Class II MHC molecules and antigen enter the same vesicles during internalization by resting B lymphocytes

Efficient presentation of Ag by a B cell to a T cell requires that Ag bind to the Ag receptor (Ig) on the B cell, after which it is internalized into an acid compartment where it is modified and returned to the cell surface in the context of class II MHC molecules. It remains uncertain whether processed Ag binds to class II which has been internalized and recycled with Ag, or to nascent class II inside the cell. To determine if cell surface class II enters the same vesicles as Ag, or is excluded during internalization of Ag which is bound to the B cell receptor, 5- and 16-nm gold particles were labeled with anti-class II and anti-Ig, respectively. Cells were incubated at 37 degrees C and internalization of these particles was observed using electron microscopy. By 10 min, 60-75% of the B cell sections contained vesicles with gold particles inside them. Between 40 and 64% of these vesicles had both 5- and 16-nm particles. Maximum internalization occurred by 30-60 min, and by 2 hr the number of small and large particles on the B cell surface became constant or increased, respectively. Both kinds of particles moved from electron-lucent to electron-dense vesicles as the incubation time increased, although a portion of the anti-class II particles remained in electron-lucent vesicles. These data clearly show that labeled, cell surface class II is not selectively excluded from Ag-containing vesicles during Ag internalization. Thus, cointernalization of Ag and class II may represent a mechanism by which processed Ag meets class II.     

Internalization and processing of transferrin and the transferrin receptor in human carcinoma A431 cells

The binding and subsequent intracellular processing of transferrin and transferrin receptors was studied in A431 cells using 125I-transferrin and a monoclonal antibody to the receptor (ATR) labeled with 125I and gold colloid. Using 125I-transferrin we have shown that, whereas at 37 degrees C uptake proceeded linearly for up to 60 min, most of the ligand that was bound was internalized and then rapidly returned to the incubation medium undegraded. At 37 degrees C, the intracellular half- life of the most rapidly recycled transferrin was 7.5 min. 125I-ATR displayed the same kinetics of uptake but following its internalization at 37 degrees C, it was partially degraded. At 22 degrees C and below, the intracellular degradation of 125I-ATR was selectively inhibited and as a result it accumulated intracellularly. Electron microscopy of conventional thin sections and of whole-cell mounts was used to follow the uptake and processing of transferrin receptors labeled with ATR- gold colloid complexes. Using a pulse-chase protocol, the intracellular pathway followed by internalized ATR gold-receptor complexes was outlined in detail. Within 5 min at 22 degrees C the internalized complexes were transferred from coated pits on the cell surface to a system of narrow, branching cisternae within the peripheral cytoplasm. By 15 min they reached larger, more dilated elements that, in thin section, appeared as irregular profiles containing small (30-50-nm diam) vesicles. By 30 min, the gold complexes were located predominantly within typical spherical multivesicular bodies lying in the peripheral cytoplasm, and by 40-60 min, they reached a system of cisternal and multivesicular body elements in the juxtanuclear area. At 22 degrees C, no other compartments became labeled but if they were warmed to 37 degrees C the gold complexes were transferred to lysosome- like elements. Extracting ATR-gold complexes with Triton X after a 30- min chase at 22 degrees C and purifying them on Sepharose-transferrin indicated that the internalized complexes remained bound to the transferrin receptor during their intracellular processing.     

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.     

The biosynthetic pathway of MHC class II but not class I molecules intersects the endocytic route

We studied the intracellular traffic and subcellular distribution of MHC class I and class II antigens in comparison with a recycling surface glycoprotein, the transferrin receptor (Tfr), in the human lymphoblastoid cell line JY. No internalization was detectable for class I molecules. Class II molecules were internalized but did not recycle. In contrast, Tfr was found to internalize and recycle. The biosynthetic pathway of class II molecules differ from that of class I molecules in that it shows a delay (1-3 hr) in transport from trans-Golgi to cell surface: here it intersects the endocytic route. Immunoelectron microscopy using anti-MHC antibodies revealed the existence of vesicular structures that were intensely labeled for class II molecules. It is proposed that at this site combination of class II molecules with processed antigen could occur.     

