Ferromagnetic isolation of endosomes involved in vitellogenin transfer into Xenopus oocytes

The transport pathway of the yolk precursor vitellogenin (VTG) has been followed using the techniques of ferrolabeling and ferromagnetic sorting, coupled with electron microscopic visualization. Vitellogenin conjugated to colloidal ferric particles of ca. 11 nm is selectively transported from the oolemma to the yolk platelets of vitellogenic Xenopus oocytes after gonadotropin stimulation of the female. Several cortical membrane compartments, labeled or unlabeled with ferric particles, are involved in the internalization and the transfer of vitellogenin to the yolk platelets. 1) Coated pits apparently fuse with coated vesicles, and coated vesicles fuse with each other in the outermost cortical cytoplasm. 2) Vesicles, depleted of their clathrin coat, fuse with cortical tubular endosomes and discharge their contents into yolk endosomes. 3) These endosomes are the direct precursors of the yolk organelles. 4) Endocytic vesicles fuse only with primordial yolk platelets of type I and not with type II or fully grown yolk platelets. After pulse-chase loading with ferric particles conjugated to vitellogenin and subsequent subcellular fractionation of the oocytes, ferromagnetic sorting of the various vesicle populations has been performed by using a "free-flow magnetic chamber". This novel method enables specification and characterization of purified endosomal compartments that accumulate protein yolk in Xenopus oocytes.     

Multivesicular bodies play a key role in vitellogenin endocytosis by Xenopus oocytes

A combination of electron microscopic tracers and subcellular fractionation has been used to examine the endocytic pathway of the yolk protein precursor, vitellogenin (VG), in Xenopus oocytes. VG was adsorbed to colloidal gold, and the organelles traversed by newly internalized ligand were examined at various time intervals after endocytosis. VG-Au enters oocytes via coated pits and vesicles and then appears rapidly in tubular endosomes and multivesicular bodies (MVBs). MVBs play a central role in VG processing for storage; the large majority of newly internalized VG enters this compartment, remaining there for up to several hours. Condensation of VG into crystalline bodies begins in MVBs, and continues with growth of the crystals until typical platelets are formed. When oocytes are exposed to high [VG], MVBs containing large amounts of internalized VG are morphologically indistinguishable from the primordial yolk platelets described earlier (Dumont, 1978). The use of VG-Au particles of two sizes demonstrates that gold particles in early MVBs were generally associated with the limiting membrane of these organelles, while older MVB compartments have gold particles well separated from the limiting membranes, suggesting that dissociation of VG from its receptor occurs in this compartment. Newly internalized ligand preferentially forms a new MVB, rather than fusing and mixing with previously formed MVBs. Progressive yolk protein condensation gradually transforms MVBs into yolk platelets over a period of several hours. Analysis of 125I-VG-Au behavior after sucrose gradient fractionation of oocytes allowed correlation of biochemical compartments with those observed in the electron microscope. MVBs containing yolk in progressive stages of condensation were found at densities from 1.16 up to 1.21 g/cc. The final, rate-limiting step in VG transport is a shift of ligand from light (1.21 g/cc) to heavy (1.23 g/cc) platelet compartments (Wall and Meleka, 1985). The morphological correlate of this process is movement of VG-Au from small (less than 3-4 microns diameter) to large (greater than 4 microns diameter) platelets.     

In Vivo Study of Vitellogenin-Gold Transport in the Ovarian Follicle and Oocyte of Xenopus laevis

The transport of injected vitellogenin (VTG)-gold in the ovarian follicle and developing oocyte in Xenopus is described. The gold particles reached the extracellular spaces of the theca and interfollicular spaces within 1 and 2 hr, respectively, after a tracer injection at 20°C. The tracers moved through channels between the constitutive cells of both the capillary endothelium and the follicle cell layer.
Compartments in the peripheral cytoplasm of vitellogenic oocytes at stage IV, which relate to yolk formation, seemed to be segregated as follows: (a) internalization compartment consisting of coated pits and vesicles of the oolemma covering the oocyte "macrovilli", (b) transport compartment of endosomes and multivesicular endosomes in the oocyte cortex, and (c) crystallization compartment of primordial yolk platelets (PYP) in the sub-cortical region. The gold particles appeared in the internalization and transport compartments at 3–6 hr after the tracer injection and in the cystallization compartment at 12–18 hr. The VTG, internalized by receptor-mediated endocytosis, was transferred from coated vesicles to multivesicular endosomes by vesicle-to-vesicle fusion. VTG crystallization took place in globular-shaped PYPs of about 1 μm. At 24 hr after the tracer injection, the gold particles appeared in completely crystallized yolk platelets, most of them clustered in the superficial layer and some integrated into the crystals.     

