Digitalis-induced cell stimulation : Support for a two-receptor model

Digitalis glycosides are potent polyclonal B cell activators in digitalis-resistant species. The stimulatory capacity is not mediated via their interaction with Na⁺, K⁺ ATPase (EC 3.6.1.3) but is due to binding to a distinct mitogen receptor located in the cell membrane. Potassium was found to influence the dose-response profile of digitalis-induced mitogenesis, thus suggesting a physiological relationship between the stimulating receptor on lymphoid cells and the Na⁺, K⁺ ATPase.     

Characterization of pneumolysin from Streptococcus pneumoniae,interacting with carbohydrate moiety and cholesterol as a component of cell membrane

The cytolytic mechanism of cholesterol-dependent cytolysins (CDCs) requires the presence of cholesterol in the target cell membrane. Membrane cholesterol was thought to serve as the common receptor for these toxins, but not all CDCs require cholesterol for binding. One member of this toxin family, pneumolysin (PLY) is a major virulence factor of Streptococcus pneumoniae, and the mechanism via which PLY binds to its putative receptor or cholesterol on the cell membrane is still poorly understood. Here, we demonstrated that PLY interacted with carbohydrate moiety and cholesterol as a component of the cell membrane, using the inhibitory effect of hemolytic activity. The hemolytic activity of PLY was inhibited by cholesterol-MβCD, which is in a 3β configuration at the C3-hydroxy group, but is not in a 3α-configuration. In the interaction between PLY and carbohydrate moiety, the mannose showed a dose-dependent increase in the inhibition of PLY hemolytic activity. The binding ability of mannose with truncated PLYs, as determined by the pull-down assay, showed that mannose might favor binding to domain 4 rather than domains 1–3. These studies provide a new model for the mechanism of cellular recognition by PLY, as well as a foundation for future investigations into whether non-sterol molecules can serve as receptors for other members of the CDC family of toxins.     

Regulation of the SHP-2 tyrosine phosphatase by a novel cholesterol- and cell confluence-dependent mechanism

Endothelial cells approaching confluence exhibit marked decreases in tyrosine phosphorylation of receptor tyrosine kinases and adherens junctions proteins, required for cell cycle arrest and adherens junctions stability. Recently, we demonstrated a close correlation in endothelial cells between membrane cholesterol and tyrosine phosphorylation of adherens junctions proteins. Here, we probe the mechanistic basis for this correlation. We find that as endothelial cells reach confluence, the tyrosine phosphatase SHP-2 is recruited to a low-density membrane fraction in a cholesterol-dependent manner. Binding of SHP-2 to this fraction was not abolished by phenyl phosphate, strongly suggesting that this binding was mediated by other regions of SHP-2 beside its SH2 domains. Annexin II, previously implicated in cholesterol trafficking, was associated in a complex with SHP-2, and both proteins localized to adhesion bands in confluent endothelial monolayers. These studies reveal a novel, cholesterol-dependent mechanism for the recruitment of signaling proteins to specific plasma membrane domains via their interactions with annexin II.     

A novel cholesterol‐insensitive mode of membrane binding promotes cytolysin‐mediated translocation by Streptolysin O

Cytolysin‐mediated translocation (CMT), performed by Streptococcus pyogenes, utilizes the cholesterol‐dependent cytolysin Streptolysin O (SLO) to translocate the NAD⁺‐glycohydrolase (SPN) into the host cell during infection. SLO is required for CMT and can accomplish this activity without pore formation, but the details of SLO's interaction with the membrane preceding SPN translocation are unknown. Analysis of binding domain mutants of SLO and binding domain swaps between SLO and homologous cholesterol‐dependent cytolysins revealed that membrane binding by SLO is necessary but not sufficient for CMT, demonstrating a specific requirement for SLO in this process. Despite being the only known receptor for SLO, this membrane interaction does not require cholesterol. Depletion of cholesterol from host membranes and mutation of SLO's cholesterol recognition motif abolished pore formation but did not inhibit membrane binding or CMT. Surprisingly, SLO requires the coexpression and membrane localization of SPN to achieve cholesterol‐insensitive membrane binding; in the absence of SPN, SLO's binding is characteristically cholesterol‐dependent. SPN's membrane localization also requires SLO, suggesting a co‐dependent, cholesterol‐insensitive mechanism of membrane binding occurs, resulting in SPN translocation.     

