Theory of the Sphering of Red Blood Cells

A rigorous mathematical solution of the sphering of a red blood cell is obtained under the assumptions that the red cells is a fluid-filled shell and that it can swell into a perfect sphere in an appropriate hypotonic medium. The solution is valid for finite strain of the cell membrane provided that the membrane is isotropic, elastic and incompressible. The most general nonlinear elastic stress-strain law for the membrane in a state of generalized plane stress is used. A necessary condition for a red cell to be able to sphere is that its extensional stiffness follow a specific distribution over the membrane. This distribution is strongly influenced by the surface tension in the cell membrane. A unique relation exists between the extensional stiffness, pressure differential, surface tension, and the ratio of the radius of the sphere to that of the undeformed red cell. The functional dependence of this stiffness distribution on various physical parameters is presented. A critique of some current literature on red cell mechanics is presented.     

Molecular structure of the beta-adrenergic receptor

The beta-adrenergic receptor from several tissues has been purified to homogeneity or photoaffinity radiolabeled and its subunit molecular weight determined by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. In this study we have examined the oligomeric structure of nondenatured beta 1- and beta 2-adrenergic receptor proteins, as solubilized with the detergent digitonin. Model systems used were frog and turkey red blood cell as well as rat, rabbit, and bovine lung plasma membrane preparations. To correct for the effects of detergent binding, sedimentation equilibrium analysis in various solvents, as adapted for the air-driven ultracentrifuge, was used. With this approach an estimate of 6 g of digitonin/g of protein binding was determined, corresponding to a ratio of 180 mol of digitonin/mol of protein. Protein molecular weights estimated by this method were 43 500 for the turkey red blood cell beta 1 receptor and 54 000 for the frog red blood cell beta 2 receptor. Molecular weights of 60 000-65 000 were estimated for beta 1 and beta 2 receptors present in mammalian lungs. These values agree with estimates of subunit molecular weight obtained by SDS gel electrophoresis of purified or photoradiolabeled preparations and suggest beta-adrenergic receptors to be digitonin solubilized from the membrane as single polypeptide chains.     

Association of sequestered beta-adrenergic receptors with the plasma membrane: a novel mechanism for receptor down regulation

Chronic exposure of frog erythrocytes to beta-adrenergic agonists leads to desensitization of the responsiveness of adenylate cyclase to isoproterenol and is accompanied by "down-regulation", a decrease in the number of beta-adrenergic receptors on the cell surface. When frog erythrocyte plasma membranes are prepared by osmotic lysis of cells, the receptors lost from the cell surface during desensitization can be recovered in a "light membrane fraction", obtained by centrifuging the cell cytosol at 158,000 X g for 1 hr. These receptors are sequestered away from the plasma membrane fraction which contains the adenylate cyclase and the guanine nucleotide regulatory protein. If desensitized frog erythrocytes are disrupted by gentler freeze/thaw procedures, however, the sequestered beta-adrenergic receptors can be demonstrated to be physically associated with the plasma membrane. Typically, plasma membranes prepared in this fashion do not demonstrate a significant down regulation despite attenuation of isoproterenol-stimulated adenylate cyclase activity. Under these conditions, beta-adrenergic receptors from control and desensitized preparations co-migrate on sucrose density gradients in exactly the same place as the plasma membrane marker, adenylate cyclase. In contrast, when membranes from osmotically lysed desensitized cells are fractionated on sucrose gradients the down regulated receptors are sequestered in a light membrane fraction which barely enters the gradient and which is physically separated from adenylate cyclase activity. The data are consistent with a novel mechanism of receptor down-regulation which appears to involve the sequestration of the beta-adrenergic receptors away from the cell surface into a membrane compartment which remains physically associated with the plasma membrane.     

The biology of beta-adrenergic receptors: analysis in human epidermoid carcinoma A431 cells.

