Acidification of the cytosol inhibits endocytosis from coated pits

Acidification of the cytosol of a number of different cell lines strongly reduced the endocytic uptake of transferrin and epidermal growth factor. The number of transferrin binding sites at the cell surface was increased in acidified cells. Electron microscopic studies showed that the number of coated pits at the cell surface was not reduced in cells with acidified cytosol. Experiments with transferrin-horseradish peroxidase conjugates and a monoclonal anti-transferrin receptor antibody demonstrated that transferrin receptors were present in approximately 75% of the coated pits both in control cells and in cells with acidified cytosol. The data therefore indicate that the reason for the reduced endocytic uptake of transferrin at internal pH less than 6.5 is an inhibition of the pinching off of coated vesicles. In contrast, acidification of the cytosol had only little effect on the uptake of ricin and the fluid phase marker lucifer yellow. Ricin endocytosed by cells with acidified cytosol exhibited full toxic effect on the cells. Although the pathway of this uptake in acidified cells remains uncertain, some coated pits may still be involved. However, the data are also consistent with the possibility that an alternative endocytic pathway involving smooth (uncoated) pits exists.     

Identification of free coated pinocytic vesicles in Swiss 3T3 cells.

Whether or not free coated vesicles are involved during internalization of ligands bound to the receptors of coated pits is controversial. Free coated vesicles cannot be identified with certainty in random individual thin sections - reconstructions based on consecutive thin sections are required. The thickness of the sections determines the reliability of such reconstructions. In the present study, serial section electron microscopy was applied to Swiss 3T3 cells and the topographical resolution yielded by 80 nm and 20 nm sections was compared. Swiss 3T3 cells in monolayer at 37 degrees C were exposed for 5 min to cationized ferritin (CF) which is a marker of pinocytic vesicles. Subsequently the cells were fixed, pelleted and further processed for electron microscopy. The results showed that reconstructions of coated CF-labeled structures based on consecutive sections of an average thickness of approximately 80 nm could not be performed with certainty. A substantial fraction (25%) of the examined profiles appeared to be free vesicles, but narrow surface connections could easily have been missed in these thick sections. The series of the much thinner 20 nm sections provided a better resolution allowing the narrowest surface connections to be identified. Accordingly, the number of truly free, coated vesicles was much lower than the number of apparently free vesicles in the thick sections. However, free coated vesicles labeled with CF were identified in the consecutive 20 nm sections (4% of the examined profiles).     

Serial section analysis of coated pits and coated vesicles in soybean protoplasts

Divergent viewpoints have been expressed regarding the existence of free coated vesicles in animal cells; this question has not been carefully addressed with plant tissues. Soybean suspension culture protoplasts were exposed to cationized ferritin (CF) for short times to label coated pits and coated vesicles. A serial section analysis did not reveal deep coated pits with long necks as reported in animal cells. Serial sections clearly demonstrated CF-labelled coated vesicles to be separate organelles and is consistent with the idea that they transfer CF from coated pits to other cytoplasmic organelles during endocytosis.     

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.     

Formation of coated vesicles from coated pits in broken A431 cells

Biochemical and morphological techniques were used to demonstrate the early steps in the endocytosis of transferrin in broken A431 cells. After binding 125I-transferrin, the cells were broken by scraping and then warmed. 125I-transferrin became inaccessible to exogenous anti- transferrin antibody providing a measure of the internalization process. Parallel morphological experiments using transferrin coupled to horseradish peroxidase confirmed internalization in broken cells. The process was characterized and compared with endocytosis in intact cells and showed many similar features. The system was used to show that both the appearance of new coated pits and the scission of coated pits to form coated vesicles were dependent on the addition of cytosol and ATP whereas invagination of pits was dependent on neither.     

