Association of annexin 2 with recycling endosomes requires either calcium- or cholesterol-stabilized membrane domains

Annexin 2 is a Ca2+- and phospholipid-binding protein previously identified on endosomal membranes and the plasma membrane. Inferred from this location and its stimulatory effect on membrane transport annexin 2 has been proposed to play a role in the structural organization and dynamics of endosomal membranes. Validation of this view requires a detailed analysis of the distribution of annexin 2 over the endosomal compartment and a characterization of the parameters governing this distribution. Towards this end we have devised an immunoisolation protocol to purify annexin 2-positive membrane vesicles from subcellular fractions of BHK cells containing early endosomes. We show that this approach leads to the isolation of intact endosomal vesicles containing internalized fluid-phase marker and that the immunoisolated membranes are positive for the transferrin receptor and Rab4 but not for the early endosomal antigen EEA1. A distinct and non-uniform distribution of annexin 2 over the early endosomal compartment is also observed in immunoelectron microscopy analyses of whole-mount specimens of BHK cells. Annexin 2 antibodies labeled transferrin receptor-containing tubular early endosomal structures, but not EEAl-positive endosomal vacuoles. We also observed that the Ca2+-independent association of annexin 2 with endosomal membranes was disrupted by the cholesterol-binding glycerid saponin, while Ca2+ could trigger annexin 2 binding to saponin-treated endosomal membranes. Thus, either Ca2+- or cholesterol-stabilized membrane domains are required for the binding of annexin 2 to endosomes suggesting that both factors may regulate this interaction.     

The subcellular distribution of early endosomes is affected by the annexin II2p11(2) complex

The tyrosine kinase substrate annexin II is a member of a multigene family of Ca2+ and lipid-binding proteins which have been implicated in a number of membrane-related events. We have analyzed the subcellular distribution of annexin II in relation to other cellular components in normal and specifically manipulated MDCK cells. In a polarized monolayer of MDCK cells annexin II and its cellular ligand p11 are restricted almost exclusively to the cortical regions of the cells which also contain peripheral early endosomes. Treatment of the polarized cells with low Ca2+ medium leads to a disintegration of the cortical cytoskeleton and a translocation of both, the annexin II2p11(2) complex and early endosomes, to the cytoplasm. A similar translocation which is however specific for the annexin II2p11(2) complex and early endosomes and does not affect other elements of the cell cortex is observed in cells expressing a trans-dominant annexin II- p11 mutant. This chimeric mutant protein causes the aggregation of endogenous annexin II and p11 and the simultaneous detachment of early endosomes from the cell periphery resulting in the binding of the early endosomes but no other components of the endocytotic or biosynthetic pathways to the annexin II/p11 aggregates. The specificity of this effect argues for the association of the annexin II2p11(2) complex with early endosomes and suggests that this association contributes to establish the peripheral localization of early endosomal structures.     

Sequential processing of epidermal growth factor in early and late endosomes of rat liver.

We have used isolated perfused rat livers to examine the intracellular processing of 125I-epidermal growth factor (EGF) and to determine where in the endocytic pathway the hydrolases which degrade EGF are acting. Following uptake of 125I-EGF at 37 or 16 degrees C, subcellular fractions enriched in endosomes and lysosomes were isolated, and their 125I-EGF content was examined by reverse-phase high performance liquid chromatography. Three forms of EGF processed at their carboxyl termini are generated in endosomes. At 37 degrees C, EGF is first processed in early endosomes by a carboxypeptidase B-like protease and is further processed in late endosomes by a trypsin-like protease and then a carboxypeptidase B-like protease. At 16 degrees C, entry of EGF into late endosomes is slowed, and only the first processed form is generated over 60 min. Longer perfusions (180 min) at 16 degrees C result in some processing (7%) by proteases found in late endosomes. EGF-horseradish peroxidase cytochemistry confirmed that the additional processing detected at 180 min correlated with movement of EGF from tubulovesicular to multivesicular endosomes. These results, combined with in vitro incubations of EGF in isolated endosomal and lysosomal fractions, suggest that different proteases are active at selective points in the endocytic pathway and that the full complement of proteases needed for complete degradation of EGF is active only in lysosomes.     