1. G-protein-linked transmembrane signaling has emerged as a major pathway for information transduction across the cell membrane. 2. In addition to photopigments that propagate the signal from light, cell-surface receptors for hormones, neurotransmitters, and autacoids propagate signals from ligand binding to membrane-bound effector units via G-proteins. 3. Biochemical and molecular features of one prominent member of these receptors, the beta-adrenergic receptor, will be highlighted in the present article. 4. The role of the human epidermoid carcinoma A431 cells as a model for the study of the structure and biology of beta-adrenergic receptors will be emphasized. 5. A model for receptor regulation, gleaned from recent advances in the biochemistry, cell and molecular biology of beta-adrenergic receptors, is discussed.     

Protein and lipid trafficking induced in erythrocytes infected by malaria parasites

The human malaria parasite Plasmodium falciparum develops in a parasitophorous vacuolar membrane (PVM) within the mature red cell and extensively modifies structural and antigenic properties of this host cell. Recent studies shed significant new, mechanistic perspective on the underlying processes. There is finally, definitive evidence that despite the absence of endocytosis, transmembrane proteins in the host red cell membrane are imported in to the PVM. These are not major erythrocyte proteins but components that reside in detergent resistant membrane (DRM) rafts in red cell membrane and are detected in rafts in the PVM. Disruption of either erythrocyte or vacuolar rafts is detrimental to infection suggesting that raft proteins and lipids are essential for the parasitization of the red cell. On secretory export of parasite proteins: an ER secretory signal (SS) sequence is required for protein secretion to the PV. Proteins carrying an additional plastid targeting sequence (PTS) are also detected in the PV but subsequently delivered to the plastid organelle within the parasite, suggesting that the PTS may have a second function as an endocytic sorting signal. A distinct but yet undefined peptidic motif underlies protein transport across the PVM to the red cell (although all of the published data does not yet fit this model). Further multiple exported proteins transit through secretory 'cleft' structures, suggesting that clefts may be sorting compartments assembled by the parasite in the red cell.     

Characterization of an altered membrane form of the beta-adrenergic receptor produced during agonist-induced desensitization

Incubation of 1321N1 human astrocytoma cells with 1 microM isoproterenol rapidly results in the conversion of a portion of the beta-adrenergic receptors to a membrane form that can be separated from markers for the plasma membrane by sucrose density gradient or differential centrifugation. This "light peak" form of the receptor reaches a maximal level within 10 min of incubation of cells with catecholamine. Two types of experiments suggest that the early phase of catecholamine-induced desensitization of the beta-adrenergic receptor-linked adenylate cyclase can be separated into at least two reactions. First, the agonist-induced loss of catecholamine-stimulated adenylate cyclase activity precedes the appearance of beta-adrenergic receptors in the light peak fraction by 1-2 min. Second, pretreatment of cells with concanavalin A prior to induction of desensitization blocks the formation of the light peak form of beta-adrenergic receptors without blocking the "uncoupling" reaction as measured by catecholamine-stimulated adenylate cyclase activity. Specificity for the reaction that converts beta-adrenergic receptors to the light peak form is indicated by the lack of a catecholamine-induced alteration in the sucrose density gradient distribution of muscarinic cholinergic receptors, adenylate cyclase or the guanine nucleotide-binding proteins, Ns and Ni. The light peak of beta-adrenergic receptors migrates at a density similar to that of at least a portion of the activity of galactosyltransferase, a marker for Golgi. Enzyme marker activities for lysosomes and endoplasmic reticulum are not associated with this population of beta-adrenergic receptors. Taken together, these and other data suggest that incubation of 1321N1 cells with isoproterenol results in a rapid uncoupling of beta-adrenergic receptors from adenylate cyclase which is followed by a change in the membrane form of the receptor. This latter step most likely represents internalization of receptors into a vesicular form which may then serve as the precursor state from which receptors are eventually lost from the cell.     

