Localized endocytosis in tobacco pollen tubes: visualisation and dynamics of membrane retrieval by a fluorescent phospholipid

Two modes of endocytosis are known to occur in eucaryotic cells: fluid phase and receptor-mediated endocytosis. Fluid-phase endocytosis in plant cells resembles the retrieval of excess plasma membrane material previously incorporated by exocytosis. Pollen tubes need to carry out strong membrane retrieval due to their fast polar tip growth. Plasma membrane labelling of pollen tubes, grown in suspension, was achieved by the incorporation of a fluorescently modified phospholipid, 1,2-bis-(4,4-difluoro-5,7-dimethyl-4-bora-3a,4a-diaza-s-indacene-3-undecanoyl)-sn-glycero-3-phosphocholine (20 μM) and measured with a confocal laser-scanning microscope. Time course experiments revealed a highly localised and relatively fast plasma membrane retrieval below the tip within the first 5 min after phospholipid application. The retrieved fluorescent plasma membrane was quickly re-integrated into parts of the endomembrane pool and then redistributed to the pollen tube base and very tip of the apex, with the exception of the cortical endoplasmic reticulum (ER) and the mitochondria even after 1-h incubation period. Low temperature (10°C) and the actin filament depolymerizing cytochalasin D (2 μM) completely abolished plasma membrane retrieval, whereas the microtubule destabilizing herbicide oryzalin (1 μM) had no effect. Our results provide strong support for a highly localised endocytotic pathway in tobacco pollen tubes. Passive uptake of bis-Bodipy FL C₁₁-phosphocholine by mere penetration can be excluded. It is a valuable alternative to the styryl dyes often used in endocytotic studies, and may also be used to follow lipid turnover because membrane flow of labelled membranes occurs apparently not in a default manner as ascertained by its fast distribution. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Guard cells undergo constitutive and pressure-driven membrane turnover

Summary. During stomatal movement, guard cells undergo large and reversible changes in cell volume and consequently surface area. These alterations in surface area require addition and removal of plasma membrane material. How this is achieved is largely unknown. Here we summarize recent studies of membrane turnover in guard cells using electrophysiology and fluorescent imaging techniques. The results implicate that membrane turnover in guard cells and most likely in plant cells in general is sensitive to changes in membrane tension. We suggest that this provides a mechanism for the adaptation of surface area of guard cells to osmotically driven changes in cell volume. In addition, guard cells also exhibit constitutive membrane turnover. Constitutive and pressure-driven membrane turnover were found to be associated with addition and removal of K⁺ channels. This implies that some of the exo- and endocytic vesicles carry K⁺ channels. Together the results demonstrate that exo- and endocytosis is an essential process in guard cell functioning. Correspondence and reprints: Institute of Botany, Darmstadt University of Technology, Schnittspahnstrasse 3, 64287 Darmstadt, Federal Republic of Germany.     

Flow and shuttle of plasma membrane during endocytosis

A striking feature of endocytosis is the large amount of surface membrane that is brought into the cells through the formation of endocytic vesicles. Little is known about the fate of this membrane material. It is implausible that it would be destroyed in lysosomes, as the rate of turnover of the constituents of plasma membrane is much too low with respect to the rate of endocytosis in all cells studied so far. Conversely, plasma membrane fragments, internalized by endocytosis cannot merely be incorporated in lysosomes, as these organelles have been shown to maintain their size, despite continuous and active endocytosis. We present evidence that plasma membrane antigens, detected by means of specific antibodies, are internalized during endocytosis and reach lysosomes. They are thereafter returned back to cell surface. These results indicate the existence of a shuttle of membrane elements between the cell surface and lysosomes.     

How does plasma membrane surface area accommodate alterations in guard cell volume during stomatal closing?