Receptor-mediated endocytosis of transferrin and ferritin by guinea-pig reticulocytes. Uptake by a common endocytic pathway

Earlier studies have shown that transferrin binds to specific receptors on the reticulocyte surface, clusters in coated pits and is then internalized via endocytic vesicles. Guinea-pig reticulocytes also have specific receptors for ferritin. In this paper ferritin and transferrin endocytosis by guinea-pig reticulocytes was studied by electron microscopy using the natural electron density of ferritin and colloidal gold-transferrin (AuTf). At 4 degrees C both ligands bound to the cell surface. At 37 degrees C progressive uptake occurred by endocytosis. AuTf and ferritin clustered in the same coated pits and small intracellular vesicles. After 60 min incubations the ligands colocalized to large multivesicular endosomes (MVE), still membrane-bound. MVE subsequently fused with the plasma membrane and released AuTf, ferritin and inclusions by exocytosis. All endocytic structures labelled with AuTf contained ferritin, but 23 to 35% of ferritin-labelled endocytic structures contained no AuTf. These data suggest that ferritin and transferrin are internalized through the same pathway involving receptors, coated pits and vesicles, but that these proteins are recycled only partly in common.     

Receptor-mediated endocytosis of transferrin and recycling of the transferrin receptor in rat reticulocytes

At 4 degrees C transferrin bound to receptors on the reticulocyte plasma membrane, and at 37 degrees C receptor-mediated endocytosis of transferrin occurred. Uptake at 37 degrees C exceeded binding at 4 degrees C by 2.5-fold and saturated after 20-30 min. During uptake at 37 degrees C, bound transferrin was internalized into a trypsin- resistant space. Trypsinization at 4 degrees C destroyed surface receptors, but with subsequent incubation at 37 degrees C, surface receptors rapidly appeared (albeit in reduced numbers), and uptake occurred at a decreased level. After endocytosis, transferrin was released, apparently intact, into the extracellular space. At 37 degrees C colloidal gold-transferrin (AuTf) clustered in coated pits and then appeared inside various intracellular membrane-bounded compartments. Small vesicles and tubules were labeled after short (5-10 min) incubations at 37 degrees C. Larger multivesicular endosomes became heavily labeled after longer (20-35 min) incubations. Multivesicular endosomes apparently fused with the plasma membrane and released their contents by exocytosis. None of these organelles appeared to be lysosomal in nature, and 98% of intracellular AuTf was localized in acid phosphatase-negative compartments. AuTf, like transferrin, was released with subsequent incubation at 37 degrees C. Freeze-dried and freeze-fractured reticulocytes confirmed the distribution of AuTf in reticulocytes and revealed the presence of clathrin-coated patches amidst the spectrin coating the inner surface of the plasma membrane. These data suggest that transferrin is internalized via coated pits and vesicles and demonstrate that transferrin and its receptor are recycled back to the plasma membrane after endocytosis.     

Glucagon receptors in endothelial and Kupffer cells of mouse liver

To determine whether hepatic sinusoidal cells contain glucagon receptors and, if so, to study the significance of the receptors in the cells, binding of [125I]-glucagon to nonparenchymal cells (mainly endothelial cells and Kupffer cells) isolated from mouse liver was examined by quantitative autoradiography and biochemical methods. Furthermore, the pathway of intracellular transport of colloidal gold-labeled glucagon (AuG) was examined in vivo. Autoradiographic and biochemical results demonstrated many glucagon receptors in both endothelial cells and Kupffer cells, and more receptors being present in endothelial cells than in Kupffer cells. In vivo, endothelial cells internalized AuG particles into coated vesicles via coated pits and transported the particles to endosomes, lysosomes, and abluminal plasma membrane. Therefore, receptor-mediated transcytosis of AuG occurs in endothelial cells. The number of particles present on the abluminal plasma membrane was constant if the amount of injected AuG increased. Therefore, the magnitude of receptor-mediated transcytosis of AuG appears to be regulated by endothelial cells. Kupffer cells internalized the ligand into cytoplasmic tubular structures via plasma membrane invaginations and transported the ligand exclusively to endosomes and lysosomes, suggesting that the ligand is degraded by Kupffer cells.     