Binding of high density lipoproteins to cell receptors promotes translocation of cholesterol from intracellular membranes to the cell surface

Cultured cells have on their cell surface a specific high-affinity binding site (receptor) for high density lipoproteins (HDL) which appears to promote cholesterol efflux. In this study we characterized the cellular mechanisms involved in HDL receptor-mediated transport of cholesterol from cultured human fibroblasts and bovine aortic endothelial cells. HDL3, chemically modified by tetranitromethane (TNM-HDL3), is not recognized by this receptor and was used as a control for efflux not mediated by HDL receptor binding. HDL3 and TNM-HDL3 were found to be equally effective in causing efflux of plasma membrane cholesterol radiolabeled with [3H]cholesterol. However, HDL3 was much more effective than TNM-HDL3 in causing efflux of [3H]cholesterol associated with intracellular membranes. By measuring movement of endogenously synthesized [3H]cholesterol to the plasma membrane, and into the medium, we found that HDL3 induced a rapid movement of [3H]cholesterol from a preplasma membrane compartment to the plasma membrane that preceded [3H]cholesterol efflux. This effect was not observed with TNM-HDL3. Thus, receptor binding of HDL3 appears to facilitate removal of cellular cholesterol from specific intracellular pools by initiation of translocation of intracellular cholesterol to the plasma membrane.     

Membrane effects of the polyene antibiotic amphotericin B and of some of its derivatives on lymphocytes

Amphotericin B (AmB) exhibits immunomodulating properties in mice.In vitro studies on lymphocytes, in relation with these properties, are reported here with AmB and two of its derivatives: the N-Fructosyl (N-Fru AmB) and the N-thiopropionyl (AmBSH) derivatives. Interactions of these molecules with thymocytes, a sensitive cell type, demonstrated that the extent of binding is not a toxicity parameter. In contrast, membrane fludity changes have been observed and appeared to be related to toxicity.Experiments performed with normal B lymphocytes have shown that Amphotericin B derivatives were more potent polyclonal B cell activators than the parent compound. To go further in the understanding of these events, we have investigated in a B cell line WEHI 231, the changes in intracellular Ca²⁺ and membrane potential induced by AmB and AmBSH. The two polyenes were shown to induce membrane depolarization but no intracellular Ca²⁺ increase.     

Reduced uptake of cholesterol esterase-modified low density lipoprotein by macrophages.

Changes in low density lipoprotein (LDL) lipid composition were shown to alter its interaction with the LDL receptor, thus affecting its cellular uptake. Upon incubation of LDL with 5 units/ml cholesterol esterase (CEase) for 1 h at 37 degrees C, there was a 33% reduction in lipoprotein cholesteryl ester content, paralleled by an increment in its unesterified cholesterol. CEase-LDL, in comparison to native LDL, was smaller in size, possessed fewer free lysine amino groups (by 14%), and demonstrated reduced binding to heparin (by 83%) and reduced immunoreactivity against monoclonal antibodies directed toward epitopes along the LDL apoB-100. Incubation of CEase-LDL with the J-774 macrophage-like cell line resulted in about a 30% reduction in lipoprotein binding and degradation in comparison to native LDL, and this was associated with a 20% reduction in macrophage cholesterol mass. Similarly, CEase-LDL degradation by mouse peritoneal macrophages, human monocyte-derived macrophages, and human skin fibroblasts was reduced by 20-44% in comparison to native LDL. CEase-LDL uptake by macrophages was mediated via the LDL receptor and not the scavenger receptor. CEase activity toward LDL was demonstrated in plasma and in cells of the arterial wall such as macrophages and endothelial cells. Thus, CEase modification of LDL may take place in vivo, and this phenomenon may have a role in atherosclerosis.     

