Inhibition of the receptor-mediated endocytosis of diferric transferrin is associated with the covalent modification of the transferrin receptor with palmitic acid

Nonpalmitoylated human asialoglycoprotein receptors recycle constitutively but are defective in coated pit-mediated endocytosis, dissociation, and delivery of ligand to lysosomes

The hepatic asialoglycoprotein receptor (ASGP-R) internalizes desialylated glycoproteins via the clathrin-coated pit pathway and mediates their delivery to lysosomes for degradation. The human ASGP-R contains two subunits, H1 and H2. Cytoplasmic residues Cys(36) in H1, as well as Cys(54) and Cys(58) in H2 are palmitoylated (Zeng, F.-Y., and Weigel, P. H. (1996) J. Biol. Chem. 271, 32454). In order to study the function(s) of ASGP-R palmitoylation, we mutated these Cys residues to Ser and generated stably transfected SK-Hep-1 cell lines expressing either wild-type or nonpalmitoylated ASGP-Rs. Compared with wild-type ASGP-Rs, palmitoylation-defective ASGP-Rs showed normal ligand binding, intracellular distribution and trafficking patterns, and pH-induced dissociation profiles in vitro. However, continuous ASOR uptake, and the uptake of prebound cell surface ASOR were slower in cells expressing palmitoylation-defective ASGP-Rs than in cells expressing wild-type ASGP-Rs. Unlike native ASGP-Rs in hepatocytes or hepatoma cells, which mediate endocytosis via the clathrin-coated pit pathway and are almost completely inhibited by hypertonic medium, only approximately 40% of the ASOR uptake in SK-Hep-1 cells expressing wild-type ASGP-Rs was inhibited by hyperosmolarity. This result suggests the existence of an alternate nonclathrin-mediated internalization pathway, such as transcytosis, for the entry of ASGP-R.ASOR complexes into these cells. In contrast, ASOR uptake mediated by cells expressing palmitoylation-defective ASGP-Rs showed only a marginal difference under hypertonic conditions, indicating that most of the nonpalmitoylated ASGP-Rs were not internalized and processed normally through the clathrin-coated pit pathway. Furthermore, cells expressing wild-type ASGP-Rs were able to degrade the internalized ASOR, whereas ASOR dissociation was impaired and degradation was barely detectable in cells expressing nonpalmitoylated ASGP-Rs. We conclude that palmitoylation of the ASGP-R is required for its efficient endocytosis of ligand by the clathrin-dependent endocytic pathway and, in particular, for the proper dissociation and delivery of ligand to lysosomes.

Fatty acid modification of the coxsackievirus and adenovirus receptor

Membrane-proximal cysteines 259 and 260 in the cytoplasmic tail of the coxsackievirus and adenovirus receptor (CAR) are known to be essential for the tumor suppression activity of CAR. We demonstrate that these residues provide an S-acylation motif for modification of CAR with the fatty acid palmitate. Substitution of alanine for cysteines 259 and 260 results in the additional localization of CAR in perinuclear compartments with no effect on the efficiency of adenovirus infection. The results indicate that palmitylation is important for stable plasma membrane expression and biological activity of CAR but is not critical for adenovirus receptor performance.

Processing of the human transferrin receptor at distinct positions within the stalk region by neutrophil elastase and cathepsin G

The ectodomain of the human transferrin receptor (TfR) is released as soluble TfR into the blood by cleavage within a stalk. The major cleavage site is located C-terminally of Arg-100; alternative cleavage sites are also present. Since the cleavage process is still unclear, we looked for proteases involved in TfR ectodomain release. In the supernatant of U937 histiocytic cells we detected alternatively cleaved TfR (at Glu-110). In membrane fractions of these cells we identified two distinct proteolytic activities responsible for TfR cleavage within the stalk at either Val-108 or Lys-95. Both activities could be inhibited by serine protease inhibitors, but not by inhibitors of any other class of proteases. Protein purification yielded a 28 kDa protein that generated the Val-108 terminus. The protease activity could be ascribed to neutrophil elastase according to the substrate specificity determined by amino acid substitution analysis of synthetic peptides, an inhibitor profile, the size of the protease and the use of specific antibodies. The results of analogous experiments suggest that the second activity is represented by another serine protease, cathepsin G. Thus, membrane-associated forms of neutrophil elastase and cathepsin G may be involved in alternative TfR shedding in U937 cells.

Synaptic strength regulated by palmitate cycling on PSD-95

Dynamic regulation of AMPA-type glutamate receptors represents a primary mechanism for controlling synaptic strength, though mechanisms for this process are poorly understood. The palmitoylated postsynaptic density protein, PSD-95, regulates synaptic plasticity and associates with the AMPA receptor trafficking protein, stargazin. Here, we identify palmitate cycling on PSD-95 at the synapse and find that palmitate turnover on PSD-95 is regulated by glutamate receptor activity. Acutely blocking palmitoylation disperses synaptic clusters of PSD-95 and causes a selective loss of synaptic AMPA receptors. We also find that rapid glutamate-mediated AMPA receptor internalization requires depalmitoylation of PSD-95. In a nonneuronal model system, clustering of PSD-95, stargazin, and AMPA receptors is also regulated by ongoing palmitoylation of PSD-95 at the plasma membrane. These studies suggest that palmitate cycling on PSD-95 can regulate synaptic strength and regulates aspects of activity-dependent plasticity.