Redistribution of cell surface transferrin receptors prior to their concentration in coated pits as revealed by immunoferritin labels

Summary Immunocytochemistry has been used to study distribution of cell surface transferrin receptors in erythroid, leukemic (K562) cells. The cells were fixed and labelled with monoclonal (OKT-9) anti-transferrin receptor antibodies; the antibody-labelled receptors were then detected by either immunofluoresceinor immunoferritin-antimouse-antibody conjugates. Typically, the immunoferritin labels were distributed diffusely at the non-coated regions of the cell surface as well as concentrated in the clathrincoated pits. To examine further this pattern of distribution, cells were labelled at 0° C and then warmed to 37° C for zero to 30 min prior to fixation. The majority of the immunoferritin labels were initially dispersed in small groups at the non-coated regions of the cell surface (mean = 6 immunoferritin labels/cluster), but larger groups were common subsequent to incubation at 37° C (mean = 13 immunoferritin labels/cluster). However, the size of immunoferritin labels in the coated pits was unchanged (mean = 12 immunoferritin labels/pit). Immunoferritin labels were typical in coated and uncoated vesicles l min after warming to 37° C, but common in endosomes, multivesicular bodies and lysosomes by 30 min. It appears that single cell-surface receptors form large aggregates prior to their concentration in coated pits. Coated vesicles, uncoated vesicles, and endosomal vacuoles may together form the non-lysosomal compartment where the internalized receptors might be dissociated from the ligands (antibodies).     

Pathway and kinetics of vitellogenin-gold internalization in the Xenopus oocyte

After in vitro incubation of Xenopus oocytes with vitellogenin (VTG)-gold conjugate, the gold particles are distributed on the whole plasma membrane. Their concentration in coated pits still occurs at 0 degrees C. At +20 degrees C the label quickly (30 sec) appears in multi-vesicular endosomes (MVE) which segregate together with primary endocytic vesicles into distinct clusters below the plasma membrane. From this step up to crystallization of the yolk platelets, the gold particles stay in the same compartment. During 5.5 h the label progressively increases along the MVE membrane, first (1.5 h) by fusion of primary endocytic vesicles with consecutively enlarging endosomes, then (4 h) by decreasing of the MVE membrane. As concerns the yolk platelet formation, concentration of primordial yolk platelets (PYP) occurs at 5.5 h from the incubation onset, the labeling of preexisting yolk platelets starts at 7 h, while crystallization of PYP begins only after 12-13 h. Our results indicate that VTG receptors are not preclustered in coated pits and their lateral translation is not inhibited at 0 degrees C. The yolk protein processing takes place within one compartment only. The VTG condensation begins with a long concentration phase of receptor-VTG complexes still integrated in the endosome membrane. It occurs in MVE by: i) a repeated fusion of primary endocytic vesicles; ii) removing part of the endosome membrane by internal vesiculation. Fusion between endosomes occurs only after VTG has dissociated from its receptors and VTG dissociates only when when the density of the VTG-receptor complexes in the endosome membrane is sufficient. Crystallization begins after a 7-8 h delay. The endosome migration into the oocyte is also controlled by the binding of VTG to its receptors. Our results also demonstrate that binding of VTG colloidal gold modifies neither the vitellogenic pathway nor the duration of the vitellogenin internalization. However when vitellogenin is bound to colloidal gold, dissociation of ligand-receptor complexes is delayed because the amount of ligand in the incubation medium is necessarily low.     

Intracellular pathways of endocytosed transferrin and non-specific tracers in epithelial cells lining the rete testis of the rat