Cholesterol modulates the membrane binding and intracellular distribution of annexin 6

Annexins are Ca(2+)- and phospholipid-binding proteins that are widely expressed in mammalian tissues and that bind to different cellular membranes. In recent years its role in membrane traffic has emerged as one of its predominant functions, but the regulation of its intracellular distribution still remains unclear. We demonstrated that annexin 6 translocates to the late endocytic compartment in low density lipoprotein-loaded CHO cells. This prompted us to investigate whether cholesterol, one of the major constituents of low density lipoprotein, could influence the membrane binding affinity and intracellular distribution of annexin 6. Treatment of crude membranes or early and late endosomal fractions with digitonin, a cholesterol-sequestering agent, displayed a strong reduction in the binding affinity of a novel EDTA-resistant and cholesterol-sensitive pool of annexin 6 proteins. In addition, U18666A-induced accumulation of cholesterol in the late endosomal compartment resulted in a significant increase of annexin 6 in these vesicles in vivo. This translocation/recruitment correlates with an increased membrane binding affinity of GST-annexin 6 to late endosomes of U18666A-treated cells in vitro. In conclusion, the present study shows that changes in the intracellular distribution and concentration of cholesterol in different subcellular compartments participate in the reorganization of intracellular pools of Ca(2+)-dependent and -independent annexin 6.     

Specific association of annexin 1 with plasma membrane-resident and internalized EGF receptors mediated through the protein core domain

Phosphorylation of the Ca2+ and membrane-binding protein annexin 1 by epidermal growth factor (EGF) receptor tyrosine kinase has been thought to be involved in regulation of the EGF receptor trafficking. To elucidate the interaction of annexin 1 during EGF receptor internalization, we followed the distribution of annexin 1-GFP fusion proteins at sites of internalizing EGF receptors. The observed association of annexin 1 with EGF receptors was confirmed by immunoprecipitation. We found that this interaction was independent of a functional phosphorylation site in the annexin 1 N-terminal domain but mediated through the Ca2+ binding core domain.     

The annexin 2/S100A10 complex controls the distribution of transferrin receptor-containing recycling endosomes

The Ca2+- and lipid-binding protein annexin 2, which resides in a tight heterotetrameric complex with the S100 protein S100A10 (p11), has been implicated in the structural organization and dynamics of endosomal membranes. To elucidate the function of annexin 2 and S100A10 in endosome organization and trafficking, we used RNA-mediated interference to specifically suppress annexin 2 and S100A10 expression. Down-regulation of both proteins perturbed the distribution of transferrin receptor- and rab11-positive recycling endosomes but did not affect uptake into sorting endosomes. The phenotype was highly specific and could be rescued by reexpression of the N-terminal annexin 2 domain or S100A10 in annexin 2- or S100A10-depleted cells, respectively. Whole-mount immunoelectron microscopy of the aberrantly localized recycling endosomes in annexin 2/S100A10 down-regulated cells revealed extensively bent tubules and an increased number of endosome-associated clathrin-positive buds. Despite these morphological alterations, the kinetics of transferrin uptake and recycling was not affected to a significant extent, indicating that the proper positioning of recycling endosomes is not a rate-limiting step in transferrin recycling. The phenotype generated by this transient loss-of-protein approach shows for the first time that the annexin 2/S100A10 complex functions in the intracellular positioning of recycling endosomes and that both subunits are required for this activity.     