Co-localization of 125I-epidermal growth factor and ferritin-low density lipoprotein in coated pits: a quantitative electron microscopic study in normal and mutant human fibroblasts

Low density lipoprotein (LDL) and epidermal growth factor (EGF) bind to receptors on the surface of human fibroblasts and are internalized in coated vesicles. Each of the ligands has been studied separately by electron microscopy in human fibroblasts using ferritin-LDL as one visual probe and 125I-EGF as a second visual probe. A mutant strain of human fibroblasts (J.D.) has been described in which LDL does not localize to coated pits and hence is not internalized. Because LDL and EGF do not compete with each other for binding, in the current studies we coincubated the two ligands with normal and mutant cells to visualize their cellular fates. In normal fibroblasts ferritin-LDL and 125I-EGF both bound preferentially to coated pits at 4 degrees C and both ligands were internalized into endocytotic vesicles and lysosomes. Quantitative studies in normal cells showed that 75% of the coated pits and vesicles that contained 125I-EGF also contained ferritin-LDL, indicating that both ligands enter the cell through the same endocytotic vesicles. In the LDL internalization-mutant J.D. cells, ferritin-LDL did not localize in coated pits and was not internalized, but 125I-EGF bound to coated pits and was internalized just as in normal fibroblasts.     

Stage-specific assays for coated pit formation and coated vesicle budding in vitro

Internalization of biotin-S-S-125I-transferrin (125I-BSST) into semiintact A431 cells were assessed by two different criteria which have allowed us to distinguish partial reactions in the complex overall process of receptor-mediated endocytosis. Early events resulting in the sequestration of ligand into deeply invaginated coated pits were measured by inaccessibility of 125I-BSST to exogenously added antibodies. Later events involving coated vesicle budding and membrane fission were measured by resistance of 125I-BSST to reduction by the membrane impermeant-reducing agent, MesNa. Acquisition of Ab inaccessibility occurred very efficiently in this cell-free system (approximately 50% of total cell-associated 125I-BSST became inaccessible) and could be inhibited by anti-clathrin mAbs and by antibodies directed against the cytoplasmic domain of the transferrin-receptor. In contrast, acquisition of MesNa resistance occurred less efficiently (approximately 10-20% of total cell-associated 125I-BSST) and showed differential sensitivity to inhibition by anti-clathrin and anti-transferrin receptor mAbs. Both partial reactions were stimulated by ATP and cytosol; indicating at least two ATP-requiring events in receptor-mediated endocytosis. The temperature dependence of both reactions was similar to that for 125I-BSST internalization in intact cells with no activity being observed below 10 degrees C. Morphological studies using gold-labeled ligands confirmed that internalization of transferrin receptors into semiintact A431 cell occurred via coated pits and coated vesicles and resulted in delivery of ligand to endosomal structures.     

Apical and basolateral coated pits of MDCK cells differ in their rates of maturation into coated vesicles, but not in the ability to distinguish between mutant hemagglutinin proteins with different internalization signals

In polarized epithelial MDCK cells, all known endogenous endocytic receptors are found on the basolateral domain. The influenza virus hemagglutinin (HA) which is normally sorted to the apical plasma membrane, can be converted to a basolateral protein by specific mutations in its short cytoplasmic domain that also create internalization signals. For some of these mutations, sorting to the basolateral surface is incomplete, allowing internalization of two proteins that differ by a single amino acid of the internalization signal to be compared at both the apical and basolateral surfaces of MDCK cells. The rates of internalization of HA-Y543 and HA-Y543,R546 from the basolateral surface of polarized MDCK cells resembled those in nonpolarized cells, whereas their rates of internalization from the apical cell surface were fivefold slower. However, HA-Y543,R546 was internalized approximately threefold faster than HA-Y543 at both membrane domains, indicating that apical endocytic pits in polarized MDCK cells retained the ability to discriminate between different internalization signals. Slower internalization from the apical surface could not be explained by a limiting number of coated pits: apical membrane contained 0.7 as many coated pits per cell cross-section as did basolateral membranes. 10-14% of HA-Y543 at the apical surface of polarized MDCK cells was found in coated pits, a percentage not significantly different from that observed in apical coated pits of nonpolarized MDCK cells, where internalization was fivefold faster. Thus, there was no lack of binding sites for HA-Y543 in apical coated pits of polarized cells. However, at the apical surface many more shallow pits, and fewer deep, mature pits, were observed than were seen at the basolateral. These results suggest that the slower internalization at the apical surface is due to slower maturation of coated pits, and not to a difference in recognition of internalization signals.     