Iodination significantly influences the binding of human transferrin to the transferrin receptor

The human transferrin receptor (TfR) and its ligand, the serum iron carrier transferrin, serve as a model system for endocytic receptors. Although the complete structure of the receptor's ectodomain and a partial structure of the ligand have been published, conflicting results still exist about the magnitude of equilibrium binding constants, possibly due to different labeling techniques. In the present study, we determined the equilibrium binding constant of purified human TfR and transferrin. The results were compared to those obtained with either iodinated TfR or transferrin. Using an enzyme-linked assay for receptor-ligand interactions based on the published direct calibration ELISA technique, we determined an equilibrium constant of Kd=0.22 nM for the binding of unmodified human Tf to surface-immobilized human TfR. In a reciprocal experiment using soluble receptor and surface-bound transferrin, a similar constant of Kd=0.23 nM was measured. In contrast, covalent labeling of either TfR or transferrin with 125I reduced the affinity 3-5-fold to Kd=0.66 nM and Kd=1.01 nM, respectively. The decrease in affinity upon iodination of transferrin is contrasted by an only 1.9-fold decrease in the association rate constant, suggesting that the iodination affects rather the dissociation than the association kinetics. These results indicate that precautions should be taken when interpreting equilibrium and rate constants determined with covalently labeled components.

Iron metabolism: iron deficiency and iron overload

Iron is an essential cofactor in a variety of cellular processes. Except for a few unusual bacterial species, iron is indispensable for living organisms. However, free iron is toxic because of its propensity to induce the formation of dangerous free radicals. Consequently, iron balance is tightly regulated. Disorders of iron homeostasis are among the most common afflictions of humans. This review discusses inherited iron deficiency and iron overload disorders and recent insights into their pathophysiology.

Palmitoylation of the Rous sarcoma virus transmembrane glycoprotein is required for protein stability and virus infectivity

The Rous sarcoma virus (RSV) transmembrane (TM) glycoprotein is modified by the addition of palmitic acid. To identify whether conserved cysteines within the hydrophobic anchor region are the site(s) of palmitoylation, and to determine the role of acylation in glycoprotein function, cysteines at residues 164 and 167 of the TM protein were mutated to glycine (C164G, C167G, and C164G/C167G). In CV-1 cells, palmitate was added to env gene products containing single mutations but was absent in the double-mutant Env. Although mutant Pr95 Env precursors were synthesized with wild-type kinetics, the phenotypes of the mutants differed markedly. Env-C164G had properties similar to those of the wild type, while Env-C167G was degraded faster, and Env containing the double mutant C164G/C167G was very rapidly degraded. Degradation occurred after transient plasma membrane expression. The decrease in steady-state surface expression and increased rate of internalization into endosomes and lysosomes paralleled the decrease in palmitoylation observed for the mutants. The phenotypes of mutant viruses were assessed in avian cells in the context of the pATV8R proviral genome. Virus containing the C164G mutation replicated with wild-type kinetics but exhibited reduced peak reverse transcriptase levels. In contrast, viruses containing either the C167G or the C164G/C167G mutation were poorly infectious or noninfectious, respectively. These phenotypes correlated with different degrees of glycoprotein incorporation into virions. Infectious revertants of the double mutant demonstrated the importance of cysteine-167 for efficient plasma membrane expression and Env incorporation. The observation that both cysteines within the membrane-spanning domain are accessible for acylation has implications for the topology of this region, and a model is proposed.

C-terminal domain of the Epstein-Barr virus LMP2A membrane protein contains a clustering signal

The latency-regulated transmembrane protein LMP2A interferes with signaling from the B-cell antigen receptor by recruiting the tyrosine kinases Lyn and Syk and by targeting them for degradation by binding the cellular E3 ubiquitin ligase AIP4. It has been hypothesized that this constitutive activity of LMP2A requires clustering in the membrane, but molecular evidence for this has been lacking. In the present study we show that LMP2A coclusters with chimeric rat CD2 transmembrane molecules carrying the 27-amino-acid (aa) intracellular C terminus of LMP2A and that this C-terminal domain fused to the glutathione-S-transferase protein associates with LMP2A in cell lysates. This molecular association requires neither the cysteine-rich region between aa 471 and 480 nor the terminal three aa 495 to 497. We also show that the juxtamembrane cysteine repeats in the LMP2A C terminus are the major targets for palmitoylation but that this acylation is not required for targeting of LMP2A to detergent-insoluble glycolipid-enriched membrane microdomains.

Transmembrane TNF (pro-TNF) is palmitoylated

Human transmembrane tumor necrosis factor (pro-TNF) was examined for protein acylation. The cDNA encoding pro-TNF was expressed in both COS-1 cells and Sf9 cells and metabolic labeling with [(3)H]myristic or [(3)H]palmitic acid was attempted. The 17 kDa mature TNF secreted from the transfected cells was not labeled, whereas the 26 kDa pro-TNF was specifically labeled with [(3)H]palmitic acid. The [(3)H]palmitic acid labeling of pro-TNF was eliminated by treatment with hydroxylamine, indicating that the labeling was due to palmitoylation of a cysteine residue via a thioester bond. Site-directed mutagenesis of the two cysteine residues residing in the leader sequence of pro-TNF demonstrated that palmitoylation of pro-TNF occurs solely at Cys-47, located at the boundary between the transmembrane and cytoplasmic domains of pro-TNF. Thus, pro-TNF interacts with the plasma membrane via both its proteinaceous transmembrane domain and a lipid anchor.