During stomatal movement, guard cells undergo considerable and repetitive variations in cell volume and consequently surface area over a period of minutes. Due to limited stretching capability of the plasma membrane, alterations in the surface area must accommodate the volume changes through membrane turnover. Using fluorescence imaging and electrophysiology techniques, extensive studies imply that endocytosis may be a critical mechanism for the plasma membrane turnover. In contrast to the conventional studies, using transmission electronic microscope in combination with laser confocal microscope so that the membrane turnover can be detected without a resolution limitation, our works, recently published in the Journal of Experimental Botany, has provided strong evidences that excretion and folding of plasma membrane are critical for the accommodation of the cell volume alterations in intact guard cells in Vicia faba L. These results have opened a new perspective on the mechanism for the membrane turnover during stomatal movement. In this addendum, we further discuss some key issues about the mechanisms for the accommodation of the cell volume alterations during stomatal movements.Key words: stomata, guard cell, plasma membrane, surface area, endocytosis, excretion, accommodationGuard cells control stomatal movement thereby regulating gas exchange in plants. During stomatal movement, guard cells undergo considerable and repetitive variations in cell volume and consequently surface area over a period of minutes. It was proposed that the alterations of the plasma membrane surface area could be up to 40%,¹ whereas the maximum possible stretching of membranes was limited to only about 2%.² Furthermore, due to the presence of a turgor pressure, it has been commonly thought that membrane infoldings should not occur in the guard cells.³ Therefore, it is reasonable to propose that alterations in the surface area must be accomplished by addition and removal of membrane material to and from the plasma membrane.⁴ While many studies imply that endocytosis most likely functions to accommodate the alterations in guard cell volume, many crucial questions about this mechanism deserve to be argued.     

Endocytosis in secretory cells

Membranes of secretion granules inserted during exocytosis into the luminal plasma membranes of glandular cells are retrieved by endocytosis as revealed by electron dense tracers applied selectively to the apical cell surfaces. Two major pathways that endocytic vesicles may take are described: (1) a direct route to the Golgi complex (e.g. in parotid and exocrine pancreas) with later appearance of the tracer in the periphery of mature secretion granules; (2) an indirect route with lysosomes as a first station and the subsequent appearance of tracer in stacked Golgi cisternae. It is presumed that some of the retrieved membrane follows the same pathways and is reutilized in the secretory cycle.     

The role of calcium in exocytosis and endocytosis in plant cells

The role of calcium in the individual cellular events leading to exocytosis is considered. Both vesicle movement processes and vesicle fusion at the cell surface require calcium for completion of specific events in this pathway. Our knowledge of these events is incomplete. In particular the movement of secretory vesicles by the cytoskeleton in response to added calcium is a key event that is beyond our comprehension at present. At the whole cell level, it is shown that external calcium, at the appropriate concentration, is required to elicit secretion at optimal rates. In both plant and animal cells secretion appears to be dependent on, or is triggered by, a rise in the level of internal free calcium ions from about 10^-7 to 10^-6M or even higher. In these eukaryotes internal organelles take up calcium and maintain a low level of calcium in the cell, offsetting the inflow of calcium from the plasma membrane. In some systems the inflow is restricted to a certain part of the plasma membrane, which then acts as a focus for exocytosis and, thereby, establishes a cellular polarity. In plant tissues there appears to be a requirement for some circulation of calcium within the apoplast, to sustain secretion. Recent papers on endocytosis have confirmed its occurrence in plant cells and made significant advances in isolating and characterising the clathrin coats of the coated vesicles involved in the uptake. There is no evidence, at present, for a direct role for calcium in these events. Indirectly, calcium stimulates exocytosis, and hence the delivery of excess membrane to the cell surface, which may be retrieved by an increase in the rate of endocytosis. Quantitative comparisons of the membrane flow occurring in these pathways are not available. Several plant cellular systems have been employed to study secretion and some of these may prove to be superior model systems for the investigation of certain aspects of the control of exocytosis and endocytosis by calcium ions.     