Endocytosis of MHC molecules by B cell-B lymphoma and B cell-T lymphoma hybrids

Different cells and different cell surface determinants of the same cells take up liposomes, bound to them via monoclonal antibodies, with variable efficiency. We have previously reported that T and B lymphocytes differ in the extent to which they take up liposomes bound to MHC class I molecules; T cells endocytose class I molecules rapidly, but B cells endocytose class I molecules much less efficiently, although their endocytosis of class II molecules is rapid. An approach toward understanding the molecular basis for this difference was made by evaluating the internalization patterns of somatic cell hybrids of B and T cells. Hybrid cells were constructed between LPS-stimulated purified B cell blasts from C57BL/6 mice (H-2b) and the HAT-sensitive AKR T lymphoma BW 5147 (H-2k). Hybrids between the BALB/c B lymphoma M12.4.1 (H-2d) and B cell LPS blasts from B10.BR (H-2k) mice were also evaluated. In all cases, for hybrid tumor cells, liposomes that were bound to class I molecules encoded by genes from the B cell donor were endocytosed as efficiently as liposomes bound to the class I molecules of the recipient lymphoid cell. T cell tumors efficiently internalized their own class I molecules and those donated by B cells; B cell tumors internalized liposomes that were bound to their own and the donor B cell class I molecules poorly. Thus, our results suggest that the internalization of an MHC molecule is not an intrinsic property of the molecule, but rather of the cell in which it is found.     

Comodulation of CD3 and CD4. Evidence for a specific association between CD4 and approximately 5% of the CD3:T cell receptor complexes on helper T lymphocytes

The aggregation of a specific class of lymphocyte surface molecules results in patching, capping, and surface modulation of the aggregated ligand. Both CD4, an associative recognition structure found on helper T lymphocytes, and CD3, a component of the T cell receptor complex, are members of this functional subgroup. When 125I-labeled monoclonal antibodies reactive with either CD4 (19Thy 5D7) or CD3 (RW24B6) were bound to T lymphocytes, the subsequent addition of goat anti-mouse Ig resulted in their rapid, temperature-dependent internalization. Whereas the binding of 125I-19Thy 5D7 (anti-CD4) was inhibited by greater than 90% in the presence of unlabeled 19Thy 5D7, no inhibition occurred in the presence of unlabeled antibody reactive with CD3 (RW28C8). We took advantage of the fact that these antibodies were of different isotypes (19Thy 5D7:IgG2a; RW28C8:IgGl) to determine whether the internalization of CD3 induced the comodulation of CD4. T lymphocytes preincubated with 125I-19Thy5D7 (anti-CD4) and unlabeled RA28C8 (anti-CD3) were treated with goat anti-mouse IgGl under conditions shown to quantitatively internalize CD3. After 1 h at 37 degrees C, T lymphocytes had internalized 10.5 +/- 2.6% (n = 3) of their antibody-bound cell surface CD4. After similar incubations with media alone or with goat anti-mouse IgGl in the absence of prebound RW28C8 (anti-CD3), no internalization of CD4 could be detected. Control antibodies reactive with CD45R (2H4, IgGl) also failed to induce the internalization of CD4. Similar results were obtained by using a helper T cell clone (T4C1) that internalized 9.6 +/- 2.8% (n = 3) of its antibody-bound cell surface CD4 in response to CD3 modulation. In a reciprocal experiment, 125I-anti-CD3 (RW24B6, IgG2b) was preincubated with T4Cl cells together with unlabeled anti-CD4 (12T4D11, IgG1) prior to the addition of goat anti-mouse IgGl. The quantitative modulation of CD4 induced the co-internalization of 4.6 +/- 0.6% (n = 3) of cell surface CD3. These results suggest that approximately 5% of the CD3:T cell receptor complexes on helper T lymphocytes are specifically associated with CD4. Furthermore, our results suggest that an average of two CD4 molecules associate with each CD3:T cell receptor complex.     