Summary The uptake and pathway of different markers and ligands for fluid-phase, adsorptive and receptor mediated endocytosis were analyzed in the epithelial cells lining the rete testis after their infusion into the lumen of these anastomotic channels. At 2 min after injection, diferric transferrin bound to colloidal gold was seen attached to the apical plasma membrane and to the membrane of endocytic coated and uncoated pits and vesicles. The injection of transferrin-gold in the presence of a 100-fold excess of unconjugated diferric transferrin revealed no binding or internalization of transferrin-gold. Similarly, apotransferrin-gold was neither bound to the apical plasma membrane nor internalized by these cells. These results thus indicate the presence of specific binding sites for diferric transferrin. At 5 min, internalized diferric transferrin-gold reached endosomes. At 15 and 30 min, the endosomes were still labeled but at these time intervals the transferrin-gold also appeared in tubular elements connected to or associated with these bodies or seen in close proximity to the apical plasma membrane. At 60 and 90 min, most of the transferrin-gold was no longer present in these organelles and was seen only exceptionally in secondary lysosomes. These results thus suggest that the tubular elements may be involved in the recycling of transferrin back to the lumen of the rete testis. The coinjection of transferrin-gold and the fluid-phase marker native ferritin revealed that both proteins were often internalized in the same endocytic pit and vesicle and shared the same endosome. However, unlike transferrin, native ferritin at the late time intervals appeared in dense multivesicular bodies and secondary lysosomes. When the adsorptive marker cationic ferritin and the fluid-phase marker albumin-gold were coinjected, again both proteins often shared the same endocytic pit and vesicle, endosome, pale and dense multivesicular body and secondary lysosomes. However, several endocytic vesicles labeled only with cationic ferritin appeared to bypass the endosomal and lysosomal compartments and to reach the lateral intercellular space and areas of the basement membrane. The rete epithelial cells, therefore, appear to be internalizing proteins and ligands by receptor-mediated and non-specific endocytosis which, after having shared the same endocytic vesicle and endosome, appear to be capable of being segregated and routed to different destinations.     

Caveolar endocytosis of simian virus 40 reveals a new two-step vesicular-transport pathway to the ER

Simian virus 40 (SV40) is unusual among animal viruses in that it enters cells through caveolae, and the internalized virus accumulates in a smooth endoplasmic reticulum (ER) compartment. Using video-enhanced, dual-colour, live fluorescence microscopy, we show the uptake of individual virus particles in CV-1 cells. After associating with caveolae, SV40 leaves the plasma membrane in small, caveolin-1-containing vesicles. It then enters larger, peripheral organelles with a non-acidic pH. Although rich in caveolin-1, these organelles do not contain markers for endosomes, lysosomes, ER or Golgi, nor do they acquire ligands of clathrin-coated vesicle endocytosis. After several hours in these organelles, SV40 is sorted into tubular, caveolin-free membrane vesicles that move rapidly along microtubules, and is deposited in perinuclear, syntaxin 17-positive, smooth ER organelles. The microtubule-disrupting agent nocodazole inhibits formation and transport of these tubular carriers, and blocks viral infection. Our results demonstrate the existence of a two-step transport pathway from plasma-membrane caveolae, through an intermediate organelle (termed the caveosome), to the ER. This pathway bypasses endosomes and the Golgi complex, and is part of the productive infectious route used by SV40.     

Molecules internalized by clathrin-independent endocytosis are delivered to endosomes containing transferrin receptors

We have previously demonstrated that the preendosomal compartment in addition to clathrin-coated vesicles, comprises distinct nonclathrin coated endocytic vesicles mediating clathrin-independent endocytosis (Hansen, S. H., K. Sandvig, and B. van Deurs. 1991. J. Cell Biol. 113:731-741). Using K+ depletion in HEp-2 cells to block clathrin- dependent but not clathrin-independent endocytosis, we have now traced the intracellular routing of these nonclathrin coated vesicles to see whether molecules internalized by clathrin-independent endocytosis are delivered to a unique compartment or whether they reach the same early and late endosomes as encountered by molecules internalized with high efficiency through clathrin-coated pits and vesicles. We find that Con A-gold internalized by clathrin-independent endocytosis is delivered to endosomes containing transferrin receptors. After incubation of K(+)- depleted cells with Con A-gold for 15 min, approximately 75% of Con A- gold in endosomes is colocalized with transferrin receptors. Endosomes containing only Con A-gold may be accounted for either by depletion of existing endosomes for transferrin receptors or by de novo generation of endosomes. Cationized gold and BSA-gold internalized in K(+)- depleted cells are also delivered to endosomes containing transferrin receptors. h-lamp-1-enriched compartments are only reached occasionally within 30 min in K(+)-depleted as well as in control cells. Thus, preendosomal vesicles generated by clathrin-independent endocytosis do not fuse to any marked degree with late endocytic compartments. These data show that in HEp-2 cells, molecules endocytosed without clathrin are delivered to the same endosomes as reached by transferrin receptors internalized through clathrin-coated pits.     