Annexin II regulates multivesicular endosome biogenesis in the degradation pathway of animal cells

Proteins of the annexin family are believed to be involved in membrane-related processes, but their precise functions remain unclear. Here, we have made use of several experimental approaches, including pathological conditions, RNA interference and in vitro transport assays, to study the function of annexin II in the endocytic pathway. We find that annexin II is required for the biogenesis of multivesicular transport intermediates destined for late endosomes, by regulating budding from early endosomes-but not the membrane invagination process. Hence, the protein appears to be a necessary component of the machinery controlling endosomal membrane dynamics and multivesicular endosome biogenesis. We also find that annexin II interacts with cholesterol and that its subcellular distribution is modulated by the subcellular distribution of cholesterol, including in cells from patients with the cholesterol-storage disorder Niemann-Pick C. We conclude that annexin II forms cholesterol-containing platforms on early endosomal membranes, and that these platforms regulate the onset of the degradation pathway in animal cells.     

EGF stimulates annexin 1-dependent inward vesiculation in a multivesicular endosome subpopulation

Here we show that EGF and EGF receptor (EGFR) are trafficked through a subpopulation of multivesicular endosomes/bodies (MVBs) that are distinct from morphologically identical vacuoles that label for the late endosomal marker lyso-bisphosphatidic acid (LBPA). EGF stimulation increases both MVB biogenesis and inward vesiculation within EGFR-containing MVBs. Deletion of annexin 1, a substrate of EGFR tyrosine kinase, abolishes the effect of EGF stimulation on inward vesiculation. This phenotype is reversible by transfection with wild-type but not Y21F phosphorylation mutant annexin 1. Deletion of annexin 1 has no effect on EGF-stimulated MVB biogenesis, suggesting that MVB biogenesis and inward vesiculation within MVB are mediated by separate mechanisms. Loss or depletion of annexin 1 has no effect on EGF degradation and causes only a small delay in EGFR degradation, indicating that annexin 1 operates downstream of Hrs- and ESCRT-mediated sorting and is required solely for EGF-stimulated inward vesiculation. Annexin 1 accumulates on internal vesicles of MVB after EGF-stimulated inward vesiculation, suggesting that it may be required for a late stage in inward vesiculation.     

Polarized transport of MHC class II molecules in Madin-Darby canine kidney cells is directed by a leucine-based signal in the cytoplasmic tail of the beta-chain.

MHC class II molecules are found on the basolateral plasma membrane domain of polarized epithelial cells, where they can present Ag to intraepithelial lymphocytes in the vascular space. We have analyzed the sorting information required for efficient intracellular localization and polarized distribution of MHC class II molecules in stably transfected Madin-Darby canine kidney cells. These cells were able to present influenza virus particles to HLA-DR1-restricted T cell clones. Wild-type MHC class II molecules were located on the basolateral plasma membrane domain, in basolateral early endosomes, and in late multivesicular endosomes, the latter also containing the MHC class II-associated invariant chain and an HLA-DM fusion protein. A phenylalanine-leucine residue within the cytoplasmic tail of the beta-chain was required for basolateral distribution, efficient internalization, and localization of the MHC class II molecules to basolateral early endosomes. However, distribution to apically located, late multivesicular endosomes did not depend on signals in the class II cytoplasmic tails as both wild-type class II molecules and mutant molecules lacking the phenylalanine-leucine motif were found in these compartments. Our results demonstrate that sorting information in the tails of class II dimers is an absolute requirement for their basolateral surface distribution and intracellular localization.     

Regulation of the MVB pathway by SCAMP3

The biogenesis of multivesicular endosomes and the sorting of activated signaling receptors into multivesicular endosomes depend on soluble protein complexes (ESCRT complexes), which transiently interact with the receptor cargo and the endosomal membrane. Previously, it was shown that the transmembrane protein secretory carrier membrane protein (SCAMP) 3, which is present on endosomes, interacts with ESCRT components. Here, we report that SCAMP3 plays a role in the biogenesis of multivesicular endosomes. We find that SCAMP3 plays a role in EGF receptor sorting into multivesicular endosomes and in the formation of intralumenal vesicles within these endosomes in vitro and thus also controls EGF receptor targeting to lysosomes. We also find that SCAMP3 regulates the EGF-dependent biogenesis of multivesicular endosomes. We conclude that the transmembrane protein SCAMP3 has a positive role in sorting into and budding of intralumenal vesicles and thereby controls the process of multivesicular endosome biogenesis.     