The influence of transferrin binding to L2C guinea pig leukemic lymphocytes on the endocytosis cycle kinetics of its receptor

The parameters regulating the internalization and recycling of transferrin-specific receptors were determined in guinea pig leukemic B lymphocytes, in the absence or presence of ligand. We show that after the cells were purified, 45-56% of the total receptors were on the cell surface. In the absence of transferrin, unoccupied receptors are quickly internalized (rate constant, 0.12 min-1) whereas their recycling is much slower (rate constant, 0.026 min-1). This difference between endocytosis and recycling rates leads to a balanced receptor distribution with only 22% of the total receptors outside after incubation of the cells for 20-30 min at 37 degrees C. The internalization rate of occupied receptors, measured in the presence of transferrin is faster (rate constant, 0.21 min-1) than that of unoccupied receptors calculated in the absence of transferrin (0.12 min-1; see above). On the other hand, mere binding of transferrin to its receptor, without internalization, arrested by cytoplasm acidification, is sufficient to induce a large increase (by a factor of seven) in the recycling rate of unoccupied internal receptors from 0.026 min-1 to 0.17 min-1. Thus, in these lymphocytes, transferrin mobilizes internal receptors by modifying the kinetic rates of internalization and recycling, leading to a new equilibrium between external and internal receptors.     

Inhibition of coated pit formation in Hep2 cells blocks the cytotoxicity of diphtheria toxin but not that of ricin toxin

It has been recently shown (Larkin, J. M., M. S. Brown, J. L. Goldstein, and R. G. W. Anderson, 1983, Cell, 33:273-285) that after a hypotonic shock followed by incubation in a K+-free medium, human fibroblasts arrest their coated pit formation and therefore arrest receptor-mediated endocytosis of low density lipoprotein. We have used this technique to study the endocytosis of transferrin, diphtheria toxin, and ricin toxin by three cell lines (Vero, Wi38/SV40, and Hep2 cells). Only Hep2 cells totally arrested internalization of [125I]transferrin, a ligand transported by coated pits and coated vesicles, after intracellular K+ depletion. Immunofluorescence studies using anti-clathrin antibodies showed that clathrin associated with the plasma membrane disappeared in Hep2 cells when the level of intracellular K+ was low. In the absence of functional coated pits, diphtheria toxin was unable to intoxicate Hep2 cells but the activity of ricin toxin was unaffected by this treatment. By measuring the rate of internalization of [125I]ricin toxin by Hep2 cells, with and without functional coated pits, we have shown that this labeled ligand was transported in both cases inside the cells. Hep2 cells with active coated pits internalized twice as much [125I]ricin toxin as Hep2 cells without coated pits. Entry of ricin toxin inside the cells was a slow process (8% of the bound toxin per 10 min at 37 degrees C) when compared to transferrin internalization (50% of the bound transferrin per 10 min at 37 degrees C). Using the indirect immunofluorescence technique on permeabilized cells, we have shown that Hep2 cells depleted in intracellular K+ accumulated ricin toxin in compartments that were predominantly localized around the cell nucleus. Our study indicates that in addition to the pathway of coated pits and coated vesicles used by diphtheria toxin and transferrin, another system of endocytosis for receptor-bound molecules takes place at the level of the cell membrane and is used by ricin toxin to enter the cytosol.     

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.     

DNA‐based probes for flow cytometry analysis of endocytosis and recycling

The internalization of proteins plays a key role in cell development, cell signaling and immunity. We have previously developed a specific hybridization internalization probe (SHIP) to quantitate the internalization of proteins and particles into cells. Herein, we extend the utility of SHIP to examine both the endocytosis and recycling of surface receptors using flow cytometry. SHIP was used to monitor endocytosis of membrane‐bound transferrin receptor (TFR) and its soluble ligand transferrin (TF). SHIP enabled measurements of the proportion of surface molecules internalized, the internalization kinetics and the proportion and rate of internalized molecules that recycle to the cell surface with time. Using this method, we have demonstrated the internalization and recycling of holo‐TF and an antibody against the TFR behave differently. This assay therefore highlights the implications of receptor internalization and recycling, where the internalization of the receptor‐antibody complex behaves differently to the receptor‐ligand complex. In addition, we observe distinct internalization patterns for these molecules expressed by different subpopulations of primary cells. SHIP provides a convenient and high throughput technique for analysis of trafficking parameters for both cell surface receptors and their ligands.      