Ultrastructural localization of Interleukin 1 in human peripheral blood monocytes; evidence for IL-1β in mitochondria

Summary The pathway of interleukin 1 (IL-1) secretion from the cell remains unclear. IL-1β is the major form produced by human monocytes, and is synthesized as a precursor of 35kDa which is processed to the extracellular biologically active 17kDa form. We have examined the intracellular localization of IL-1β in lipopolysaccharide (LPS)-stimulated human peripheral blood monocytes, by immunocytochemistry and immunoprecipitation of subcellular fractions. LPS treatment slightly damaged the cells. Unstimulated cells showed very little immunolabelling. In contrast, there was heavy immunolabelling on LPS stimulated cells. Immunolabelling occured within the cytoplasm, nucleus and mitochondria. There was no immunolabelling on the membranous secretory organelles and the plasma membrane. Blebs of cytoplasm budding from the cell surface were immunolabelled, suggesting an alternative route of secretion of IL-1β from the cell. Immunoprecipitation studies confirmed these results.     

Analysis of Occludin Trafficking,Demonstrating Continuous Endocytosis,Degradation, Recycling and Biosynthetic Secretory Trafficking

Tight junctions (TJs) link adjacent cells and are critical for maintenance of apical-basolateral polarity in epithelial monolayers. The TJ protein occludin functions in disparate processes, including wound healing and Hepatitis C Virus infection. Little is known about steady-state occludin trafficking into and out of the plasma membrane. Therefore, we determined the mechanisms responsible for occludin turnover in confluent Madin-Darby canine kidney (MDCK) epithelial monolayers. Using various biotin-based trafficking assays we observed continuous and rapid endocytosis of plasma membrane localised occludin (the majority internalised within 30 minutes). By 120 minutes a significant reduction in internalised occludin was observed. Inhibition of lysosomal function attenuated the reduction in occludin signal post-endocytosis and promoted co-localisation with the late endocytic system. Using a similar method we demonstrated that ∼20% of internalised occludin was transported back to the cell surface. Consistent with these findings, significant co-localisation between internalised occludin and recycling endosomal compartments was observed. We then quantified the extent to which occludin synthesis and transport to the plasma membrane contributes to plasma membrane occludin homeostasis, identifying inhibition of protein synthesis led to decreased plasma membrane localised occludin. Significant co-localisation between occludin and the biosynthetic secretory pathway was demonstrated. Thus, under steady-state conditions occludin undergoes turnover via a continuous cycle of endocytosis, recycling and degradation, with degradation compensated for by biosynthetic exocytic trafficking. We developed a mathematical model to describe the endocytosis, recycling and degradation of occludin, utilising experimental data to provide quantitative estimates for the rates of these processes.     

Effects of colchicine on DNA synthesis, endocytosis and fine structure of cultivated arterial smooth muscle cells

Confluent secondary cultures of rat arterial smooth muscle cells were exposed to cationic and anionic derivatives of ferritin and horseradish peroxidase and studied electron microscopically in order to clarify the influence of molecular net charge on surface binding and endocytosis of proteins. The cationic markers bound uniformly to the plasma membrane. They were then ingested by membrane invagination and via small vesicles transported to lysosomes and the Golgi complex. These organelles were both labelled already after 30 min of incubation. With longer exposure times (2-4 h), an increasing accumulation within the lysosomes was observed, whereas the labelling of the Golgi complex decreased. In spite of continued interiorization of plasma membrane carrying the cationic markers, the cells retained their ability to bind the latter to the surface. The anionic markers did not bind to the cell surface, were taken up in the fluid phase, and later observed only in lysosomes. If assuming that the cationic and anionic proteins serve as markers for the plasma membrane and fluid phase, respectively, but do not affect the intracellular path of interiorized membrane, these results indicate that the endocytic vesicles fuse with and empty their content into lysosomes and that part of the incoming membrane subsequently is transferred to the Golgi complex for possible recirculation back to the cell surface. If, on the other hand, the net charge of the exogenous marker influences the path of the vesicles, there may exist more than one recovery route for membrane interiorized by endocytosis.     