Membrane and protein interactions of oxysterols

PURPOSE OF REVIEW: Oxysterols, oxidation products of cholesterol, mediate numerous and diverse biological processes. The objective of this review is to explain some of the biochemical and cell biological properties of oxysterols based on their membrane biophysical properties and their interaction with integral and peripheral membrane proteins. RECENT FINDINGS: According to their biophysical properties, which can be distinct from those of cholesterol, oxysterols can promote or inhibit the formation of membrane microdomains or lipid rafts. Oxysterols that inhibit raft formation are cytotoxic. The stereo-specific binding of cholesterol to sterol-sensing domains in cholesterol homeostatic pathways is not duplicated by oxysterols, and some oxysterols are poor substrates for the pathways that detoxify cells of excess cholesterol. The cytotoxic roles of oxysterols are, at least partly, due to a direct physical effect on membranes involved in cholesterol-induced cell apoptosis and raft mediated cell signaling. Oxysterols regulate cellular functions by binding to oxysterol binding protein and oxysterol binding protein-related proteins. Oxysterol binding protein is a sterol-dependent scaffolding protein that regulates the extracellular signal-regulated kinase signaling pathway. According to a recently solved structure for a yeast oxysterol binding protein-related protein, Osh4, some members of this large family of proteins are likely sterol transporters. SUMMARY: Given the association of some oxysterols with atherosclerosis, it is important to identify the mechanisms by which their association with cell membranes and intracellular proteins controls membrane structure and properties and intracellular signaling and metabolism. Studies on oxysterol binding protein and oxysterol binding protein-related proteins should lead to new understandings about sterol-regulated signal transduction and membrane trafficking pathways in cells.     

Membrane cholesterol modulates serotonin transporter activity

The synaptic actions of the neurotransmitter serotonin are terminated by a selective high-affinity reuptake mediated by the serotonin transporter (SERT). To gain insight into the modulation of the functional properties of this integral membrane protein by cholesterol, a main component of the lipid bilayer, we stably expressed the rat SERT in human embryonic kidney 293 cells and, upon altering the cholesterol content of these cells by different means, analyzed SERT activity. Depletion of the level of membrane cholesterol by treatment with either the cholesterol chelating agent methyl-beta-cyclodextrin (MbetaCD), cholesterol oxidase, or the cholesterol-binding fluorochrome filipin resulted in a decrease in SERT activity due to both a loss of affinity of substrate and ligand binding and a concomitant reduction of the maximal transport rate. In cholesterol-depleted membranes, cholesterol levels could be restored to those found in untreated membranes by incubation of the membranes with an MbetaCD-cholesterol complex, which correlated with a reversal of the cholesterol depletion-mediated decrease in the level of high-affinity binding. This was not the case when other steroids, such as ergosterol, 5-cholestene, or pregnenolone, were substituted into cholesterol-depleted membranes. These results suggest that membrane cholesterol modulates the functional properties of the SERT by specific molecular interactions which are needed to stabilize the transporter in its optimally active form.     

Forces Required to Initiate Membrane Tether Extrusion from Cell Surface Depend on Cell Type But Not on the Surface Molecule

When a cell adhered to another cell or substratum via surface proteins is forced to detach, lipid membrane tethers are often extruded from the cell surface before the protein bond dissociates. For example, during the inflammatory reaction leukocytes roll on the surface of activated endothelial cells. The rolling adhesion is mediated by interactions of selectins with their ligands, e.g., P-selectin glycoprotein ligand (PSGL)-1, which extrudes membrane tethers from the surfaces of both leukocytes and endothelial cells. Membrane tether extrusion has been suggested to regulate leukocyte rolling. Here we examine several factors that may affect forces required to initiate membrane tethers, or initial tether force. It was found that initial tether forces were similar regardless of the presence or absence of the cytoplasmic tail of P-selectin and regardless of whether the tethers were extruded via binding to PSGL-1 or Fcγ receptors. Initial tether forces were found to depend on the cell types tested and were greatly reduced by treatment of latrunculin A, which inhibits actin polymerization. These data provide additional insights to the control of membrane tether extrusion, which should be taken into account when cellular functions such as rolling where tether extrusion plays a regulatory role are compared using different cell types expressing the same molecule.     

A macrophage receptor for (mannose/glucosamine)-glycoproteins of potential importance in phagocytic activity

Lung macrophages, in the absence of serum factors in vitro, strongly bound and ingested yeast cells ($\text{Candida}\text{krusei}$ and zymosan). Binding was temperature-and calcium-dependent, and was inhibited by the presence of D-mannose, D-glucosamine, horseradish peroxidase and beta-glucuronidase. Pretrypsinization of the macrophages also prevented binding of yeast cells. Binding was not affected by D-mannitol, D-glucose, D-galactose nor L-fucose. I suggest that macrophage binding of yeast cells is mediated by a mannose/glucosamine receptor on the cell membrane. This receptor may be responsible for opsosin-independent phagocytosis of activators of the alternative complement pathway and, as well, the phagocyte-dependent clearance of certain lysosomal enzymes.     