Receptor-mediated endocytosis of transferrin in K562 cells

Human diferric transferrin binds to the surface of K562 cells, a human leukemic cell line. There are about 1.6 X 10(5) binding sites per cell surface, exhibiting a KD of about 10(-9) M. Upon warming cells to 37 degrees C there is a rapid increase in uptake to a steady state level of twice that obtained at 0 degree C. This is accounted for by internalization of the ligand as shown by the development of resistance to either acid wash or protease treatment of the ligand-cell association. After a minimum residency time of 4-5 min, undegraded transferrin is released from the cell. Internalization is rapid but is dependent upon cell surface occupancy; at occupancies of 20% or greater the rate coefficient is maximal at about 0.1-0.2 min-1. In the absence of externally added ligand only 50% of the internalized transferrin completes the cycle and is released to the medium with a rate coefficient of 0.05 min-1. The remaining transferrin can be released from the cell only by the addition of ligand, suggesting a tight coupling between cell surface binding, internalization, and release of internalized ligand. There is a loss of cell surface-binding capacity that accompanies transferrin internalization. At low (less than 50%) occupancy this loss is monotonic with the extent of internalization. Even at saturating levels of transferrin, the loss of surface receptors upon internalization never exceeds 60-70% of the initial binding capacity. This suggests that receptors enter the cell with ligand but are replaced so as to maintain a constant, albeit reduced, receptor number on the cell surface. In the absence of ligand, the cell surface receptor number returns at 37 degrees C. Neither sodium azide nor NH4Cl blocks internalization of ligand. However, they both prevent the release of transferrin from the cell thus halting the transferrin cycle. Excess ligand can overcome the block due to NH4Cl but not azide although the cycle is markedly slower. Iron is delivered to these cells by transferrin at 37 degrees C with a rate coefficient of 0.15 to 0.2 min-1. The iron is released from the transferrin and the majority is found in intracellular ferritin. There is a large internal receptor pool comprising 70 to 80% of the total cell receptors and this may be involved in maintaining the steady state iron uptake.     

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.     

Internalization of the fibronectin receptor is a constitutive process

Using a monoclonal antibody specific for the hamster fibronectin receptor (FnR), we have demonstrated that a portion of the CHO cell FnR population is constitutively endocytosed. Three independent techniques were used to study the internalization: 1) after saturation binding of an anti-FnR antibody (PB1) to cells at 4 degrees C, internalization was initiated by warming to 37 degrees C, and then acid/salt elution of membrane-bound ligand was used to quantitate the internalized 125I-PB1; 2) cell vesicular traffic was pharmacologically disrupted with monensin or chloroquine, and the subsequent reduction of the cell surface pool of FnR was monitored; and 3) selective immunoprecipitation was used to separate surface and internalized 125I-labeled FnR. These experiments indicate that about 30% of the cell surface FnR is endocytosed with a t1/2 of 7 min and that this internalization occurs regardless of the ligation state of the receptor. Other observations indicate that the larger fraction of the cell surface FnR pool (70-75%) is apparently shed from the cell upon ligation with antibody at 37 degrees C. This process occurs much more slowly than receptor internalization and leads to an overall reduction in the amount of cell surface FnR. Our results suggest physically or chemically distinct populations of FnR, one of which is unavailable for internalization and recycling.     

Cross-linking of plasmalemmal cholesterol in lymphocytes induces capping, membrane shedding, and endocytosis through coated pits.

By use of a nicked and biotinylated perfringolysin O (BCtheta), which binds to cholesterol specifically, we studied consequences of cross-linking cholesterol in lymphocytes. When bound with BCtheta and then with labeled avidin or streptavidin, capping occurred in most cells within 30 min at 37 degrees C. It was inhibited by cytochalasin D or NaN3, but not by nocodazole. When BCtheta-cholesterol was capped, Thy-1 and transferrin receptor, a GPI-anchored protein and a transmembrane protein, respectively, remained evenly distributed. By fluorescence and electron microscopy, a cluster of small vesicles bound with BCtheta were observed in the cap. They were then shed in the medium or internalized through coated pits. The result indicates that cross-linking of cholesterol in lymphocytes induces capping, but does not affect distribution of membrane proteins, and that the capped cholesterol molecules are either shed as vesicles or endocytosed.     