Red cell membrane lipids in hemoglobinopathies

The complex mixture of lipids and proteins of the red blood cell membrane is well maintained during the life of the cell. Lipid analysis of the red cell reveals hundreds of phospholipid molecular species and cholesterol that differ with respect to their (polar) head group, and (apolar) side chains. These molecules move rapidly in the plane, as well as across the lipid bilayer. This dynamic movement is highly organized. In the plane of the bilayer, areas enriched in certain lipids accommodate protein structure and modulate function. While lipids move across the bilayer, the organization is highly asymmetric. Amino phospholipids are mainly found on the inside and choline containing phospholipids on the outside. Both the composition and organization of the red cell membrane is maintained throughout the life of the red cell by an intricate mechanism that involves enzymes, transporters and cytosolic factors. Key proteins that maintain red blood cell lipid organization have recently been identified. Alterations in these mechanisms, as the result of the globin mutations in sickle cell disease or thalassemia will lead to loss of membrane viability, apoptosis during erythropoiesis, early demise of the cell in the circulation, and when these cells are not removed appropriately their presence has pathologic consequences.     

The hepatic adrenergic receptors

Summary The presence of both alpha- and beta-adrenergic receptors in liver designated the hepatic plasma membrane as a useful tool for the elucidation of the mechanisms by which the hormonal signal is transfered through the membrane via a coupling system to an amplifying entity. This process is well documented for the beta-adrenergic receptor which is linked to adenylate cyclase, whereby it modulates the cyclic AMP level. Much less is known about the alpha-adrenergic receptor.Recently, two factors have contributed to a renewed interest in alpha- and beta-adrenergic receptors in liver: i) The fact that activation of glycogenolysis in isolated liver parenchymall cells by epinephrine may be mediated by either alpha- or beta-adrenergic receptors, depending on the species or on the state of nutrition, and not only by beta-adrenergic receptors as previously thought. ii) The existence of specific adrenergic agonists and antagonists radiolabeled to a high specific activity which has permitted the characterization of adrenergic receptors in terms of nature, number, affinity and regulation.The present review will be devoted to the recent progress made in the physiological, pharmacological and biochemical characterization of alpha- and beta-adrenergic receptors in the liver.     

Quantitation of the guanine nucleotide binding regulatory protein Gs in S49 cell membranes using antipeptide antibodies to alpha s

Polyclonal antibodies reactive against the guanine nucleotide binding stimulatory protein, Gs, were affinity-purified from two rabbits immunized with a synthetic peptide corresponding to amino acids 28-42 in the alpha-subunit, alpha s. On immunoblots, these antibodies recognized alpha s, but not alpha-subunits from two other guanine nucleotide binding regulatory proteins, Gi and Go. A competitive enzyme-linked immunosorbent assay was developed in which inhibition of antibody binding to peptide-coated microtiter plates was used to quantitate purified Gs or Gs in cholate extracts of cell membranes. Plasma membranes derived from wild type S49 lymphoma cells contained 18.9 +/- 2.3 pmol/mg of membrane protein of alpha s. The same membranes bound 169 +/- 12 fmol/mg of protein of [125I]iodocyanopindolol to beta-adrenergic receptors, indicating that the amount of Gs is far in excess of the amount of beta-adrenergic receptors. Thus, even if every beta-adrenergic receptor molecule were to activate 10 Gs molecules, in order for Gs to be limiting for the receptors to reach their high affinity state, it is likely that compartmentation exists for target cell membrane receptors and Gs. Moreover, a comparison of beta-adrenergic receptor number and Gs levels in several different S49 lymphoma cell mutants having lesions in receptors or Gs argues against a coordinate regulation of beta-adrenergic receptors and Gs.     

Subunit dissociation is the mechanism for hormonal activation of the Gs protein in native membranes

We have recently reported (Ransn?s, L.A., and Insel, P.A. (1988) J. Biol. Chem. 263, 9482-9485) development of antipeptide antibodies to the alpha s protein of the stimulatory guanine nucleotide binding regulatory protein, Gs, and use of one of these antibodies, GS-1, to quantitate Gs levels in S49 lymphoma cell membranes. Another of these antibodies, termed GS-2, appears to detect only dissociated alpha s, but not the heterotrimer alpha s beta gamma. Using a competitive enzyme-linked immunosorbent assay, we have found that the guanine nucleotides GTP and guanosine 5'-O-(thiotriphosphate) (GTP gamma S) (but not GDP) and the beta-adrenergic receptor agonist isoproterenol activate Gs in native S49 cell membrane by subunit dissociation. Evidence for this includes detection of dissociated alpha s in membrane extracts and release of alpha s from S49 cell membranes treated with GTP gamma S or isoproterenol. Moreover, the estimates of apparent stoichiometry for this dissociation indicate that each beta-adrenergic receptor is able to activate greater than or equal to 100 molecules of Gs in native membranes. Thus, receptor-mediated dissociation of Gs is likely to be the major site of amplification of signal transduction by agonists active at hormone receptors that link to Gs.     