Delivery of peptides and proteins through the blood-brain barrier

Peptide and protein therapeutics are generally excluded from transport from blood to brain, owing to the negligible permeability of these drugs to the brain capillary endothelial wall, which makes up the blood-brain barrier (BBB) in vivo. However, peptides or protein therapeutics may be delivered to the brain with the use of the chimeric peptide strategy for peptide drug delivery. Chimeric peptides are formed when a non-transportable peptide therapeutic is coupled to a BBB drug transport vector. Transport vectors are proteins such as cationized albumin, or the OX26 monoclonal antibody to the transferrin receptor; these proteins undergo absorptive-mediated and receptor-mediated transcytosis through the BBB, respectively. In addition to vector development, another important element of the chimeric peptide strategy is the design of strategies for coupling drugs to the vector that give high efficiency coupling and result in the liberation of biologically active peptides following cleavage of the bond linking the therapeutic and the transport vector. The avidin/biotin system has been recently shown to be advantageous in fulfilling these criteria for successful linker strategies. The use of the OX26 monoclonal antibody, the use of the avidin/biotin system as a linker strategy, and the design of a vasoactive intestinal peptide (VIP) analogue that is suitable for monobiotinylation and retention of biologic activity following cleavage, allowed for the recent demonstration of in vivo pharmacologic effects in brain following the systemic administration of relatively low doses (12 microg/kg) of neuropeptide.

Structural and Functional Stability of the Mature Transferrin Receptor from Human Placenta

The transferrin receptor (TfR) is a N- and O-glycosylated transmembrane protein mediating the cellular iron uptake by binding and internalization of diferric transferrin. In this study, rate constants and dissociation constants of 125I-ferri-transferrin binding to the human TfR were examined dependent on receptor glycan composition, pH, bivalent cations, and temperature. To do so, purified human placental TfR was noncovalently immobilized to polystyrene surfaces and subjected to alterations in various parameters. We found that transferrin binding was clearly dependent on a receptor pretreatment with buffers of various pH in that most of the TfR molecules irreversibly lost transferrin binding activity below pH 6.5. However, the dissociation constant of the remaining active binding sites was not affected. Similarly, we were able to define the thermal stability of the receptor as a function of transferrin binding ability. Binding of transferrin was completely lost provided that the receptor was pretreated at temperatures of at least 65 degrees C. Treatment with EDTA also caused an irreversible loss of transferrin binding activity, indicating that the functionally active conformation of the mature TfR depends on bivalent cations. In order to examine the role of the receptor glycans, we enzymatically removed the sialic acid residues, the hybrid and oligomannosidic N-glycans, or all types of N-glycans. In contrast to the parameters described above, all desialylated and N-deglycosylated TfR variants had exactly the same transferrin binding properties as the native TfR. To assess changes in the secondary structure of the receptor, circular dichroic spectra were recorded from TfR at pH 5.0, from heat pretreated receptor and from deglycosylated TfR. Since the receptor did not exhibit detectable changes in the CD spectrum of the deglycosylated receptor, it can be concluded that the N-linked carbohydrates of the mature, fully processed TfR are not essential for transferrin binding and conformational stability.

The roles of iron in health and disease

Iron is vital for almost all living organisms by participating in a wide variety of metabolic processes, including oxygen transport, DNA synthesis, and electron transport. However, iron concentrations in body tissues must be tightly regulated because excessive iron leads to tissue damage, as a result of formation of free radicals. Disorders of iron metabolism are among the most common diseases of humans and encompass a broad spectrum of diseases with diverse clinical manifestations, ranging from anemia to iron overload and, possibly, to neurodegenerative diseases. The molecular understanding of iron regulation in the body is critical in identifying the underlying causes for each disease and in providing proper diagnosis and treatments. Recent advances in genetics, molecular biology and biochemistry of iron metabolism have assisted in elucidating the molecular mechanisms of iron homeostasis. The coordinate control of iron uptake and storage is tightly regulated by the feedback system of iron responsive element-containing gene products and iron regulatory proteins that modulate the expression levels of the genes involved in iron metabolism. Recent identification and characterization of the hemochromatosis protein HFE, the iron importer Nramp2, the iron exporter ferroportin1, and the second transferrin-binding and -transport protein transferrin receptor 2, have demonstrated their important roles in maintaining body's iron homeostasis. Functional studies of these gene products have expanded our knowledge at the molecular level about the pathways of iron metabolism and have provided valuable insight into the defects of iron metabolism disorders. In addition, a variety of animal models have implemented the identification of many genetic defects that lead to abnormal iron homeostasis and have provided crucial clinical information about the pathophysiology of iron disorders. In this review, we discuss the latest progress in studies of iron metabolism and our current understanding of the molecular mechanisms of iron absorption, transport, utilization, and storage. Finally, we will discuss the clinical presentations of iron metabolism disorders, including secondary iron disorders that are either associated with or the result of abnormal iron accumulation.

Autopalmitoylation of tubulin

Pure rat brain tubulin is readily palmitoylated in vitro using [3H]palmitoyl CoA but no added enzymes. A maximum of approximately six palmitic acids are added per dimer in 2-3 h at 36-37 degrees C under native conditions. Both alpha and beta tubulin are labeled, and 63-73% of the label was hydroxylamine-labile, presumed thioesters. Labeling increases with increasing pH and temperature, and with low concentrations of guanidine HCl or KCl (but not with urea) to a maximum of approximately 13 palmitates/dimer. High SDS and guanidine HCl concentrations are inhibitory. At no time could all 20 cysteine residues of the dimer be palmitoylated. Polymerization to microtubules, or use of tubulin S, markedly decreases the accessibility of the palmitoylation sites. Palmitoylation increases the electrophoretic mobility of a portion of alpha tubulin toward the beta band. Palmitoylated tubulin binds a colchicine analogue normally, but during three warm/cold polymerization/depolymerization cycles there is a progressive loss of palmitoylated tubulin, indicating decreased polymerization competence. We postulate that local electrostatic factors are major regulators of reactivity of tubulin cysteine residues toward palmitoyl CoA, and that the negative charges surrounding a number of the cysteines are sensitive to negative charges on palmitoyl CoA.