Osmotically evoked shrinking of guard-cell protoplasts causes vesicular retrieval of plasma membrane into the cytoplasm

The dye FM1-43 was used alone or in combination with measurements of the membrane capacitance (C_m) to monitor membrane changes in protoplasts from Viciafaba L. guard cells. Confocal images of protoplasts incubated with FM1-43 (10 μM) at constant ambient osmotic pressure (π_o) revealed in confocal images a slow internalisation of FM1-43-labelled membrane into the cytoplasm. As a result of this process the relative fluorescence intensity of the cell interior (f_FM,i) increased with reference to the total fluorescence (f_FM,t) by 7.4 × 10⁻⁴ min⁻¹. This steady internalisation of dye suggests the occurrence of constitutive endocytosis under constant osmotic pressure. Steady internalisation of FM1-43 labelled membrane caused a prominent staining of a ring-like structure located beneath the plasma membrane. Abrupt elevation of π_o by 200 mosmol kg⁻¹ caused, over the first minutes of incubation, a rapid internalisation of FM1-43 fluorescence into the cytoplasm concomitant with a decrease in cell perimeter. Within the first 5 min the cell perimeter decreased by 7.9%. Over the same time f_FM,i/f_FM,t increased by 0.13, reflecting internalisation of fluorescent label into the cytoplasm. Combined measurements of C_m and total fluorescence of a protoplast (f_FM,p) showed that an increase in π_o evoked a decrease in C_m but no change in f_FM,p. This means that surface contraction of the protoplast is due to retrieval of excess membrane from the plasma membrane and internalisation into the cytoplasm. Further inspection of confocal images revealed that protoplast shrinking was only occasionally associated with internalisation of giant vesicles (median diameter 2.7 μm) with FM1-43-labelled membrane. But, in all cases, osmotic contraction was correlated with a diffuse distribution of FM1-43 label throughout the cytoplasm. From this, we conclude that endocytosis of small vesicles into the cytoplasm is the obligatory process by which cells accommodate an osmotically driven decrease in membrane surface area. Received: 4 May 1999 / Accepted: 19 August 1999     

Rapid recovery of releasable vesicles and formation of nonreleasable endosomes follow intense exocytosis in chromaffin cells

Neurons and neuroendocrine cells must retrieve plasma membrane excess and refill vesicle pools depleted by exocytosis. To perform these tasks cells can use different endocytosis/recycling mechanisms whose selection will impact on vesicle recycling time and secretion performance. We used FM1-43 to evaluate in the same experiment exocytosis, endocytosis, and recovery of releasable vesicles on mouse chromaffin cells. Various exocytosis levels were induced by a variety of stimuli, and we discriminated the resultant endocytosis-recycling responses according to their ability to rapidly generate releasable vesicles. Exocytosis of 20% of plasma membrane (provoked by nicotine/acetylcholine) was followed by total recovery of releasable vesicles. If a stronger stimulus (50 mM K⁺ and 2 mM Ca²⁺) provoking intense exocytosis (51 ± 7%) was applied, endocytosis still retrieved all the fused membrane, but only a fraction (19 ± 2%) was releasable by a second stimulus. Using ADVASEP-7 or bromophenol blue to quickly eliminate fluorescence from noninternalized FM1-43, we determined that this fraction became releasable in <2 min. The remaining nonreleasable fraction was distributed mainly as fluorescent spots (0.7 µm) selectively labeled by 40- to 70-kDa dextrans and was suppressed by a phosphatidylinositol-3-phosphate kinase inhibitor, suggesting that it had been formed by a bulk retrieval mechanism. We concluded that chromaffin cells can rapidly recycle significant fractions of their total vesicle population, and that this pathway prevails when cholinergic agonists are used as secretagogues. When exocytosis exceeded 20% of plasma membrane, an additional mechanism was activated, which was unable to produce secretory vesicles in our experimental time frame but appeared crucial to maintaining membrane surface homeostasis under extreme conditions. endocytosis; mouse chromaffin cells; calcium signal; FM1-43; ADVASEP-7; bromophenol blue     

Copper-dependent degradation of the Saccharomyces cerevisiae plasma membrane copper transporter Ctr1p in the apparent absence of endocytosis.