Functional anatomy of the Arabidopsis cytokinesis-specific syntaxin KNOLLE

In plant cytokinesis, Golgi/trans-Golgi network-derived vesicles are targeted to the plane of cell division where they fuse with one another to form the partitioning membrane (cell plate). This membrane fusion requires a specialised syntaxin (Qa-SNARE), named KNOLLE in Arabidopsis. KNOLLE is only made during the M-phase of the cell cycle, targeted to the plane of cell division and degraded in the vacuole at the end of cytokinesis. To identify the parts of KNOLLE required for proper targeting and function in membrane fusion, we generated chimeric syntaxins comprising complementary fragments from KNOLLE and MVB-localized PEP12 (SYP21). Surprisingly, targeting of the chimeric protein was not specified by the C-terminal membrane anchor. Rather the N-terminal region including helix Ha and the adjacent linker to helix Hb appeared to played a critical role. However, deletion of this N-terminal fragment from KNOLLE (KN(Δ1-82) ) had the same effect as its presence in the chimeric protein (KN(1-82) -PEP12(64-279) ), suggesting that targeting to the plane of cell division occurs by default, i.e. when no sorting signal would target the syntaxin to a specific endomembrane compartment. Once the full-length syntaxin accumulated at the plane of division, phenotypic rescue of the knolle mutant only required the SNARE domain plus the adjacent linker connecting helix Hc to the SNARE domain from KNOLLE. Our results suggest that targeting of syntaxin to the plane of cell division occurs without active sorting, whereas syntaxin-mediated membrane fusion requires sequence-specific features.     

Regulation of beta-adrenergic receptors and calcium channel agonist binding sites in cultured human embryonal smooth muscle cells

Recent electrophysiological studies with cell membrane patches of cardiac myocytes and an electrically excitable cell line derived from rat pituitary tumor suggested that voltage activated calcium channels must be phosphorylated to respond to membrane depolarization (Armstrong and Eckert 1986; Trautwein and Kameyama 1986). In view of the "phosphorylation hypothesis" we investigated the adenylate-cyclase activity, the characteristics of beta-adrenergic and calcium channel agonist binding sites in control and desensitized (exposure to isoproterenol) human embryonal cells (HEC), and in fragmented membrane preparations of canine coronary smooth muscle. Our results suggest that down-regulation of the membrane-bound beta-adrenergic receptors, induced by isoproterenol in human embryonal cells and also in adult canine vascular tissue, results in physical translocation of beta-adrenergic binding sites into the light membrane fraction. This phenomenon is accompanied with an increased intracellular concentration of cAMP in and an increased binding of the calcium channel agonist (3H) BAYK 8644 to both HEC and canine smooth muscle membrane preparations. It could be concluded that phosphorylation of beta-adrenergic receptors regulates not only the beta subcellular distribution of the beta receptors but also the availability of calcium channel agonist binding sites in the cellular membrane.     

Topo-optical reactions on the membrane of the human red cell ghost (author's transl)]

Previous studies have proved that the thiazin dyes toluidine blue, azure A, azure B, 1.9-dimethyl methylene blue and the quinolin dyes N,N'-diethylpseudoisocyanine chloride, N,N'-6,6'-dichlorpseudoisocyanine chloride are suitable for topo-optical reaction on the membrane of the red blood cells. In the present study the applicability of the thiazin and quinolin dyes on the membrane of the human red cell ghost was examined. Optical analysis revealed that the thiazin dyes are bound in radial position to the membrane, while the quinolin dyes are bound parallel to the membrane's plane.     