Hrs and SNX3 functions in sorting and membrane invagination within multivesicular bodies

After internalization, ubiquitinated signaling receptors are delivered to early endosomes. There, they are sorted and incorporated into the intralumenal invaginations of nascent multivesicular bodies, which function as transport intermediates to late endosomes. Receptor sorting is achieved by Hrs—an adaptor-like protein that binds membrane PtdIns3P via a FYVE motif—and then by ESCRT complexes, which presumably also mediate the invagination process. Eventually, intralumenal vesicles are delivered to lysosomes, leading to the notion that EGF receptor sorting into multivesicular bodies mediates lysosomal targeting. Here, we report that Hrs is essential for lysosomal targeting but dispensable for multivesicular body biogenesis and transport to late endosomes. By contrast, we find that the PtdIns3P-binding protein SNX3 is required for multivesicular body formation, but not for EGF receptor degradation. PtdIns3P thus controls the complementary functions of Hrs and SNX3 in sorting and multivesicular body biogenesis.     

Re-localization of activated EGF receptor and its signal transducers to multivesicular compartments downstream of early endosomes in response to EGF

The rapid internalization of receptor tyrosine kinases after ligand binding has been assumed to be a negative modulation of signal transduction. However, accumulating data indicate that signal transduction from internalized cell surface receptors also occurs from endosomes. We show that a substantial fraction of tyrosine-phosphorylated epidermal growth factor receptor (EGFR) and Shc, Grb2 and Cbl after internalization relocates from early endosomes to compartments which are negative for the early endosomes, recycling vesicle markers EEA1 and transferrin in EGF-stimulated cells. These compartments contained the multivesicular body and late endosome marker CD63, and the late endosome and lysosome marker LAMP-1, and showed a multivesicular morphology. Subcellular fractionation revealed that activated EGFR, adaptor proteins and activated ERK 1 and 2 were located in EEA1-negative and LAMP-1-positive fractions. Co-immunoprecipitations showed EGFR in complex with both Shc, Grb2 and Cbl. Treatment with the weak base chloroquine or inhibitors of lysosomal enzymes after EGF stimulation induced an accumulation of tyrosine-phosphorylated EGFR and Shc in EEA1-negative and CD63-positive vesicles after a 120-min chase period. This was accompanied by a sustained activation of ERK 1 and 2. These results suggest that EGFR signaling is not spatially restricted to the plasma membrane, primary vesicles and early endosomes, but is continuing from late endocytic trafficking organelles maturing from early endosomes.     

SNX12 role in endosome membrane transport

In this paper, we investigated the role of sorting nexin 12 (SNX12) in the endocytic pathway. SNX12 is a member of the PX domain-containing sorting nexin family and shares high homology with SNX3, which plays a central role in the formation of intralumenal vesicles within multivesicular endosomes. We found that SNX12 is expressed at very low levels compared to SNX3. SNX12 is primarily associated with early endosomes and this endosomal localization depends on the binding to 3-phosphoinositides. We find that overexpression of SNX12 prevents the detachment (or maturation) of multivesicular endosomes from early endosomes. This in turn inhibits the degradative pathway from early to late endosomes/lysosomes, much like SNX3 overexpression, without affecting endocytosis, recycling and retrograde transport. In addition, while previous studies showed that Hrs knockdown prevents EGF receptor sorting into multivesicular endosomes, we find that overexpression of SNX12 restores the sorting process in an Hrs knockdown background. Altogether, our data show that despite lower expression level, SNX12 shares redundant functions with SNX3 in the biogenesis of multivesicular endosomes.     