Cloning of an L-3-hydroxyacyl-CoA dehydrogenase that interacts with the GLUT4 C-terminus

Evidence indicates that the carboxy-terminal cytoplasmic domain of glucose transporter 4 (GLUT4) is important for the regulation of GLUT4 in muscle and adipocytes. We cloned from a human skeletal muscle cDNA library a 34-kDa protein which interacts with GLUT4 C-terminal cytoplasmic domain in a two-hybrid system and also with GLUT4 C-terminus synthetic peptide in an in vitro binding assay. This protein, called YP10, showed a high degree (>90%) of sequence homology with l-3-hydroxyacyl-CoA dehydrogenase (HAD) and had a dehydrogenase activity similar to pig heart HAD, which was inhibited by GLUT4 C-terminus synthetic peptide. An antiserum raised against pig heart HAD also reacted with YP10. Western blot analysis using this antiserum revealed abundant immunoreactivity only in the mitochondria- and plasma membrane-enriched fractions of rat adipocytes. Northern blots revealed that YP10 mRNA is most abundant in skeletal and heart muscle. These findings suggest that YP10, a HAD isoform, interacts with GLUT4 at the plasma membrane and may play a role in cross-talk between glucose transport and fatty acid metabolism.

Structural model of phospholipid-reconstituted human transferrin receptor derived by electron microscopy

BACKGROUND

The transferrin receptor (TfR) regulates the cellular uptake of serum iron. Although the TfR serves as a model system for endocytosis receptors, neither crystal structure analysis nor electron microscopy has yet revealed the molecular dimensions of the TfR. To derive the first molecular model, we analyzed purified, lipid-reconstituted human TfR by high-resolution electron microscopy.

RESULTS

A structural model of phospholipid-reconstituted TfR was derived from 72 cryo-electron microscopic images. The TfR dimer consists of a large extracellular globular domain (6.4 x 7.5 x 10.5 nm) separated from the membrane by a thin molecular stalk (2.9 nm). A comparative protein sequence analysis suggests that the stalk corresponds to amino acid residues 89-126. Under phospholipid-reconstitution conditions, the human TfR not only integrates into vesicles, but also forms rosette-like structures called proteoparticles. Scanning transmission electron microscopy revealed an overall diameter of 31.5 nm and a molecular mass of 1669 +/- 26 kDa for the proteoparticles, corresponding to nine TfR dimers. The average mass of a single receptor dimer was determined as being 186 +/- 4 kDa.

CONCLUSIONS

Proteoparticles resemble TfR exosomes that are expelled by sheep reticulocytes upon maturation. The structure of proteoparticles in vitro is thus interpreted as being the result of the TfR's strong self-association potential, which might facilitate the endosomal sequestration of the TfR away from other membrane proteins and its subsequent return to the cell surface within tubular structures. The stalk is assumed to facilitate the tight packing of receptor molecules in coated pits and recycling tubuli.

Stimulation of 125I-transferrin binding and 59Fe uptake in rat adipocytes by vanadate: treatment time determines apparent tissue sensitivity

Vanadium compounds have been documented to stimulate a number of insulin biological effects in vitro and in vivo. We previously demonstrated stimulation of glucose transport and insulin-like growth factor-II (IGF-II) binding in rat adipocytes. These actions are associated with translocation of glucose transporters and IGF-II receptors from an intracellular compartment to the plasma membrane. The transferrin receptor is also recruited to the plasma membrane in response to insulin. Freshly isolated rat adipocytes were incubated with vanadate and insulin at 37 degrees C, and after treating the cells with KCN to inhibit further receptor movement, diferric 125I-transferrin binding was assayed. Vanadate stimulated a dose- and time-dependent increase in 125I-transferrin binding, reaching maximum (approximately threefold) stimulation at 1 mmol/L after a 4-hour incubation. This was equivalent to the maximum insulin effect that was obtained with 10(-8) mol/L after 30 minutes. A similar degree of stimulation was achieved with 0.1 mmol/L vanadate after 8 hours of exposure. Dose-response data showed that the apparent sensitivity to vanadate was time-dependent and increased with the duration of exposure (EC50: 30 minutes, 1 mmol/L; 3 hours, 0.35 mmol/L). Scatchard analysis of 125I-transferrin binding showed that both insulin and vanadate increased receptor binding capacity with no effect on receptor affinity. Total cellular transferrin receptor content measured by immunoblotting with monoclonal anti-transferrin receptor antibody (OX-26) was not altered by insulin or vanadate, consistent with receptor translocation. Assessment of 59Fe uptake from 59Fe-labeled diferric transferrin showed that vanadate augmented 59Fe uptake in a dose-dependent manner to an extent similar to insulin, demonstrating the functional activity of the receptors (percent of control: 10(-8) mol/L insulin, 175% +/- 23.8%, P < .02; 0.3 mmol/L vanadate, 188% +/- 17.3%, P < .01). We conclude that vanadate mimics insulin to augment cell surface transferrin receptors and increase Fe uptake in rat adipocytes. The time-dependent apparent increase in sensitivity is consistent with the effectiveness of very low concentrations of vanadate in vivo after several days of administration, and suggests a requirement for vanadate entry into cells to mediate this biological response.