Membrane cholesterol modulates galanin-GalR2 interaction.

The neuropeptide galanin mediates a number of diverse physiological and pathophysiological actions via interaction with membrane-bound receptors. The role that membrane cholesterol plays in modulating the interaction between galanin and one of the three cloned galanin receptor subtypes (GalR2) expressed in Chinese hamster ovary (CHO) cells was examined. Reduction of membrane cholesterol by treatment with methyl-beta-cyclodextrin (CD) or by culturing cells in lipoprotein-deficient serum markedly decreased galanin binding to the receptor. Addition of cholesterol back to CD-treated, cholesterol-depleted membranes restored galanin binding to control levels. Hill analysis suggests that the GalR2 binds multiple molecules of cholesterol (n >/= 3) in a positively cooperative manner. This interaction appears to be cholesterol-specific as only cholesterol and a limited number of cholesterol analogues were able to rescue galanin binding. The inability of some of these analogues to rescue the binding activity also suggests that binding of galanin to GalR2 is independent of membrane fluidity as, like cholesterol, cholesterol analogues generally rigidize membranes. In addition, treatment of the membranes with other modulators of membrane fluidity, e.g. ethanol, did not affect galanin binding to the GalR2. In contrast, treatment of membranes, with filipin, a molecule that clusters cholesterol within the membranes, or with cholesterol oxidase resulted in markedly reduced galanin binding. Incubation of membranes with 100 microM GTP-gamma-S did not alter the IC(50) for CD in the prebinding assay treatment suggesting that the effect of cholesterol was independent of G protein interaction. Preincubation of intact cells with CD also drastically impaired the ability of galanin to activate intracellular inositol phosphate accumulation in GalR2-transfected CHO cells. These data detail a new mechanism for the regulation of galanin receptor signaling which may link altered functions of GalRs with abnormal cholesterol metabolism.     

Identification and characterization of a high density lipoprotein-binding protein in cell membranes by ligand blotting

Cholesterol efflux from cultured cells can be mediated through binding of high density lipoprotein (HDL) to a cell-surface site which shows many characteristics of a biological receptor. To determine whether a specific protein forms a component of this site, cell membrane proteins were analyzed by ligand blotting using 125I-HDL3. Results demonstrated that membranes from a number of cell types possess a protein with an apparent molecular mass of 110 kDa that binds HDL and apoA-I and apoA-II proteoliposomes, but not low density lipoprotein, acetylated low density lipoprotein, or apoE proteoliposomes. The binding activity of this protein was increased by loading cells with cholesterol and was abolished by trypsin treatment of intact cell monolayers. These results suggest that HDL binds with specificity to a cell-surface protein which is regulated by intracellular cholesterol levels. Since HDL binding to intact cell monolayers shows the same characteristics, the 110-kDa binding protein may represent the proposed HDL receptor that functions to facilitate transport of cholesterol from cells to HDL particles.     

Interaction of amphotericin B and its N-fructosyl derivative with murine thymocytes: a comparative study using fluorescent membrane probes

The polyene antibiotics amphotericin B (AmB) and N-(1-deoxy-D-fructos-1-yl)amphotericin (N-Fru-AmB) have different activity towards murine thymocytes (N-Fru-AmB is less toxic but is a potent immunomodulator). The interactions of the drugs with these cells have been studied by fluorescence methods. Fluorescence energy transfer from 1-[4-(trimethylammonio) phenyl]-6-phenylhexa-1,3,5-triene, p-toluenesulfonate (TMA-DPH) to polyenes was used to follow the binding of the two drugs to the plasma membrane. The results, confirmed by circular dichroism measurements, indicate that at saturation the ratio AmB bound/plasma membrane lipid is low (less than 1 molecule of polyene for 170 lipids). The slightly higher binding of AmB as compared to N-Fru-AmB demonstrates that affinity of the antibiotic for plasma membrane does not account for the activity of the polyenes towards lymphocytes. The effect of the two polyenes on membrane fluidity was studied by steady-state fluorescence anisotropy. The results suggest that AmB strongly perturbs the structure of the membrane whereas only a slight decrease of the anisotropy is observed with N-Fru-AmB in the range of concentration where the biological activity has been demonstrated. Polyene location was further investigated by comparing the energy transfer efficiency obtained with TMA-DPH and with the parental compound 1,6-diphenylhexa-1,3,5-triene, p-toluene sulfonate (DPH). While AmB binds to plasma membrane, as well as to intracellular structures, N-Fru-AmB seems to accumulate into the cell and bind to intracellular membrane structures.     