Comparative study of vitellogenesis in the anuran amphibians Ceratophrys cranwelli (Leptodactilidae) and Bufo arenarum (Bufonidae)

The present study analyses, by transmission electron microscopy, vitellogenesis in two anuran amphibian families: Leptodactilidae (Ceratophrys cranwelli) and Bufonidae (Bufo arenarum). These differ in the type of stimulus that sets off their reproductive period, pluvial changes being the trigger in C. cranwelli and temperature increase in B. arenarum. We found that vitellogenesis follows an endocytic pathway that involves membranous structures (coated pits, coated vesicles, endosomes and multivesicular bodies). This process results in a fully grown yolk platelet of similar structure in both species. Despite the above similarity, a distinctive feature in B. arenarum was that the multivesicular bodies exhibited condensed proteins together with lipid droplets, the latter remaining as such even in the primordial yolk platelet. In C. cranwelli, however, lipids droplets were only found attached to the primordial yolk platelet. The coexistence of lipid droplets together with proteins in the nascent precursor yolk platelets observed in B. arenarum is similar to that found in B. marinus. This fact might constitute a characteristic feature of the Bufonidae family.     

Hemopexin joins transferrin as representative members of a distinct class of receptor-mediated endocytic transport systems

Receptor-mediated transport of heme by hemopexin in vivo and in vitro results in catabolism of heme but not the protein, suggesting that intact apohemopexin recycles from cells. However, until now, the intracellular transport of hemopexin by receptor-mediated endocytosis remained to be established. Biochemical studies on cultured human HepG2 and mouse Hepa hepatoma cells demonstrate that hemopexin is transported to an intracellular location and, after endocytosis, is subsequently returned intact to the medium. During incubation at 37 degrees C, hemopexin accumulated intracellularly for ca. 15 min before reaching a plateau while surface binding was saturated by 5 min. No internalization of ligand took place during incubation at 4 degrees C. These and other data suggest that hemopexin receptors recycle, and furthermore, incubation with monensin significantly inhibits the amount of cell associated of heme-[125I]hemopexin during short-term incubation at 37 degrees C, consistent with a block in receptor recycling. Ammonium chloride and methylamine were less inhibitory. Electron microscopic autoradiography of heme-[125I]hemopexin showed the presence of hemopexin in vesicles of the classical pathway of endocytosis in human HepG2 hepatoma cells, confirming the internalization of hemopexin. Colloidal gold-conjugated hemopexin and electron microscopy showed that hemopexin bound to receptors at 4 degrees C is distributed initially over the entire cell surface, including microvilli and coated pits. After incubation at 37 degrees C, hemopexin-gold is located intracellularly in coated vesicles and then in small endosomes and multivesicular bodies. Colocalization of hemopexin and transferrin intracellularly was shown in two ways. Radioiodinated hemopexin was observed in the same subcellular compartment as horseradish peroxidase conjugates of transferrin using the diaminobenzidine-induced density shift assay. In addition, colloidal gold derivatives of heme-hemopexin and diferric transferrin were found together in coated pits, coated vesicles, endosomes and multivesicular bodies. Therefore, hemopexin and transferrin act by a similar receptor-mediated mechanism in which the transport protein recycles after endocytosis from the cell to undergo further rounds of intracellular transport.     

Receptor-mediated endocytosis: the intracellular journey of transferrin and its receptor

A variety of ligands and macromolecules enter cells by receptor-mediated endocytosis. Ligands bind to their receptors on the cell surface and ligand-receptor complexes are localized in specialized regions of the plasma membrane called coated pits. Coated pits invaginate and give rise to intracellular coated vesicles containing ligand-receptor complexes which are thus internalized. Transferrin, a major serum glycoprotein which transports iron into cells, enters cells by this pathway. It binds to its receptor on the cell surface, transferrin-receptor complexes cluster in coated pits and are internalized in coated vesicles. Coated vesicles then lose their clathrin coat and fuse with endosomes, an organelle with an internal pH of about 5-5.5. Most ligands dissociate from their receptors in endosomes and they finally end up in lysosomes where they are degraded, while their receptors remain bound to membrane structures and recycle to the cell surface. Transferrin has a different fate: in endosomes iron dissociates from transferrin but apotransferrin remains bound to its receptor because of its high affinity for the receptor at acid pH. Apotransferrin thus recycles back to the plasma membrane still bound to its receptor. When the ligand-receptor complex reaches the plasma membrane or a compartment at neutral pH, apotransferrin dissociates from its receptor with a half-life of 18 s because of its low affinity for its receptor at neutral pH. The receptor is then ready for a new cycle of internalization, while apotransferrin enters the circulation, reloads iron in the appropriate organs and is ready for a new cycle of iron transport.     