The cell surface protein repertoire needs to be regulated in response to changes in the extracellular environment. In this study, we investigate protein turnover of the Saccharomyces cerevisiae plasma membrane copper transporter Ctr1p, in response to a change in extra-cellular copper levels. As Ctr1p mediates high affinity uptake of copper into the cell, modulation of its expression is expected to be involved in copper homeostasis. We demonstrate that Ctr1p is a stable protein when cells are grown in low concentrations of copper, but that exposure of cells to high concentrations of copper (10 microM) triggers degradation of cell surface Ctr1p. This degradation appears to be specific for Ctr1p and does not occur with another yeast plasma membrane protein tested. Internalization of some Ctr1p can be seen when cells are exposed to copper. However, yeast mutant strains defective in endocytosis (end3, end4 and chc1-ts) and vacuolar degradation (pep4) exhibit copper-dependent Ctr1p degradation, indicating that internalization and delivery to the vacuole is not the principal mechanism responsible for degradation. In addition, a variant Ctr1p with a deletion in the cytosolic tail is not internalized upon exposure of cells to copper, but is nevertheless degraded. These observations indicate that proteolysis at the plasma membrane most likely explains copper-dependent turnover of Ctr1p and point to the existence of a novel pathway in yeast for plasma membrane protein turnover.     

The ABC-transporter Ste6 accumulates in the plasma membrane in a ubiquitinated form in endocytosis mutants.

We are investigating the transport and turnover of the multispanning membrane protein Ste6. The Ste6 protein is a member of the ABC-transporter family and is required for the secretion of the yeast mating pheromone a-factor. In contrast to the prevailing view that Ste6 is a plasma membrane protein, we found that Ste6 is mainly associated with internal membranes and not with the cell surface. Fractionation and immunofluorescence data are compatible with a Golgi localization of Ste6. Despite its mostly intracellular localization, the Ste6 protein is in contact with the cell surface, as demonstrated by the finding that Ste6 accumulates in the plasma membrane in endocytosis mutants. The Ste6 protein which accumulates in the plasma membrane in endocytosis mutants is ubiquitinated. Ste6 is thus the second protein in yeast besides MAT alpha 2 for which ubiquitination has been demonstrated. Ste6 is a very unstable protein (half-life 13 min) which is stabilized approximately 3-fold in a ubc4 ubc5 mutant, implicating the ubiquitin system in the degradation of Ste6. The strongest stabilizing effect on Ste6 is, however, observed in the vacuolar pep4 mutant (half-life > 2 h), suggesting that most of Ste6 is degraded in the vacuole. Secretory functions are required for efficient degradation of Ste6, indicating that Ste6 enters the secretory pathway and is transported to the vacuole by vesicular carriers.     

Spatiotemporal analysis of endocytosis and membrane distribution of fluorescent sterols in living cells