Coat proteins isolated from clathrin coated vesicles can assemble into coated pits

Isolated human fibroblast plasma membranes that were attached by their extracellular surface to a solid substratum contained numerous clathrin coated pits that could be removed with a high pH buffer (Moore, M.S., D.T. Mahaffey, F.M. Brodsky, and R.G.W. Anderson. 1987. Science [Wash. DC]. 236:558-563). When these membranes were incubated with coat proteins extracted from purified bovine coated vesicles, new coated pits formed that were indistinguishable from native coated pits. Assembly was dependent on the concentration of coat protein with half maximal assembly occurring at 7 micrograms/ml. Assembly was only slightly affected by the presence of divalent cations. Whereas normal appearing lattices formed in a low ionic strength buffer, when assembly was carried out in a low pH buffer, few coated pits were evident but numerous small clathrin cages decorated the membrane. Coated pits did not form randomly on the surface; instead, they assembled at differentiated regions of membrane that could be distinguished in carbon/platinum replicas of frozen and etched membranes by the presence of numerous particles clustered into patches the size and shape of a coated pit.     

Serial-section analysis of coated pits and vesicles involved in adsorptive pinocytosis in cultured fibroblasts

We have examined, by analyzing thin (15-20 nm) serial sections, whether coated pits involved in adsorptive pinocytosis in cultured fibroblasts give rise to free coated vesicles or represent permanently surface-associated structures from the neck of which uncoated receptosomes pinch off and carry ligand into the cell. Human skin fibroblasts and mouse L-929 fibroblasts were incubated with cationized ferritin (CF), a ligand known to bind to coated pit regions, at 37 degrees C before fixation. In thin sections, CF was found in coated vesicular profiles within the cytoplasm. Serial sections revealed that whereas many of these coated profiles communicated with the cell surface, thus representing pits, about 10% in L-cells and 36% in skin fibroblasts were actually free coated vesicles. Moreover, evidence for uncoated vesicular structures (receptosomes) budding off from the coated pits was not obtained. We therefore conclude that coated pits do pinch off from the plasma membrane to form free, coated vesicles (pinosomes).     

Receptor-mediated endocytosis in cultured fibroblasts: cryptic coated pits and the formation of receptosomes

Concentrative receptor-mediated endocytosis of many specific ligands by cultured fibroblasts occurs through the coated pit-receptosome pathway. The formation of receptosomes was studied using two impermeant electron-dense labels for the cell surface, ruthenium red and concanavalin A-horseradish peroxidase. These studies show that at 4 degrees C, virtually all coated structures near the plasma membrane are in communication with the cell surface, and are not isolated coated vesicles. On warming cells to 37 degrees C for only 1 minute, a major portion of these structures become cryptic, that is, not labeled by these surface markers. However, on cooling cells immediately back to 4 degrees C, virtually all of these structures are again in communication with the surface. Many images showed that membrane of these cryptic pits to be continuous with the cell surface when caught in the appropriate plane of section; often there was a very narrow entrance that excluded extracellular label. At 37 degrees C, receptosomes could be occasionally seen forming as an invagination of membrane adjacent to the coated region. Mechanisms by which receptosomes may form and other evidence demonstrating the failure of coated pits to pinch off to form isolated coated vesicles during endocytosis are discussed.     

Induction of mutant dynamin specifically blocks endocytic coated vesicle formation

Dynamin is the mammalian homologue to the Drosophila shibire gene product. Mutations in this 100-kD GTPase cause a pleiotropic defect in endocytosis. To further investigate its role, we generated stable HeLa cell lines expressing either wild-type dynamin or a mutant defective in GTP binding and hydrolysis driven by a tightly controlled, tetracycline- inducible promoter. Overexpression of wild-type dynamin had no effect. In contrast, coated pits failed to become constricted and coated vesicles failed to bud in cells overexpressing mutant dynamin so that endocytosis via both transferrin (Tfn) and EGF receptors was potently inhibited. Coated pit assembly, invagination, and the recruitment of receptors into coated pits were unaffected. Other vesicular transport pathways, including Tfn receptor recycling, Tfn receptor biosynthesis, and cathepsin D transport to lysosomes via Golgi-derived coated vesicles, were unaffected. Bulk fluid-phase uptake also continued at the same initial rates as wild type. EM immunolocalization showed that membrane-bound dynamin was specifically associated with clathrin-coated pits on the plasma membrane. Dynamin was also associated with isolated coated vesicles, suggesting that it plays a role in vesicle budding. Like the Drosophila shibire mutant, HeLa cells overexpressing mutant dynamin accumulated long tubules, many of which remained connected to the plasma membrane. We conclude that dynamin is specifically required for endocytic coated vesicle formation, and that its GTP binding and hydrolysis activities are required to form constricted coated pits and, subsequently, for coated vesicle budding.     