The transferrin receptor cytoplasmic domain determines its rate of transport through the biosynthetic pathway and its susceptibility to cleavage early in the pathway

The soluble human transferrin receptor (TfR) found in blood is the result of a proteolytic cleavage occurring in the ectodomain of the receptor close to the transmembrane domain at Arg-100. We have discovered another cleavage site between Gly-91 and Val-92 even closer to the transmembrane domain. Cleavage at Gly-91 differs markedly from the normal cleavage site. It occurs when the entire cytoplasmic portion or the proximal 31 amino acids of the transmembrane domain are deleted. A soluble disulfide-bonded dimer of the TfR is released into the medium in contrast to the cleavage at Arg-100 where a dimer lacking intersubunit disulfide bonds is released. Whereas the cleavage at Arg-100 is generated by cycling through the endosomal system, pulse-chase experiments indicate that cleavage at Gly-91 occurs predominantly during the biosynthesis of the receptor. Pulse-chase analysis of the biosynthesis of mutant TfRs that lack the membrane-proximal cytoplasmic domain show that they exit the endoglycosidase H-sensitive compartment at a slower rate than the wild type TfR. These results suggest that the cytoplasmic domain influences the trafficking of the TfR either by influencing the folding of the ectodomain or by providing a positive signal for its transport through the biosynthetic pathway.

Exon/intron structure of the human transferrin receptor gene

A PCR-based intron jumping strategy has been utilized to investigate the exon/intron structure of the human transferrin receptor gene and determine the sequences of exon/intron junctions. There are 18 exons and introns 5' to a large exon encoding the last translated segment and a sizable 3' untranslated segment. All of the translated segments are encoded by exons 2-19. The tight turn motif, which is critical to the process of endocytosis, is encoded by exon 3. Based on recent studies of human/chicken receptor chimeras, it appears that the residues most likely to be involved in transferrin binding are encoded by exons 17-19. Exon 12 exhibits the greatest degree of homology with the gene for the prostate specific membrane antigen. A polymorphism has been tentatively identified at nucleotide position 519 in exon 4; the presence of either adenine or guanine should result in either serine or glycine, respectively, at position 142 of the amino acid sequence. This analysis of genomic structure will permit further detailed studies of the regulation, expression and evolution of the human transferrin receptor gene.

Binding of HIV-1 Nef to a novel thioesterase enzyme correlates with Nef-mediated CD4 down-regulation

Nef is a 27-kDa myristoylated protein conserved in primate lentiviruses. In vivo, simian immunodeficiency virus Nef is required in macaques to produce a high viral load and full pathological effects. Nef has at least three major effects in vitro, induction of CD4 down-regulation, alteration of T cell activation pathways, and enhancement of viral infectivity. We have used the yeast two-hybrid system to identify cellular proteins that interact with HIV-1Lai Nef and could mediate Nef function. A human cDNA was isolated that encodes a new type of thioesterase, an enzyme that cleaves thioester bonds. This novel thioesterase is unlike the animal types I and II thioesterases previously cloned but is homologous to the Escherichia coli thioesterase II. Nef and this thioesterase interact in vitro and are co-immunoprecipitated by anti-Nef antibodies in CEM cells expressing Nef. Nef alleles from human immunodeficiency virus-1 (HIV-1) isolates unable to down-regulate CD4 do not react or react poorly with thioesterase. An HIV-1 NefLai mutant selected for its lack of interaction with thioesterase was also unable to down-regulate CD4 cell-surface expression. These observations suggest that this human thioesterase is a cellular mediator of Nef-induced CD4 down-regulation.

Regulation of cellular signalling by fatty acid acylation and prenylation of signal transduction proteins

Covalent modification by fatty acylation and prenylation occurs on a wide variety of cellular signalling proteins. The enzymes that catalyze attachment of these lipophilic moieties to proteins have recently been identified and characterized. Each lipophilic group confers unique properties to the modified protein, resulting in alterations in protein/protein interactions, membrane binding and targeting, and intracellular signalling. The biochemistry and cell biology of protein myristoylation, farnesylation and geranylgeranylation is reviewed here, with emphasis on the Src family of tyrosine kinases, Ras proteins and G protein coupled signalling systems.

Palmitoylation: a post-translational modification that regulates signalling from G-protein coupled receptors

Protein acylation is a post-translational modification that has seized much attention in the last few years. Depending on the nature of the fatty acid added, protein acylation can take the form of palmitoylation, myristoylation, or prenylation. Palmitoylation has been implicated in the modification of several different proteins and is particularly prevalent in G-protein coupled receptors and their cognate G-proteins, where it is thought to have an important regulatory function. Given that palmitoylation of these proteins is a dynamic phenomenon in which turnover rate is modulated by agonist activation, it is thought to be implicated in processes such as receptor phosphorylation and desensitization as well as in G-protein membrane translocation. A better understanding of the regulation of signal transduction mediated by G-protein coupled receptors will require the identification and characterization of those enzymes implicated in the palmitoylation and depalmitoylation process of this large class of receptors and their signalling allies.

Association of Drosophila cysteine string proteins with membranes

Cysteine string proteins are putative synaptic vesicle proteins that lack a transmembrane domain. Our analysis shows that Drosophila cysteine string proteins are extensively modified by hydroxylamine-sensitive fatty acylation. This modification could be responsible for association of csp's with membranes. Extensive deacylation of Dcsp's by a 20 h incubation in 1 M hydroxylamine, pH 7.0, or methanolic KOH produces a protein of 6-7 kDa lower mass than untreated Dcsp's. Surprisingly, the hydroxylamine treatment does not cause release of Dcsp's from membranes. On the other hand, alkaline stripping of membranes isolated from Drosophila brain by 0.1 M sodium carbonate, pH 11.5, causes a significant release of Dcsp's from membranes into the cytosol. These results indicate that fatty acylation may not form the main anchor of Dcsp's in membranes. Taking advantage of the endocytotic block in the Drosophila mutant shibire ts1, we analyzed the acylation states of Dcsp's in two stages during synaptic vesicle recycling and found no evidence for an acylation/deacylation cycle of Dcsp's in the brain nerve terminals.