Distribution and dynamics of cholesterol in the plasma membrane as well as internalization pathways for sterol from the cell surface are of great cell biological interest. Here, UV-sensitive wide field microscopy of the intrinsically fluorescent sterols, dehydroergosterol (DHE) and cholestatrienol (CTL) combined with advanced image analysis were used to study spatiotemporal sterol distribution in living macrophages, adipocytes and fibroblasts. Sterol endocytosis was directly visualized by time-lapse imaging and noise-robust tracking revealing confined motion of DHE containing vesicles in close proximity to the cell membrane. Spatial surface intensity patterns of DHE as well as that of the lipid marker DiIC12 being assessed by statistical image analysis persisted over several minutes in cells having a constant overall curvature. Sites of sterol endocytosis appeared indistinguishable from other regions of the cell surface, and endocytosis contributed by 62% to total sterol uptake in J774 cells. DHE co-localized with fluorescent transferrin (Tf) in vesicles right after onset of endocytosis and in deepened surface patches of energy depleted cells. Surface caveolae labeled with GFP-tagged caveolin were not particularly enriched in DHE or CTL. Some sterol co-localized with internalized caveolin suggesting that caveolar endocytosis contributes to vesicular sterol uptake. These findings demonstrate that plasma membrane sterol is internalized by several endocytic pathways. Sterol endocytosis does not require formation of microscopically resolvable sterol clusters or enrichment of sterol in surface caveolae. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Testing for endocytosis in plants

Summary. For many years endocytosis has been regarded with great scepsis by plant physiologists. Although now generally accepted, care must still be taken with experiments designed to demonstrate endocytic uptake at the plasma membrane. We have taken a critical look at the various agents which are in use as markers for plant endocytosis, pointing out pitfalls and precautions which should be taken. We also take this opportunity to introduce the tyrphostins – tyrosine kinase inhibitors –, which also seem to prevent endocytosis in plants. Correspondence and reprints: Heidelberg Institute for Plant Sciences, University of Heidelberg, Im Neuenheimer Feld 230, 69120 Heidelberg, Federal Republic of Germany.     

Cholesterol modulation of nicotinic acetylcholine receptor surface mobility

Nicotinic acetylcholine receptor (AChR) function and distribution are quite sensitive to cholesterol (Chol) levels in the plasma membrane (reviewed by Barrantes in J Neurochem 103 (suppl 1):72–80, 2007). Here we combined confocal fluorescence recovery after photobleaching (FRAP) and confocal fluorescence correlation spectroscopy (FCS) to examine the mobility of the AChR and its dependence on Chol content at the cell surface of a mammalian cell line. Plasma membrane AChR exhibited limited mobility and only ~55% of the fluorescence was recovered within 10 min after photobleaching. Depletion of membrane Chol by methyl-β-cyclodextrin strongly affected the mobility of the AChR at the plasma membrane; the fraction of mobile AChR fell from 55 to 20% in Chol-depleted cells, whereas Chol enrichment by methyl-β-cyclodextrin-Chol treatment did not reduce receptor mobility at the cell surface. Actin depolymerization caused by latrunculin A partially restored receptor mobility in Chol-depleted cells. In agreement with the FRAP data, scanning FCS experiments showed that the diffusion coefficient of the AChR was about 30% lower upon Chol depletion. Taken together, these results suggest that membrane Chol modulates AChR mobility at the plasma membrane through a Chol-dependent mechanism sensitive to cortical actin.     

Endocytosis of the vasopressin receptor by anterior pituitary cells is increased by corticotropin-releasing factor (CRF)

Endocytosis of certain receptors such as the transferrin receptor and the EGF-receptor appears to be influenced by second messengers. If second messengers are involved in modulation of endocytosis, not only endocytosis of the stimulated receptor itself but also of receptors for other ligands on the cell surface may be influenced by receptor occupancy. Corticotropin-releasing factor (CRF) and vasopressin act synergistically on secretion of ACTH from the anterior pituitary. The results presented here demonstrate that CRF increases retrieval of the vasopressin receptor in anterior pituitary cells in primary culture without influencing the surface binding of vasopressin. This is not a function of an increased membrane turnover since endocytosis of the transferrin receptor is not influenced by CRF.     

