of ApbE (ApbE(peri)) lacking the lipoprotein modification allowed an apbE mutant to grow in the absence of thiamine, indicating that soluble ApbE could function in thiamine synthesis and that lipoation and membrane association were not required. Alteration of the amino acid implicated in membrane sorting for other lipoproteins did not result in a relocalization of ApbE to the outer membrane, suggesting that additional sorting determinants exist for ApbE.

Interactions between lipid-anchored and transmembrane proteins. Spin-label ESR studies on avidin-biotinyl phosphatidylethanolamine in membrane recombinants with myelin proteolipid proteins.

Interactions between lipid-anchored and transmembrane proteins are relevant to the intracellular membrane sorting of glycosyl phosphatidylinositol-linked proteins. We have studied the interaction of a spin-labeled biotinyl diacyl phospholipid, with and without specifically bound avidin, with the myelin proteolipid protein (or the DM-20 isoform) reconstituted in dimyristoylphosphatidylcholine. Tetrameric avidin bound to the N-biotinyl lipid headgroup is a surface-anchored protein, and the myelin proteolipid is an integral protein containing four transmembrane helices. The electron spin resonance (ESR) spectrum of N-biotinyl phosphatidylethanolamine spin-labeled at the C-14 position of the sn-2 chain consists of two components in fluid-phase membranes of dimyristoylphosphatidylcholine containing the proteolipid. In the absence of avidin, this is characteristic of lipid-protein interactions with integral transmembrane proteins. The more motionally restricted component represents the lipid population in direct contact with the intramembranous surface of the integral protein, and the more mobile component corresponds to the bulk fluid lipid environment of the bilayer. In the presence of avidin, the biotin-lipid chains have reduced mobility because of the binding to avidin, even in the absence of the proteolipid [Swamy, M. J., and Marsh, D. (1997) Biochemistry 36, 7403-7407]. In the presence of the proteolipid, the major fraction of the avidin-anchored chains is further restricted in its mobility by interaction with the transmembrane protein. At a biotin-lipid concentration of 1 mol %, approximately 80% of the avidin-linked chains are restricted in membranes with a phosphatidylcholine:proteolipid molar ratio of 37:1. This relatively high stoichiometry of interaction can be explained when allowance is made for the closest interaction distance between the lipid-anchored avidin tetramer and the transmembrane proteolipid hexamer, without any specific interaction between the two types of membrane-associated proteins. The interaction is essentially one of steric exclusion, but the lipid chains are rendered more sensitive to interaction with the integral protein by being linked to avidin, even though they are removed from the immediate intramembrane protein-lipid interface. This could have implications for the tendency of lipid-anchored chains to associate with membrane domains with reduced lipid mobility.

Molecular Mechanisms of Membrane Trafficking. What do we Learn from Dictyostelium discoideum?

Thanks to increasing interest, understanding of the molecular mechanisms underlying intracellular membrane transport is truly emerging. An even more rapid advance is expected since the recognition that efforts to unravel both membrane traffic and cytoskeleton need to be concerted. The two main membrane traffic pathways are the biosynthetic/ secretory route, where transport occurs from the ER via the Golgi apparatus to the plasma membrane and the endocytic route involving the flow from the plasma membrane to the degradative compartment. These two pathways intersect at many compartments, both comprise multiple transport steps and both involve efficient sorting of membrane and soluble proteins. Here, we review recent studies on the dissection of endocytic trafficking in Dictyostelium discoideum and integrate the information in the light of knowledge acquired from other systems.