Palmitoylation of brain capillary proteins

Palmitoylation is a reversible posttranslational modification which is involved in the regulation of several membrane proteins such as beta 2-adrenergic receptor, p21ras and trimeric G-protein alpha-subunits. This covalent modification could be involved in the regulation of the numerous membrane proteins present in the blood-brain barrier capillaries. The palmitoylation activity present in brain capillaries was characterized using [3H]palmitate labeling followed by chloroform methanol precipitation. Palmitate solubilizing agents such as detergents and bovine serum albumin (BSA), were used for optimizing activity. Some palmitoylated substrates were identified using [3H]palmitate labeling followed by immunoprecipitation with specific antibodies. Two optimal palmitate solubilization conditions were found, one involves cell permeabilization (Triton X-100) and the other represents a more physiological condition where membrane integrity is conserved (BSA). Sensitivity to the cysteine modifier N-ethylmaleimide and to hydrolysis, using hydroxylamine or alkaline methanolysis, indicated that palmitic acid was bound to the proteins by a thioester bond. Maximal palmitate incorporation was reached after 30 or 60 min of incubation in the presence of Triton or BSA, respectively. Depalmitoylation was observed in the presence of BSA, but not with detergents. The palmitoylation reaction was optimal at pH 8 or 9 in the presence of Triton or BSA, respectively, but palmitoylated substrates were detectable over a wide range of pH values. In the presence of Triton X-100, the addition of ATP, CoA and Mg2+ to the incubation medium increased palmitoylation by up to 80-fold. Two palmitoylated substrates were identified, a 42 kDa G-protein alpha subunit and p21ras. The study shows that the utilization of palmitate solubilizing agents is essential to measure in vitro palmitoylation in brain capillaries. Several palmitoylated proteins are present in the blood-brain barrier including five major substrates of 12, 21, 35, 42 and 55 kDa. It is suggested that palmitoylation could play a crucial role in the regulation of brain capillary function, since the two substrates identified in this study are known to be involved in signal transduction, vesicular transport and cell differentiation.

Hydroxylamine treatment differentially inactivates purified rat hepatic asialoglycoprotein receptors and distinguishes two receptor populations

We previously showed that two subpopulations of asialoglycoprotein receptors (ASGP-Rs), designated State 1 and State 2 ASGP-Rs, are present in intact cells and that State 2 ASGP-Rs can be inactivated in permeable rat hepatocytes in a temperature- and ATP-dependent manner. These inactivated ASGP-Rs can be quantitatively reactivated by the addition of palmitoyl-CoA (Weigel, P. H., and Oka, J. A. (1993) J. Biol. Chem. 268, 27186-27190). Here we show that approximately 50% of purified rat ASGP-Rs are inactivated by treatment with hydroxylamine under mild conditions. The activity of affinity-purified ASGP-Rs was assessed by measuring the specific binding of 125I-asialo-orosomucoid (ASOR) in a dot-blot assay after immobilization onto nitrocellulose. Treatment of ASGP-Rs in solution with 0.0125-1.0 M NH2OH, pH 7.4, at 4 degrees C for 4 h resulted in a progressive loss of ASOR binding activity. ASGP-R inactivation with NH2OH occurred more readily at basic pH or at room temperature. Similar treatment with Tris had no effect on ASGP-R activity. The kinetics of ASGP-R activity loss and the dose-response for this inactivation were both biphasic, indicating the presence of two equal populations of ASGP-Rs with different sensitivities to NH2OH. The more sensitive population of ASGP-Rs (approximately 50%) was inactivated by treatment with 0.2 M NH2OH (4 degrees C, 4 h) or with 1.0 M NH2OH (4 degrees C, 1 h) without detectable peptide cleavage as assessed by SDS-polyacrylamide gel electrophoresis. State 1 ASGP-Rs, purified from chloroquine- or monensin-treated hepatocytes, showed significantly less sensitivity to NH2OH treatment (both in kinetics and dose dependence). Furthermore, under mild conditions NH2OH caused dissociation and inactivation of approximately 50% of the total ASGP-Rs (State 1 and State 2) that were prebound to ASOR-Sepharose, whereas the same treatment caused dissociation of only < 20% of State 1 ASGP-Rs from such preformed complexes. As shown in the accompanying paper (Zeng, F. Y., Kaphalia, B. S., Ansari, G. A. S., and Weigel, P. H. (1995) J. Biol. Chem. 270, 21382-21387) all three RHL subunits of active ASGP-Rs, in fact, contain covalently attached palmitate and stearate. In cultured cells, [3H]palmitic acid is metabolically incorporated into all three subunits. These radiolabeled fatty acids are completely released from purified ASGP-Rs by mild NH2OH treatment.(ABSTRACT TRUNCATED AT 400 WORDS)

Fatty acylation of the rat asialoglycoprotein receptor. The three subunits from active receptors contain covalently bound palmitate and stearate