The membrane skeleton--a distinct structure that regulates the function of cells

It has long been known that the red blood cell contains a membrane skeleton that stabilizes the plasma membrane, determines its shape, and regulates the lateral distribution of the membrane glyco-proteins to which it is attached. The way in which these functions are regulated in other cells has not been understood. It has now been shown that platelets also contain a membrane skeleton. In contrast to the membrane skeleton of the red blood cell, the platelet membrane skeleton has actin-binding protein, not spectrin, as a major component. The platelet membrane skeleton regulates the same cellular functions as the red blood cell membrane skeleton. Other cells may contain a membrane skeleton that is critical to their viability and normal functioning.     

Neutrophil chemoattractant receptors and the membrane skeleton

Signal transduction via receptors for N-formylmethionyl peptide chemoattractants (FPR) on human neutrophils is a highly regulated process which involves participation of cytoskeletal elements. Evidence exists suggesting that the cytoskeleton and/or the membrane skeleton controls the distribution of FPR in the plane of the plasma membrane, thus controlling the accessibility of FPR to different proteins in functionally distinct domains. In desensitized cells, FPR are restricted to domains which are depleted of G proteins but enriched in cytoskeletal proteins such as actin and fodrin. Thus, the G protein signal transduction partners of FPR become inaccessible to the agonist-occupied receptor, preventing cell activation. The mechanism of interaction of FPR with the membrane skeleton is poorly understood but evidence is accumulating that suggests a direct binding of FPR (and other receptors) to cytoskeletal proteins such as actin.     

Experimental conditions influence [3H]-dihydroalprenolol binding characteristics to living HeLa cells due to morphological changes: a warning

Harvesting of plated growing HeLa cells, followed by incubation of these cells without any addition at 37 degrees C was found to cause changes in the cell shape. This phenomenon is accompanied by a diminished binding of the beta-adrenergic antagonist [3H]-dihydroalprenolol and the alpha-adrenergic antagonist phentolamine to a binding compartment not representing beta-adrenergic receptors. These binding sites have a high affinity for hydrophobic agents and most probably represent lipophilic structures in the cellular membrane. Changes in the cell shape obviously cause alterations in the physical properties of the plasma membrane. This might lead to misinterpretations of the results from experiments in which the redistribution of beta-adrenergic receptors is followed during incubation with agonists, as receptor occupation with subsequent receptor redistribution is possibly accompanied by effects on the membrane microviscosity. It is concluded that investigations performed in order to follow physiological events like receptor redistribution and desensitization processes, may be obfuscated by changes in the normal physical state of the living cells.     

Determination of the desensitization of beta-adrenergic receptors by [3H]CGP-12177.

Isoprenaline treatment of C6-glioma cells induced a fast decrease in the number of beta-adrenergic receptors as determined by binding of [3H]CGP-12177, which paralleled the decrease in the hormonally stimulated adenylate cyclase activity. The total number of receptors, as determined by binding of (-)-[3H]dihydroalprenolol, did not decrease. Separation of the beta-adrenergic receptors on a sucrose density gradient showed that the decrease in the number of receptors detectable with CGP-12177 was due to a movement of the receptors from the plasma membrane to a vesicular cell compartment. By using both (-)-[3H]dihydroalprenolol and [3H]CGP-12177 it is thus possible to differentiate between the total number of receptors and those present at the plasma membrane in an unfractionated cell lysate.     

The orientation of the magnetic axes of the membrane-bound iron-sulfur clusters of spinach chloroplasts

Spinach chloroplast membranes were oriented onto mylar sheets by partial dehydration, and the orientation of the magnetic axes of membrane-bound paramagnetic clusters determined by electron paramagnetic resonance (EPR) spectroscopy. Our results indicate that the reduced Rieske iron-sulfur cluster signal is of orthorhombic symmetry oriented with th gy = 1.90 axis orthogonal to the membrane plane and with the gz = 2.03 axis in the membrane plane; the gx-axis is undetectable, presumably due to its broadness. If the Rieske center is a two-iron iron-sulfur cluster, we conclude that the iron-iron axis lies in the plane of the membrane. Illumination reduces the two bound chloroplast iron-sulfur proteins known as Clusters A and B. Center A is oriented such that gx = 1.86 and gy = 1.94 lie at an angle of about 40, and gz = 2.05 is at approximately 25, to the membrane plane. There are two possible orientations of Cluster B depending on the set of g-values assigned to this cluster. For one set of g-values, gz = 2.04 and gx = 1.89 are oriented in the plane of the membrane while gy = 1.92 is orthogonal to the plane. Alternatively, gz = 2.07 and gy = 1.94 are oriented approximately 50 and 40 to the membrane plane respectively, and gx = 1.80 is in the plane of the membrane. An additional light-induced signal at g = 2.15 oriented orthogonal to the plane is currently unexplained, as are other membrane perpendicular signals seen at g = 2.3 and g = 1.73 in dark-adapted samples.     