Emergence of a surface immunoglobulin recycling process during B lymphocyte differentiation

Surface immunoglobulin (Ig)-mediated endocytosis has been investigated in rat B lymphocytes and plasma cells, using horseradish peroxidase (HRP)-labeled sheep anti-rat Ig Fab' fragment of antibody and HRP as monomeric ligands, respectively. Quantitative estimates of HRP activity associated either with plasma membrane or with endomembrane compartments were made in several experimental conditions. Binding of HRP-conjugate on B lymphocytes was followed by its endocytosis in combination with surface Ig, as shown by the progressive disappearance of plasma membrane-associated HRP activity. Between 1 and 6 h at 37 degrees C in presence of conjugate the total amount of cell-associated activity was constant. These results indicate that during this time no reappearance of surface Ig occurred by neosynthesis, by the expression of an intracellular pool or by the recycling in a free form of the previously internalized molecules. On the contrary, at saturating doses, internalization of HRP by anti-HRP plasma cells increased linearly with time at 37 degrees C in presence of antigen, when, during the same time, the plasma membrane HRP-binding capacity remained constant. Cycloheximide did not affect continuous HRP uptake. The existence of a large intracellular pool of receptors has been ruled out by experiments of removal of binding sites with pronase. In addition, monensin caused a progressive decrease in the number of surface receptors on plasma cells but not on B lymphocytes. Our data then indicate that, unlike B lymphocytes, plasma cells were able to recycle their surface Ig.     

Endocytosis and de novo expression of major histocompatibility complex encoded class I molecules: kinetic and ultrastructural studies

The endocytic pathway and expression of the major histocompatibility complex encoded class I molecule H-2Kk was investigated in murine fibroblasts. Internalization of H-2K molecules did not occur constitutively. Endocytosis of the molecules was induced by addition of multivalent ligands such as rabbit anti-mouse immunoglobulin serum or protein A-bearing liposomes to cells pretreated with anti-H-2Kk antibodies. The complete removal of H-2K molecules took about 5 h at 37 degrees C and was not inhibited by the lysosomotropic agent NH4Cl or the protein synthesis inhibitor cycloheximide. When targeted liposomes that contained carboxyfluorescein at a self-quenched concentration were directed against H-2K molecules, the cells became highly fluorescent after 30 min: a consequence of carboxyfluorescein release from the liposomes. This process was inhibited by NH4Cl but not by cycloheximide, suggesting internalization of H-2K molecules into acidic intracellular compartments. The endocytic pathway of liposomes directed against H-2K molecules and the subcellular compartments involved in this process were investigated with targeted liposomes containing horseradish peroxidase. By electron microscopy, the endocytic process was shown to start very rapidly (1-2 min) and involved uncoated cell surface invaginations. The cytoplasmic uncoated vesicles fused together into larger vacuoles containing concentrated liposomes and by 1 h, liposomes began to be destroyed in lysosomal compartments. Within 4 h, 90% of liposomes were lysed inside the cell. The fate of radiolabeled anti-H-2K antibody was also investigated. Degradation of the antibody occurred only when cross-linked with a second layer of antibody, beginning after 2 h and becoming more pronounced after 20 h of incubation. The original cell surface abundance of H-2K molecules was reestablished after 5 to 7 h. During this time neither NH4Cl nor cycloheximide had any effect on the cell surface expression of the molecule. However, after a second cycle of internalization, cells incubated with cycloheximide no longer expressed these molecules. These results suggested that H-2K molecules were not recycled back to the surface after internalization but were degraded in lysosomal compartments together with their ligand. Preexisting molecules, already present in intracellular pools, were expressed to replace them. By immunoprecipitation of metabolically labeled intracellular and surface H-2K molecules, we observed an intracellular pool of H-2K of about 70 to 80% of the total cellular H-2K.     

Insertion and internalization of vasoactive intestinal peptide (VIP) receptors in murine CD4 T lymphocytes.