Clathrin-mediated constitutive endocytosis of PIN auxin efflux carriers in Arabidopsis

Endocytosis is an essential process by which eukaryotic cells internalize exogenous material or regulate signaling at the cell surface [1]. Different endocytic pathways are well established in yeast and animals; prominent among them is clathrin-dependent endocytosis [2, 3]. In plants, endocytosis is poorly defined, and no molecular mechanism for cargo internalization has been demonstrated so far [4, 5], although the internalization of receptor-ligand complexes at the plant plasma membrane has recently been shown [6]. Here we demonstrate by means of a green-to-red photoconvertible fluorescent reporter, EosFP [7], the constitutive endocytosis of PIN auxin efflux carriers [8] and their recycling to the plasma membrane. Using a plant clathrin-specific antibody, we show the presence of clathrin at different stages of coated-vesicle formation at the plasma membrane in Arabidopsis. Genetic interference with clathrin function inhibits PIN internalization and endocytosis in general. Furthermore, pharmacological interference with cargo recruitment into the clathrin pathway blocks internalization of PINs and other plasma-membrane proteins. Our data demonstrate that clathrin-dependent endocytosis is operational in plants and constitutes the predominant pathway for the internalization of numerous plasma-membrane-resident proteins including PIN auxin efflux carriers.     

Constitutive clathrin-mediated endocytosis of CTLA-4 persists during T cell activation

CTLA-4 is one of the most important negative regulators of the T cell immune response. However, the subcellular distribution of CTLA-4 is unusual for a receptor that interacts with cell surface transmembrane ligands in that CTLA-4 is rapidly internalized from the plasma membrane. It has been proposed that T cell activation can lead to stabilization of CTLA-4 expression at the cell surface. Here we have analyzed in detail the internalization, recycling, and degradation of CTLA-4. We demonstrate that CTLA-4 is rapidly internalized from the plasma membrane in a clathrin- and dynamin-dependent manner driven by the well characterized YVKM trafficking motif. Furthermore, we show that once internalized, CTLA-4 co-localizes with markers of recycling endosomes and is recycled to the plasma membrane. Although we observed limited co-localization of CTLA-4 with lysosomal markers, CTLA-4 was nonetheless degraded in a manner inhibited by lysosomal blockade. T cell activation stimulated mobilization of CTLA-4, as judged by an increase in cell surface expression; however, this pool of CTLA-4 continued to endocytose and was not stably retained at the cell surface. These data support a model of trafficking whereby CTLA-4 is constitutively internalized in a ligand-independent manner undergoing both recycling and degradation. Stimulation of T cells increases CTLA-4 turnover at the plasma membrane; however, CTLA-4 endocytosis continues and is not stabilized during activation of human T cells. These findings emphasize the importance of clathrin-mediated endocytosis in regulating CTLA-4 trafficking throughout T cell activation.     

Turnover of the surface proteins and the receptor for serum asialoglycoproteins in primary cultures of rat hepatocytes

The turnover of plasma membrane proteins in primary rat hepatocyte cultures was examined by following the loss of polypeptides labeled in situ by lactoperoxidase-catalyzed iodination using 125I and 131I. Most plasma membrane proteins had similar rates of degradation, having a half-life of approximately 85 h. By in situ labeling via lactoperoxidase-catalyzed iodination, as well as metabolically labeling cells with L-[35S]methionine, the asialoglycoprotein receptor, a plasma membrane constituent, was identified and shown to exist in three forms which were structurally related. The turnover of receptor on the cell surface was examined by following the loss of iodinated cell surface receptor, while the turnover of total cellular receptor, including both surface and internally localized receptor was assayed by following the loss of receptor labeled metabolically with [35S]methionine. The turnover rate in both cases was approximately 20 h. Receptor-mediated endocytosis of asialoglycoproteins had no effect on the turnover of the plasma membrane proteins or receptor. Based on estimates of the rate of metabolism of the asialoglycoprotein ligand relative to the turnover rate of the receptor, we conclude each molecule of receptor can deliver about 1,000 molecules of ligand to the lysosome to be degraded.