Exfoliation of the beta-adrenergic receptor and the regulatory components of adenylate cyclase by cultured rat glioma C6 cells

Cultured rat glioma C6 cells exfoliate membrane vesicles which have been termed 'exosomes' into the culture medium. The exosomes contained both stimulatory and inhibitory GTP-binding components of adenylate cyclase (the stimulatory, Gs, and the inhibitory, Gi, regulatory components) and beta-adrenergic receptors but were devoid of adenylate cyclase activity. It was therefore apparent that the catalytic component of adenylate cyclase was either not exfoliated or was inactivated during the exfoliation process. The presence of Gs or Gi in the exosomes was detected by ADP ribosylation using [alpha-32P]NAD in the presence of cholera or pertussis toxins, respectively. The exosomal concentration of each of the two components was estimated to be about one fifth of that of the cell membrane when expressed on a per mg protein basis. Exosomal Gs was almost as active as the membrane-derived Gs in its ability to reconstitute NaF- and guanine nucleotide-stimulated adenylate cyclase activity in membranes of S49 cyc- cells, which lack a functional Gs. The ability of exosomal Gs to reconstitute isoproterenol-stimulated activity, however, was much lower than that of membrane Gs. The density of beta-adrenergic receptors in the exosomes was much less than that found in the membranes. Although the exosomal receptors bound the antagonist iodocyanopindolol with the same affinity as receptors from the cell membrane, the affinity for the agonist isoproterenol was 13- to 18-fold lower in the exosomes. In addition, this affinity was not modulated by GTP in the exosomes. Thus, exfoliated beta-adrenergic receptors seem to be impaired in their ability to couple to and activate Gs. This was directly tested by coupling the receptors to a foreign adenylate cyclase using membrane fusion. The fusates were then assayed for agonist-stimulated activity. While significant stimulation of the acceptor adenylate cyclase was obtained using C6 membrane receptors, the exosomal receptors were completely inactive. Thus during exfoliation, there appear to be changes in the components of the beta-adrenergic-sensitive adenylate cyclase that results in a nonfunctional system in the exosomes.     

Blood as a near-"ideal" emulsion: a retrospective on the concept of the red cell as a fluid drop, its implications for the structure of the red cell membrane

Although the question whether the red cell is fluid or solid has been discussed since 17th century, it was the author's measurement of the relative viscosity of blood in 1960's that supplied the first direct evidence that the red cell interior is fluid. Furthermore, through his application of the equations of Taylor and, later, Oldroyd, to this problem, it became evident that, for the red cell to exhibit fluid-drop-like behavior, the membrane must also be fluid. This led to his concept of the red cell membrane as a complex two-phase structure (lipoprotein micelles and two-dimensional protein networks) which was similar to the one accepted nearly a decade later. The requirements of the theory of ideal emulsions that the shear stress be transmitted into the cell interior via low viscosity membrane, are met in the later work of other investigators using the concept of a tank-treading membrane having viscoelastic properties. This paper reviews the original work of the author which led to the development of an equation for the relative viscosity of blood as a function of volume concentration, C: nr = (1 - TkC)-2.5, valid at shear rates above 180 sec-1, in which T is the Taylor factor which gives a measure of fluidity of the red cell, and k is a plasma trapping factor. Both T and k increase with increasing rigidity of the red cell. Finally, the effect of the membrane viewed as a complex two-phase fluid, on the rheology of the red cell is discussed.