Endogenous cleavage of annexin I generates a truncated protein with a reduced calcium requirement for binding to neutrophil secretory vesicles and plasma membrane

We have earlier shown that an N-terminal truncated annexin I molecule, annexin I(des1-8), is generated in human neutrophils through cleavage by a membrane localized metalloprotease. The truncated protein showed differences in membrane binding among the neutrophil granule populations as compared to full-length annexin I. In this study, we investigated the cleavage capabilities of isolated neutrophil secretory vesicles and plasma membrane, and the binding of full-length annexin I and annexin I(des1-8) to these membrane fractions. Translocations were performed in vitro to secretory vesicles and plasma membrane, respectively, at different Ca(2+) concentrations. We show that the annexin I-cleaving membrane localized metalloprotease is present both in the secretory vesicles and the plasma membrane. The N-terminal truncation of annexin I gives rise to a molecule with a decreased Ca(2+) requirement for binding, both to secretory vesicles and plasma membrane. There was, thus, no difference in binding of either full-length annexin I or annexin I(des1-8) to the secretory vesicles as compared to the plasma membrane.     

Annexin V relocates to the platelet cytoskeleton upon activation and binds to a specific isoform of actin.

We have previously reported that stimulation of platelets causes a relocation of annexin V to the cytoplasmic side of the plasma membrane where it associates with actin. This study examined the association of annexin V with the platelet cytoskeleton and its binding to actin, following both physiological activation with thrombin and Ca2+ -ionophore activation. The time-dependence of annexin V incorporation into the detergent-extracted cytoskeleton following activation with thrombin was also measured. Although calcium from the intracellular stores was enough to relocate intracellular annexin V to the cytoskeleton, this relocation was further enhanced by influx of extracellular calcium. The association of annexin V with the cytoskeleton was found to be unaffected by the action of cytochalasin E, however, annexin V was solubilized when DNase I was used to depolymerize the membrane cytoskeleton, and spontaneously re-associated with the actin filaments when re-polymerization was induced in vitro. Using a bifunctional crosslinking reagent we have identified an 85-kDa complex in both membrane and cytoskeleton fractions containing annexin V and actin. Direct binding to actin filaments was only observed in high [Ca2+], however, inclusion of an extract from thrombin-stimulated platelets lowered the [Ca2+] requirement for the binding of annexin V to F-actin to physiological levels. We also show that GST-annexin V mimics the physiological binding of annexin V to membranes, and that this GST-annexin V binds directly to a specific isoform of actin. Immunoprecipitation using antibodies against annexin V copurify annexin V and gamma- but not beta-actin from activated platelets. This is the first report of a possible preferential binding of annexin V to a specific isoform of actin, namely gamma-actin. The results of this study suggest a model in which annexin V that relocates to the plasma membrane and binds to gamma-actin in an activation-dependent manner forms a strong association with the platelet cytoskeleton.     

Lipid raft endocytosis and exosomal transport facilitate extracellular trafficking of annexin A2

Annexin A2 (AnxA2), a Ca(2+)-dependent phospholipid-binding protein, is known to associate with the plasma membrane and the endosomal system. Within the plasma membrane, AnxA2 associates in a Ca(2+) dependent manner with cholesterol-rich lipid raft microdomains. Here, we show that the association of AnxA2 with the lipid rafts is influenced not only by intracellular levels of Ca(2+) but also by N-terminal phosphorylation at tyrosine 23. Binding of AnxA2 to the lipid rafts is followed by the transport along the endocytic pathway to be associated with the intralumenal vesicles of the multivesicular endosomes. AnxA2-containing multivesicular endosomes fuse directly with the plasma membrane resulting in the release of the intralumenal vesicles into the extracellular environment, which facilitates the exogenous transfer of AnxA2 from one cell to another. Treatment with Ca(2+) ionophore triggers the association of AnxA2 with the specialized microdomains in the exosomal membrane that possess raft-like characteristics. Phosphorylation at Tyr-23 is also important for the localization of AnxA2 to the exosomal membranes. These results suggest that AnxA2 is trafficked from the plasma membrane rafts and is selectively incorporated into the lumenal membranes of the endosomes to escape the endosomal degradation pathway. The Ca(2+)-dependent exosomal transport constitutes a novel pathway of extracellular transport of AnxA2.     