A Study of the Mechanism of Internalisation of Tetanus Toxin by Primary Mouse Spinal Cord Cultures

The fate of tetanus toxin bound to neuronal cells at 0 degree C was followed using an anti-toxin 125I-protein A assay. About 50% of surface-bound toxin disappeared within 5 min of warming cells to 37 degrees C. Experiments with 125I-toxin showed that much of this loss was due to dissociation of bound toxin into the medium. Some toxin was however rapidly internalised, and could be detected only by permeabilizing cells with Triton X-100 prior to assay. To investigate the mechanism of internalisation, tetanus toxin was adsorbed to colloidal gold. Toxin-gold was shown to be stable, and to recognise the same receptor(s) as free toxin. Quantitation of the distribution of toxin-gold particles bound to the cell body at 4 degrees C showed that it was concentrated in coated pits. After 5 min at 37 degrees C, toxin-gold appeared in coated vesicles, endosomes, and tubules. After 15 min, it was found largely in endosomes, and at 30 min in multivesicular bodies. The involvement of coated pits in internalisation of tetanus toxin, but not cholera toxin, was confirmed using the free toxins, anti-toxins, and protein A-gold. Toxin-gold also entered nerve terminals and axons via coated pits, accumulating in synaptic vesicles and intraaxonal uncoated vesicles, respectively.     

Morphometric analysis of coated pits and vesicles in the proximal and distal caput epididymidis

A morphometric analysis of coated and uncoated structures found in the apical portion of principal cells from both the proximal and distal caput epididymidis has been carried out. Almost all endocytic, coated vesicles are found within 1 micron of the luminal surface of principal cells and the volume fraction of these and of uncoated vesicles is much greater in the proximal caput epididymidis. A serial section analysis indicated that many coated "vesicles" are tangentially sectioned coated pits and that a complex network of interconnected vesicular and tubular structures exists in the apical cytoplasm. Efferent duct ligation has no effect on the number of size of large coated and uncoated vesicles in either the proximal or distal caput epididymidis, indicating that substances delivered to principal cells from the lumen are not required to maintain the endocytic machinery. However, this treatment does result in a considerable increase in the number of large coated vesicles associated with the basal surface of principal cells from the proximal but not the distal caput epididymidis. The volume fraction of small, presumably exocytic, coated vesicles is significantly greater in the apical cytoplasm of cells from the distal caput epididymidis in control animals. Efferent duct ligation results in a significant increase in the volume fraction of these vesicles in the proximal but not distal caput epididymidis. These results show that there are marked differences in structure among principal cells from these two regions of the epididymis and that this may reflect differences in control and function.     

Inhibition of endocytosis from coated pits by acidification of the cytosol

Binding and endocytosis of the ligands transferrin, epidermal growth factor (EGF), and ricin were measured in a number of different cell lines after treatment of cells with compounds that react with SH-groups and under conditions where the cytosolic pH was lowered. N-ethylmalemide and diamide irreversibly inhibited endocytosis of all ligands tested, whereas low pH in the cytosol strongly inhibited endocytosis of transferrin and EGF. Data obtained by electron microscopy indicated that the formation of coated vesicles from coated pits is inhibited in acidified cells. Entry of ricin was much less affected, and ricin endocytosed under these conditions was able to intoxicate the cells. At low pH in the cytosol there was a calcium-dependent increase in the number of transferrin receptors at the cell surface. The increase was even larger in the presence of the calcium ionophore A23187, whereas it was completely blocked by the calmodulin antagonists trifluoperazine and W7. The results show that endocytosis from coated pits can be inhibited in a reversible way by acidification of the cytosol and they suggest that a second pathway of endocytosis exists, possibly involving formation of vesicles from uncoated areas of the membrane.     