Rat hepatic asialoglycoprotein receptors (ASGP-Rs) are hetero-oligomers composed of three homologous glycoprotein subunits, designated rat hepatic lectins (RHL) 1, 2, and 3. ASGP-Rs mediate the endocytosis and degradation of circulating glycoconjugates containing terminal N-acetylgalactosamine or galactose, including desialylated plasma glycoproteins. We have shown in permeable rat hepatocytes that the ligand binding activity of one subpopulation of receptors (designated State 2 ASGP-Rs) can be decreased or increased, respectively, by ATP and palmitoyl-CoA (Weigel, P. H., and Oka, J. A. (1993) J. Biol. Chem. 268, 27186-27190). We proposed that a reversible and cyclic acylation/deacylation process may regulate ASGP-R activity during endocytosis, receptor-ligand dissociation, and receptor recycling. In the accompanying paper (Zeng, F-Y., and Weigel, P. H. (1995) J. Biol. Chem. 270, 21388-21395), we show that the ligand binding activity of affinity-purified State 2 ASGP-Rs is decreased by treatment with hydroxylamine under mild conditions consistent with these ASGP-Rs being fatty acylated in vivo. In this study, we used a chemical method to determine the presence of covalently-bound fatty acids in individual ASGP-R subunits. The affinity-purified ASGP-R preparations were separated by SDS-polyacrylamide gel electrophoresis under nonreducing conditions, and the gel slices containing individual RHL subunits were treated with alkali to release covalently bound fatty acids, which were subsequently analyzed by gas chromatography and confirmed by gas chromatography-mass spectrometry. Both stearic and palmitic acids were detected in all three receptor subunits. Pretreatment of ASGP-Rs with hydroxylamine before SDS-polyacrylamide gel electrophoresis reduced the content of both fatty acids by 66-80%, indicating that most of these fatty acids are attached to cysteine residues via thioester linkages. Furthermore, when freshly isolated hepatocytes were cultured in the presence of [3H]palmitate, all three RHL subunits in affinity-purified ASGP-Rs were metabolically labeled. We conclude that RHL1, RHL2, and RHL3 are modified by fatty acylation in intact cells.

Palmitoylation of the glucose transporter in blood-brain barrier capillaries

Palmitoylation of GLUT1 was investigated in brain capillaries. The glucose transporter was shown to be palmitoylated using [3H]palmitate labeling and immunoprecipitation. The labeling was sensitive to methanolic KOH or hydroxylamine hydrolysis, indicating the presence of an ester or thioester bond. The released fatty acid was analyzed by reverse-phase HPLC and was identified as [3H]palmitate. Specificity of the immunoprecipitation was assessed by competitive inhibition of anti-GLUT1 binding with a synthetic C-terminal peptide against which the antibody was raised. In vivo studies were performed using capillaries isolated from control rats, streptozotocin-induced diabetic rats and diet-induced hyperglycemic rats. Glycemia was increased 2- and 5-fold in the hyperglycemic and diabetic groups, respectively. GLUT1 expression was evaluated in the three groups by Western blot analysis. A 36% decrease in GLUT1 expression was observed in the diabetic group, while there was no significant variation in GLUT1 expression in the hyperglycemic group. Palmitoylation of GLUT1 was increased in both diet-induced hyperglycemic and diabetic groups. These results suggest that palmitoylation may be involved in the regulation of glucose transport activity in hyperglycemia.

Human erythrocyte membrane protein 4.2 is palmitoylated

Protein 4.2 is a major protein of the human erythrocyte membrane. It has previously been shown to be N-myristoylated. After labeling of intact human erythrocytes with [3H]palmitic acid, radioactivity was found to be associated with protein 4.2 by immunoprecipitation of peripheral membrane proteins extracted at pH 11 from ghosts with anti-(4.2) sera, followed by SDS/PAGE and fluorography. The fatty acid linked to protein 4.2 was identified as palmitic acid after hydrolysis of protein and thin-layer chromatography of the fatty acid extracted in the organic phase. Protein 4.2 could be depalmitoylated with hydroxylamine, suggesting a thioester linkage. Depalmitoylated protein 4.2 showed significantly decreased binding to protein-4.2-depleted membranes, compared to native protein 4.2.

Overview: protein palmitoylation in the nervous system: current views and unsolved problems

Palmitoylation refers to a dynamic post-translational modification of proteins involving the covalent attachment of long-chain fatty acids to the side chains of cysteine, threonine or serine residues. In recent years, palmitoylation has been identified as a widespread modification of both viral and cellular proteins. Because of its dynamic nature, protein palmitoylation, like phosphorylation, appears to have a crucial role in the functioning of the nervous system. Several important questions regarding the post-translational acylation of cysteine residues in proteins are briefly discussed: (a) What are the molecular mechanisms involved in dynamic acylation? (b) What are the determinants of the fatty acid specificity and the structural requirements of the acceptor proteins? (c) What are the physiological signals regulating this type of protein modification, and (d) What is the biological role(s) of this reaction with respect to the functioning of specific nervous system proteins? We also present the current experimental obstacles that have to be overcome to fully understand the biology of this dynamic modification.

Posttranslational acylation of the transferrin receptor in LSTRA cells with myristate, palmitate and stearate: evidence for distinct acyltransferases

When incubated with [3H]myristate or [3H]palmitate, LSTRA cells, a murine T cell line, incorporated radiolabel into a protein of 95 kDa as analyzed by SDS-polyacrylamide gel electrophoresis. This dually acylated protein was identified as the transferrin receptor by immunoprecipitation with a monoclonal anti-transferrin receptor antibody. Acylation of the transferrin receptor was posttranslational and occurred via ester or thioester linkages. Analysis of radiolabeled transferrin receptor protein from [3H]myristate-labeled cells by acid hydrolysis followed by thin layer chromatography revealed the exclusive presence of [3H]myristate. Labeled transferrin receptor protein from [3H]palmitate-labeled cells contained predominantly [3H]stearate and smaller amounts of [3H]palmitate. This is in contrast to the protein-tyrosine kinase p56lck, which in [3H]palmitate-treated LSTRA cells, incorporated primarily [3H]palmitate. An analog of myristic acid, 5-nonanyloxyfuran-2-carboxylic acid, inhibited the incorporation of [3H]myristate, but not [3H]palmitate or [3H]stearate into transferrin receptor protein, suggesting that these acylation events are distinct. These studies indicate that the murine transferrin receptor is acylated posttranslationally with myristate, palmitate and stearate and suggest that more than one acyltransferase activity is responsible for its acylation.