Binding and endocytosis of heparin-gold conjugates by the fenestrated endothelium of the rat choriocapillaris

Summary Heparin-gold probes were used to localize regions of heparin binding on the luminal surface of the diaphragmed-fenestrated endothelium of the rat choriocapillaris. Structures of endothelial cells were unlabeled when rats were kept on ice and perfused with solutions at 4° C. When the heparin-gold quantity was doubled, only a few heparin-gold particles marked some diaphragms spanning fenestrae, vesicles and channels, parajunctional regions of the plasmalemma, and coated pits. With solutions at 4° C, but the animals kept at room temperature, all of these structures in the endothelial cells were labeled. This binding was not altered by the perfusion of low levels of unlabeled heparin, but was eliminated following high levels of unlabeled heparin, and by digestion with trypsin and pronase. At 37° C, heparin was localized to the above structures and, in addition, was internalized into coated vesicles, endosomes, and multivesicular bodies, but not other types of lysosomes. Some particles were found in tubules adjacent to the Golgi stacks. Heparin-gold was also transported to the abluminal front of the endothelium by vesicles. A desulfated, non-anticoagulant, fraction of heparin bound to gold was localized to the endothelium in the same manner. These results demonstrate receptors for heparin on the surface of a fenestrated endothelium. Furthermore, they show the pathway of endocytosis and transport of heparin. The possible roles of heparin in the function of the endothelium is discussed.     

Ultrastructural visualization of the internalization of low density lipoprotein by human placental cells

Summary Low density lipoproteins (LDL) were conjugated to colloidal gold to visualize the route for internalization of LDL in the cultured cells of human term placenta. Cells were obtained from placental villi (caesarian section) by a standard trypsin-DNase dispersion method followed in some cases by a Percoll gradient centrifugation step. Employing electron microscopy it was observed that after 3 days of culture, cells obtained by trypsin-DNAse dispersion were a mixture of macrophages, mononucleated cells and large multinucleated cells. When the cells were incubated for 3 days after the Percoll purification, essentially multinucleated cells identical to the syncytiotrophoblast were present. The number of LDL receptor was increased by preincubation in medium with lipoprotein depleted serum. In binding experiments cells incubated at 4° C for 2 h with medium containing gold LDL conjugates showed gold LDL attached to the plasma membrane without characteristic localization. After incubation with gold LDL at 37° C for various times, the three cellular types showed ligand internalization. Gold LDL endocytosis involved first coated pits but also uncoated plasmalemmal invaginations. Then gold LDL was further observed in coated and non coated vesicles, smooth walled endosomes, multivesicular bodies and tubular vesicles. Lastly free gold particles were observed in lysosome like dense bodies. These results prove the internalization of gold LDL conjugates by human cultured placental cells, particularly by syncytiotrophoblast like multinucleated cells. This accumulation of LDL (the major cholesterol carrying protein in humans) is recognised to be responsable for the exogenous cholesterol supply indispensable to the progesterone biosynthesis and cellular growth of the placenta.     

Axonal and dendritic endocytic pathways in cultured neurons

The endocytic pathways from the axonal and dendritic surfaces of cultured polarized hippocampal neurons were examined. The dendrites and cell body contained extensive networks of tubular early endosomes which received endocytosed markers from the somatodendritic domain. In axons early endosomes were confined to presynaptic terminals and to varicosities. The somatodendritic but not the presynaptic early endosomes were labeled by internalized transferrin. In contrast to early endosomes, late endosomes and lysosomes were shown to be predominantly located in the cell body. Video microscopy was used to follow the transport of internalized markers from the periphery of axons and dendrites back to the cell body. Labeled structures in both domains moved unidirectionally by retrograde fast transport. Axonally transported organelles were sectioned for EM after video microscopic observation and shown to be large multivesicular body-like structures. Similar structures accumulated at the distal side of an axonal lesion. Multivesicular bodies therefore appear to be the major structures mediating transport of endocytosed markers between the nerve terminals and the cell body. Late endocytic structures were also shown to be highly mobile and were observed moving within the cell body and proximal dendritic segments. The results show that the organization of the endosomes differs in the axons and dendrites of cultured rat hippocampal neurons and that the different compartments or stages of the endocytic pathways can be resolved spatially.     