Modes of annexin-membrane interactions analyzed by employing chimeric annexin proteins

Annexin II is a member of the annexin family of Ca(2+)- and phospholipid-binding proteins which is particularly enriched on early endosomal membranes and has been implicated in participating in endocytic events. In contrast to other endosomal annexins the association of annexin II with its target membrane can occur in the absence of Ca(2+) in a manner depending on the unique N-terminal domain of the protein. However, endosome binding of annexin II does not require formation of a protein complex with the intracellular ligand S100A10 (p11) as an annexin II mutant protein (PM AnxII) incapable of interacting with p11 is still present on endosomal membranes. Fusion of the N-terminal sequence of this PM AnxII (residues 1-27) to the conserved protein core of annexin I transfers the capability of Ca(2+)-independent membrane binding to the otherwise Ca(2+)-sensitive annexin I. These results underscore the importance of the N-terminal sequence of annexin II for the Ca(2+)-independent endosome association and argue for a direct interaction of this sequence with an endosomal membrane receptor.     

Antibodies to hepatic endosomes. Identification of two endosome antigens

Endosome fractions were prepared from rat liver homogenates, and antibodies were raised in rabbits against the integral membrane proteins. Immunofluorescent studies showed that these antibodies identified primarily intracellular structures in liver sections, isolated hepatocytes and HepG-2 cells. Immunoelectron microscopy using protein A-gold confirmed that endocytic multivesicular structures, especially those located at the biliary pole of the hepatocyte, were labeled. Biochemical analysis showed that approximately 12 endosome antigens were present. A major 43 kDa glycosylated antigen corresponded to the asialoglycoprotein receptor subunit. A further antigen identified in endosomes was a 115 kDa polypeptide pI 4.3 previously identified as a major calmodulin-binding protein. The antigens identified in rat liver endosomes were different to those previously shown by other studies to be present in the Golgi apparatus and lysosomes.     

Rab5-dependent trafficking of the m4 muscarinic acetylcholine receptor to the plasma membrane, early endosomes, and multivesicular bodies

The m4 subtype of muscarinic acetylcholine receptor regulates many physiological processes and is a novel therapeutic target for neurologic and psychiatric disorders. However, little is known about m4 regulation because of the lack of pharmacologically selective ligands. A crucial component of G protein-coupled receptor regulation is intracellular trafficking. We thus used subtype-specific antibodies and quantitative immunocytochemistry to characterize the intracellular trafficking of m4. We show that following carbachol stimulation, m4 co-localizes with transferrin, and the selective marker of early endosomes, EEA1. In addition, m4 intracellular localization depends on Rab5 activity. The dominant negative Rab5S34N inhibits m4 endocytosis initially following carbachol stimulation, and reduces the size of m4 containing vesicles. The constitutively active Rab5Q79L enhances m4 intracellular distribution, even in unstimulated cells. Rab5Q79L also produces strikingly enlarged vacuoles, which by electron microscopy contain internal vesicles, suggesting that they are multivesicular bodies. m4 localizes both to the perimeter and interior of these vacuoles. In contrast, transferrin localizes only to the vacuole perimeter, demonstrating divergence of m4 trafficking from the pathway followed by constitutively endocytosed transferrin. We thus suggest a novel model by which multivesicular bodies sort G protein-coupled receptors from a transferrin-positive recycling pathway to a nonrecycling, possibly degradative pathway.