Depletion of intracellular potassium disrupts coated pits and reversibly inhibits cell polarization during fibroblast spreading

To learn more about the possible role of the coated pits endocytic pathway in cell adhesion, we studied attachment and spreading of fibroblasts whose coated pits were disrupted by depletion of intercellular potassium. Fibroblasts incubated in suspension in potassium-free medium lost 80% of their intracellular potassium within 10 min and showed disrupted coated pits based on fluorescence staining of clathrin. Potassium-depleted cells attached and spread on fibronectin-coated substrata over the same time course (15 min-2 h) as control cells. Unlike controls, however, potassium-depleted fibroblasts attained a radial morphology with circumferentially organized actin filament bundles and were unable to make the transition to a polarized morphology with stress fibers. In the radially spread fibroblasts, fibronectin receptors and vinculin colocalized in focal adhesion sites and appeared to be membrane insertion points for circumferentially arranged actin filament bundles, but these sites were much smaller than the focal adhesion plaques in polarized cells. The effects of potassium depletion on cell adhesion were reversible. Within 1 h after switching K(+)-depleted fibroblasts to medium containing KCl, cells developed a polarized morphology with actin stress fibers inserting into focal adhesion plaques. Coated pits also reformed on the cell surface during this time. Because formation of focal adhesion plaques preceded reappearance of clathrin-coated pits at the cell margins, it seems unlikely that coated pits play a direct role in adhesion plaque assembly. Polarization of fibroblasts upon addition of KCl was inhibited by ouabain showing that intracellular potassium was required for activity. Polarization also was inhibited when potassium-depleted cells were switched to potassium-containing medium under hypertonic or acidified conditions, both of which have been shown to inhibit receptor- mediated endocytosis. Our results suggest that the coated pit endocytic pathway is not required for initial attachment, spreading, and formation of focal adhesions by fibroblasts, but may play a role in cell polarization.     

Potassium-dependent assembly of coated pits: new coated pits form as planar clathrin lattices

Previous studies have shown that when human fibroblasts are depleted of intracellular K+, coated pits disappear from the cell surface and the receptor-mediated endocytosis of low density lipoprotein (LDL) is inhibited. We have now used the K+ depletion protocol to study several aspects of coated pit function. First, since coated pits rapidly form when K+-depleted fibroblasts are incubated in the presence of 10 mM KCl, we studied the sequence of assembly of coated pits as visualized in carbon-platinum replicas of inner membrane surfaces from cells that had been incubated in the presence of K+ for various times. New coated pits initially appeared as planar clathrin lattices that increased in size by the formation of polygons at the margin of the lattice. Once the lattice reached a critical size it invaginated to form coated vesicles. Second, we determined that LDL-ferritin can induce clustering of LDL receptors over noncoated membrane on the surface of K+-depleted fibroblasts; however, when these cells are subsequently incubated in the presence of K+, these clusters become associated with newly formed coated pits and are internalized. Finally, we determined that K+ depletion inhibits the assembly of coated pits, but that existing coated pits in K+-depleted cells are able to internalize LDL. These results suggest that the clathrin lattice of coated pits is actively involved in membrane shape change during endocytosis and that the structural proteins of the lattice are cyclically assembled and disassembled in the process.     

alpha 2 Macroglobulin binding to the plasma membrane of cultured fibroblasts. Diffuse binding followed by clustering in coated regions