Ultrastructural visualization of the internalization of low density lipoprotein by human placental cells

Low density lipoproteins (LDL) were conjugated to colloidal gold to visualize the route for internalization of LDL in the cultured cells of human term placenta. Cells were obtained from placental villi (caesarian section) by a standard trypsin-DNase dispersion method followed in some cases by a Percoll gradient centrifugation step. Employing electron microscopy it was observed that after 3 days of culture, cells obtained by trypsin-DNase dispersion were a mixture of macrophages, mononucleated cells and large multinucleated cells. When the cells were incubated for 3 days after the Percoll purification, essentially multinucleated cells identical to the syncytiotrophoblast were present. The number of LDL receptor was increased by preincubation in medium with lipoprotein depleted serum. In binding experiments cells incubated at 4 degrees C for 2 h with medium containing gold LDL conjugates showed gold LDL attached to the plasma membrane without characteristic localization. After incubation with gold LDL at 37 degrees C for various times, the three cellular types showed ligand internalization. Gold LDL endocytosis involved first coated pits but also uncoated plasmalemmal invaginations. Then gold LDL was further observed in coated and non coated vesicles, smooth walled endosomes, multivesicular bodies and tubular vesicles. Lastly free gold particles were observed in lysosome like dense bodies. These results prove the internalization of gold LDL conjugates by human cultured placental cells, particularly by syncytiotrophoblast like multinucleated cells. This accumulation of LDL (the major cholesterol carrying protein in humans) is recognised to be responsible for the exogenous cholesterol supply indispensable to the progesterone biosynthesis and cellular growth of the placenta.     

Rab11 regulates the compartmentalization of early endosomes required for efficient transport from early endosomes to the trans-golgi network

Several GTPases of the Rab family, known to be regulators of membrane traffic between organelles, have been described and localized to various intracellular compartments. Rab11 has previously been reported to be associated with the pericentriolar recycling compartment, post-Golgi vesicles, and the trans-Golgi network (TGN). We compared the effect of overexpression of wild-type and mutant forms of Rab11 on the different intracellular transport steps in the endocytic/degradative and the biosynthetic/exocytic pathways in HeLa cells. We also studied transport from endosomes to the Golgi apparatus using the Shiga toxin B subunit (STxB) and TGN38 as reporter molecules. Overexpression of both Rab11 wild-type (Rab11wt) and mutants altered the localization of the transferrrin receptor (TfR), internalized Tf, the STxB, and TGN38. In cells overexpressing Rab11wt and in a GTPase-deficient Rab11 mutant (Rab11Q70L), these proteins were found in vesicles showing characteristics of sorting endosomes lacking cellubrevin (Cb). In contrast, they were redistributed into an extended tubular network, together with Cb, in cells overexpressing a dominant negative mutant of Rab11 (Rab11S25N). This tubularized compartment was not accessible to Tf internalized at temperatures <20 degrees C, suggesting that it is of recycling endosomal origin. Overexpression of Rab11wt, Rab11Q70L, and Rab11S25N also inhibited STxB and TGN38 transport from endosomes to the TGN. These results suggest that Rab11 influences endosome to TGN trafficking primarily by regulating membrane distribution inside the early endosomal pathway.     

Receptor-mediated endocytosis of insulin by cultured endothelial cells.

Label-fracture immunochemistry and pre-embedding indirect immunocytochemistry were applied to investigate insulin uptake by endothelial cells. Freeze fracture replicas showed that a small percentage of native insulin receptors are associated with non-coated pits (4%) and coated pits (2%). After warming, receptor bound insulin became increasingly associated with such endocytotic vesicles. After 2 min the percentage of detectable insulin associated with non-coated and coated pits increased to 16% and 8%, respectively. Pre-embedding immunocytochemical localization of insulin gave results consistent with those obtained from the label-fracture studies. Both non-coated and coated vesicles appeared labelled after 5 min of warming. Non-coated vesicles contained 25% of the cell associated insulin while 9% was associated with coated pits and vesicles. After 10 min of warming, 9% of label was located in non-coated vesicles and 7% in coated vesicles. A large proportion (29%) of the label was found in tubular-vesicular endosomes at this time. After 15 min of warming, 30% of the remaining cell-associated gold label was found in multivesicular bodies. These experiments demonstrate that insulin uptake by endothelium is mediated by both coated and non-coated vesicles and that, once internalized, insulin is routed through endosomal pathways that primarily result in transcytosis.