The process of cellular uptake of iron from transferrin. A computer simulation program

In an attempt to improve our understanding of the complex interplay between cell compartments and chemical species during cellular uptake of iron from transferrin, we designed a computer simulation program based on current models of receptor-mediated endocytosis and pinocytosis. The program calculates and visualizes, as a function of time, the changes in transferrin, apotransferrin, and iron concentrations occurring in all relevant cellular compartments during cellular iron acquisition from transferrin. Simulation of literature data showed that the program generates results that are in accordance with experimental data. Furthermore, from measurements of the uptake of [carboxyl-14C]dextran we could utilize the program to suggest rate constants characteristic for the pinocytic process in rat reticulocytes. Moreover, simulations indicate that the apparent difference in the iron uptake process observed between reticulocytes and hepatocytes may be explained by the contribution made by pinocytosis to the iron uptake process. Finally, the present program should have potential as an educational tool during introduction to the field of receptor-mediated endocytosis in general and to cellular iron metabolism in particular.

Keratinocyte transglutaminase membrane anchorage: analysis of site-directed mutants

Keratinocyte transglutaminase is anchored on the cytosolic side of the plasma membrane by fatty acid thioesterification near the amino terminus, a process which is seen to occur within 30 min of synthesis. The importance of a cluster of five cysteines (residues 47, 48, 50, 51, and 53) where acylation was presumed to occur is now demonstrated by site-directed mutagenesis. Transglutaminase mutants in which the cluster is deleted or the cysteines are all converted to alanine or serine are cytosolic. Partial replacement of the cluster, leaving two contiguous cysteines, is sufficient to confer membrane anchorage, while a single cysteine is only partially effective. As demonstrated with a soluble transglutaminase mutant, membrane anchorage confers susceptibility of the amino-terminal region to phorbol ester-stimulated phosphorylation. Attachment of 105 residues from the transglutaminase amino terminus to involucrin, a highly soluble protein, results in membrane anchorage of the hybrid protein. Attachment of the cysteine cluster alone does not result in membrane attachment of involucrin, but a 32-residue segment containing this cluster is sufficient. Stable transfectants of the human transglutaminase in mouse 3T3 cells are membrane-bound, indicating the fatty acid transacylation is not keratinocyte-specific.

The G protein alpha s subunit incorporates [3H]palmitic acid and mutation of cysteine-3 prevents this modification

We investigated whether alpha s could be acylated by palmitate by transfecting COS cells with the cDNA for the wild-type, long form of alpha s and metabolically labeling with [3H]palmitate or [35S]methionine. Cells were separated into particulate and soluble fractions and immunoprecipitated with a specific peptide antibody. [3H]Palmitate was incorporated into both endogenous and transfected alpha s. Inhibition of protein synthesis with cycloheximide did not block the radiolabeling of alpha s with [3H]palmitate. Hydroxylamine treatment caused a release of the tritium radiolabel, demonstrating that the incorporation was through a thioester bond. The tritium radiolabel was base-labile and comigrated with [3H]palmitate on thin-layer chromatography. The third residue of the wild-type alpha s was mutated from a cysteine to an alanine by site-directed mutagenesis. This mutant was expressed in COS cells and localized to the particulate fraction as determined by immunoprecipitation of the [35S]methionine-labeled cells. The cysteine-3 mutant did not undergo radiolabeling with [3H]palmitate, indicating that this residue is crucial for the modification.

The human placental transferrin receptor: reconstitution into liposomes and electron microscopy

Human transferrin receptor was isolated from Triton X-100 solubilized placental plasma membranes by a rapid one-step chromatographic procedure based on immunoadsorption of the receptor-transferrin complex on anti-transferrin Sepharose and lectin-affinity on wheat germ agglutinin. Following exchange of Triton X-100 with CHAPS or n-octylglucoside, the purified receptor was incorporated into egg phosphatidylcholine liposomes upon detergent removal by dialysis (lipid/protein ratio 15:1 to 45:1 (w/w)). Reconstitution of the receptor was confirmed by trypsin cleavage to dissociate the large extracellular receptor domain from the liposomal membranes. Electron micrographs of the receptor-lipid recombinants negatively stained with sodium sillicotungstate, showed that the receptor molecules distributed very inhomogeneously on the liposomes, most receptors being clustered. Single copies of the receptor were seen as elongate structures (5 x 10 nm) oriented with their long axis parallel to the liposome surface and separated from this by a 2-3 nm gap. This result provides evidence for a narrow connecting link between the globular extracellular receptor domain and the membrane spanning segment.

Internalization efficiency of the transferrin receptor

Quantitative ultrastructural and biochemical methods have allowed us to obtain a coherent set of data on the internalization efficiency of the transferrin receptor (TfR). In confluent cell cultures we find that (1) the initial internalization rate of transferrin is approximately 10% per minute, and (2) around 10% of cell-surface TfRs are present in coated pits. From these data a lifetime of coated pits of ca. 1 min is derived. Furthermore, we show that coated pits constitute 1.1-1.4% of the plasma membrane area in confluent cell cultures. Thus, the TfR is concentrated six- to ninefold in coated pits compared to resident plasma membrane proteins. Moreover, we show that the concentration of TfRs in coated pits is cell density dependent, since only around 5% of the receptors are present in coated pits in low-density cultures. Correspondingly, the internalization of TfRs in high-density cell cultures is roughly twice as efficient as that in low-density cell cultures. The reduced TfR internalization efficiency at low cell density is accounted for by a concomitant decrease to 0.55% in the relative surface area occupied by coated pits.

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.