Using transmission electron microscopy, we have studied the interaction of alpha 2 macroglobulin (alpha 2 M) with the surface of cultured fibroblasts. When cells were incubated for 2 h at 4 degrees C with ferritin-conjugated alpha 2 M, approximately 90% of the alpha 2 M was diffusely distributed on the cell surface, and the other 10% was concentrated in "coated" pits. A pattern of diffuse labeling with some clustering in "coated" pits was also obtained when cells were incubated for 5 min at 4 degrees C with alpha 2 M, fixed with glutaraldehyde, and the alpha 2 M was localized with affinity-purified, peroxidase-labeled antibody to alpha 2 M. Experiments in which cells were fixed with 0.2% paraformaldehyde before incubation with alpha 2 M showed that the native distribution of alpha 2 M receptors was entirely diffuse without significant clustering in "coated" pits. This indicates that some redistribution of the alpha 2 M-receptor complexes into clusters occurred even at 4 degrees C. In experiments with concanavalin A(Con A), we found that some of the Con A clustered in coated regions of the membrane and was internalized in coated vesicles, but much of the Con A was directly internalized in uncoated vesicles or pinosomes. We conclude that unoccupied alpha 2 M receptors are diffusely distributed on the cell surface. When alpha 2 M-receptor complexes are formed, they rapidly cluster in coated regions or pits in the plasma membrane and subsequently are internalized in coated vesicles. Because insulin and epidermal growth factor are internalized in the same structures as alpha 2 M (Maxfield, F.R., J. Schlessinger, Y. Schechter, I. Pastan, and M.C. Willingham. 1978. Cell, 14: 805--810.), we suggest that all peptide hormones, as well as other proteins that enter the cell by receptor-mediated endocytosis, follow this same pathway.     

Cholinergic stimulation of chromaffin cells induces rapid coating of the plasma membrane

Stimulation of primary bovine adrenal chromaffin cells by carbachol produced a 6-fold increase in cell surface coated pits within 30 s. This coat appeared not to be recruited from a preformed pool at the plasma membrane, but from some pool transparent to electron microscopy. The number of coated pits appeared to decrease rapidly after 1 to 2 min stimulation, but processing for electron microscopy using tannic acid to enhance contrast indicated that both coated pits and closed coated vesicles were increased relative to unstimulated cells for up to 30 min. Analyses of purified adrenal medulla coated vesicles showed a lipid composition close to that expected for cell surface membrane, but there were only trace levels of plasma membrane marker enzymes. Coated vesicles contained significant amounts of both membrane and content proteins characteristic of the chromaffin granule, suggesting that medulla coated vesicles preferentially carry secretion granule proteins. The kinetics of stimulus-dependent formation of coated membrane in the cortical zone of chromaffin cells is closely similar to that observed for secretion granule membrane retrieval.     

Evidence from lateral mobility studies for dynamic interactions of a mutant influenza hemagglutinin with coated pits

Replacement of cysteine at position 543 by tyrosine in the influenza virus hemagglutinin (HA) protein enables the endocytosis of the mutant protein (Tyr 543) through coated pits (Lazarovits, J., and M. G. Roth. 1988. Cell. 53:743-752). To investigate the interactions between Tyr 543 and the clathrin coats in the plasma membrane of live cells, we performed fluorescence photobleaching recovery measurements comparing the lateral mobilities of Tyr 543 (which enters coated pits) and wild-type HA (HA wt, which is excluded from coated pits), following their expression in CV-1 cells by SV-40 vectors. While both proteins exhibited the same high mobile fractions, the lateral diffusion rate of Tyr 543 was significantly slower than that of HA wt. Incubation of the cells in a sucrose-containing hypertonic medium, a treatment that disperses the membrane-associated coated pits, resulted in similar lateral mobilities for Tyr 543 and HA wt. These findings indicate that the lateral motion of Tyr 543 (but not of HA wt) is inhibited by transient interactions with coated pits (which are essentially immobile on the time scale of the lateral mobility measurements). Acidification of the cytoplasm by prepulsing the cells with NH4Cl (a treatment that arrests the pinching-off of coated vesicles from the plasma membrane and alters the clathrin lattice morphology) led to immobilization of a significant part of the Tyr 543 molecules, presumably due to their entrapment in coated pits for the entire duration of the lateral mobility measurement. Furthermore, in both untreated and cytosol-acidified cells, the restrictions on Tyr 543 mobility were less pronounced in the cold, suggesting that the mobility-restricting interactions are temperature dependent and become weaker at low temperatures. From these studies we conclude the following. (a) Lateral mobility measurements are capable of detecting interactions of transmembrane proteins with coated pits in intact cells. (b) The interactions of Tyr 543 with coated pits are dynamic, involving multiple entries of Tyr 543 molecules into and out of coated pits. (c) Alterations in the clathrin lattice structure can modulate the above interactions.