Dissociation kinetics and equilibrium binding properties of polyene antibiotic complexes with phosphatidylcholine/sterol vesicles

The interactions of sonicated vesicles with the polyene antibiotics amphotericin B, candicidin, mediocidin , and a water-soluble, guanidine derivative of amphotericin B were examined by UV-visible spectroscopy at concentrations below which the polyenes become self-associated. The association constants, Kapp, and the numbers of binding sites per sterol or phospholipid molecule (n) were determined at 30 degrees C and pH 7.4. A single class of binding sites was found, with no evidence of cooperativity. For the binding of mediocidin , amphotericin B, and the guanidine derivative with phosphatidylcholine (PC), PC/cholesterol, and PC/ergosterol vesicles, Kapp was in the range of (1.0-3.0) X 10(6) M-1; Kapp was higher for candicidin-vesicle interaction, reaching 9.0 X 10(6) M-1 with PC/ergosterol vesicles. Binding of the guanidine derivative of amphotericin B to PC vesicles lacking sterol was extensive (n = 0.46); since the other polyenes, which have low aqueous solubilities, had n less than 0.05, positive charges in the mycosamine moiety appear to enhance the extent of polyene antibiotic interaction with the glycerophospholipid head group. Higher values of n (and, therefore, of nKapp ) were found with sterol-containing than with sterol-free vesicles, suggestive of penetration of the polyenes toward the interior of the bilayer when sterol is present. For binding to PC/sterol vesicles, nKapp followed the order of candicidin greater than guanidine derivative of amphotericin B greater than amphotericin B much greater than mediocidin . The values of n and nKapp were appreciably higher for amphotericin B-ergosterol than for amphotericin B-cholesterol interaction in vesicles.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cholesterol depletion inhibits fatty acid uptake without affecting CD36 or caveolin-1 distribution in adipocytes

Caveolin-1 and CD36 are plasma membrane fatty acid binding proteins that participate in adipocyte fatty acid uptake and metabolism. Both are associated with cholesterol-enriched caveolae/lipid rafts in the plasma membrane that are important for long chain fatty acid uptake. Depletion of plasma membrane cholesterol reversibly inhibited oleate uptake by adipocytes without altering the amount or the cell surface distribution of either caveolin-1 or CD36. Cholesterol levels thus regulate fatty acid uptake by adipocytes via a pathway that does not involve altered cell surface localization of caveolin-1 or CD36.     

Kinetics of MHC-CD8 interaction at the T cell membrane

CD8 plays an important role in facilitating TCR-MHC interaction, promoting Ag recognition, and initiating T cell activation. MHC-CD8 binding kinetics have been measured in three dimensions by surface plasmon resonance technique using purified molecules. However, CD8 is a membrane-anchored, signaling kinase-linked, and TCR-associated molecule whose function depends on the cell membrane environment. Purified molecules lack their linkage to the membrane, which precludes interactions with other structures of the cell as well as signaling. Furthermore, three-dimensional binding in the fluid phase is biologically and physically distinct from two-dimensional binding across apposing cell membranes. As a first step toward characterizing the molecular interactions between T cells and APCs, we used a micropipette adhesion frequency assay to measure the adhesion kinetics of single mouse T cells interacting with single human RBCs coated with MHC. Using anti-TCR mAb we isolated and characterized the specific two-dimensional MHC-CD8 binding from the trimolecular TCR-MHC-CD8 interaction. The TCR-independent MHC-CD8 interaction has a very low affinity that depends on the MHC alleles, but not on the peptide complexed to the MHC and whether CD8 is an alphaalpha homodimer or an alphabeta heterodimer. Surprisingly, MHC-CD8 binding affinity varies with T cells from different TCR transgenic mice and these affinity differences were abolished by treatment with cholesterol oxidase to disrupt membrane rafts. These data highlight the relevance and importance of two-dimensional analysis of T cells and APCs and indicate that membrane rafts play an important role in modulating the affinity of cell-cell interactions.