The specific binding of vasoactive intestinal peptide (VIP) to murine lymphocytes was investigated. CD4 T cells from mesenteric lymph nodes (MLN) bound more 125I-VIP than did unseparated MLN lymphocytes at 37 degrees C, but not at 4 degrees C. The differences between the amount of 125I-VIP bound by the CD4 T cells and unseparated MLN lymphocytes at 37 degrees C depended upon a difference in the amount of the ligand that was internalized by the cells. The rate of insertion of unoccupied VIP receptors from the cytoplasm into the cell membrane (370 receptors/cell/min), the rate constants for internalization of ligand occupied VIP receptors (0.55 min-1) and unoccupied VIP receptors (0.11 min-1), and the rate constant for the elimination of internalized VIP (0.07 min-1) by CD4 T cells were evaluated. These results provide new understanding of the behaviour of VIP receptors on lymphocytes and indicate a mechanism by which CD4 T lymphocytes can homologously regulate their surface expression of VIP receptors in the presence of ambient VIP.     

The asialoglycoprotein receptor internalizes and recycles independently of the transferrin and insulin receptors

Receptor-mediated endocytosis of specific ligands is mediated through clustering of receptor-ligand complexes in coated pits on the cell surface, followed by internalization of the complex into endocytic vesicles. We show that internalization of asialoglycoprotein by HepG2 hepatoma cells is accompanied by a rapid (t1/2 = 0.5-1 min) depletion of surface asialoglycoprotein receptors. This is followed by a rapid (t1/2 = 2-4 min) reappearance of surface receptors; most of these originate from endocytosed cell-surface receptors. The loss and reappearance of asialoglycoprotein receptors is specific, and depends on prebinding of ligand to its receptor. HepG2 cells also contain abundant receptors for both insulin and transferrin. Endocytosis of asialoglycoprotein and its receptor has no effect on the number of surface binding sites for transferrin or insulin. We conclude that binding of asialoglycoprotein to its surface receptor triggers a rapid and specific endocytosis of the receptor-ligand complex, probably due to a clustering in clathrin-coated pits or vesicles.     

Novel receptor-mediated internalization of interleukin 2 in B cells

Novel IL-2-binding molecules (p70 and p75) mediating internalization and degradation of IL-2 were examined by employing a human B lymphoblastoid line, SKW6-4 cells. High concentrations of IL-2 induced IgM secretion in these cells through a receptor distinct from Tac antigen. The acid-wash technique revealed that more than 60% of 125I-labeled IL-2 bound to the cells became acid-unremovable in the first 30 min of incubation at 37 degrees C and degradation products of 125I-IL-2 increased after 30 min of incubation. Treatment of the cells with NaN3 buffer inhibited the appearance of acid-unremovable 125I-IL-2, suggesting that acid-unremovable 125I-IL-2 was not due to fluid-phase pinocytosis but due to internalization. Loss of labeled bands by incubation of cells with 125I-IL-2 at 37 degrees C before affinity cross-linking demonstrated that 125I-IL-2 was internalized via novel IL-2-binding molecules. These results suggest that novel IL-2-binding molecules are responsible for internalization and may mediate signal transduction in B cells in the absence of Tac antigen.     

Dynamics of interleukin-6 internalization and degradation in rat hepatocytes.

We have investigated the dissociation, internalization, and degradation of 125I-interleukin-6 (125I-IL-6) by primary rat hepatocytes. Temperature shift experiments following saturation binding of 125I-IL-6 to cell surface receptors in hepatocytes showed a rapid loss of surface-bound 125I-IL-6 (t1/2 = 15 min), concomitant with a rapid rise in internalized radiolabeled ligand. After reaching a maximum by 30 min at 37 degrees C, the level of internalized 125I-IL-6 decreased with time and appeared in the culture media in a non-trichloroacetic acid-precipitable (degraded) state. The addition of the lysosomotropic agent chloroquine inhibited this receptor-mediated degradation of IL-6 without affecting ligand internalization. Polyacrylamide gel electrophoresis analysis of internalized 125I-IL-6 confirms these results. Additionally, we show that the IL-6.IL-6 receptor complex is stable, and dissociation of these two molecular species occurs at a pH below 5.0. In contrast to published results, data presented in this study clearly indicate that IL-6 is rapidly internalized and degraded within hepatocytes by a receptor-mediated mechanism.