Physico-chemical mechanisms of transport by micropinocytosis

Blood plasma proteins adsorption on a capillar endoteliocyte membrane surface can be accompanied by the formation of protein clusters. Their superficial protein density is about 10(16) protein globules per m2. The surface density of free energy of such protein layer in a cluster is estimated according to total energy of individual protein globules hydrophobic contribution, and its value is approximately 5 mJ X m-2. It is identical to local variation quantity of the membrane free energy. An alternation of the free surface energy must lead to the appearance of chemically induced and bending moments and to the membrane distortion accompanied by the caveole forming. The blood hydrostatic pressure in capillar lumen (approximately 33 X 10(2)N X m-2) creates the membrane isotropic tension which is proportional to its value and to caveole radius. The latter according to Laplas' equation closes the caveole into the vesicula with the radius approximately 40 nm. The transport of free vesicula by cytoplasmic currents to the basal surface of an endoteliocyte results in exocytosis (which proceeds approximately 0.1 s) with a release of the vesicula surface free energy (approximately 10(-16) J). The capillar endotelium vesicular transport is the indivisible endocytosis-exocytosis process characterized by "the turnover" of the cell plasmic membrane matter without its loss.     

Equilibrium characteristics of calcium binding on the inner surface of membrane vesicles

A method is proposed for determining equilibrium parameters of calcium binding on the inner surface of membrane vesicules. Based on the studies of concentration relationship of calcium content in vesicules of myometrium sarcolemma (at the equilibrium state) there were determined the values of maximal capacity of Ca2+-binding (12.79 nmole/mg of protein) and the dissociation constants of Ca2+-binding centre complex (62.3 mkM) on the inner surface of the vesicules, and the value of intravesicular volume as well (25.7 mkl/mg of protein).     

The enter of viruses family Picornaviridae in residents macrophages

Viruses enter in cells through clathrin- and dinamin-mediated uptake route-endocytosis, caveolae-mediated local destruction of cell plasma membranes, and macropinocytosis. The non-enveloped viruses to which Picornaviridae famiy is attributed are important human and animal pathogens. The aim of this study was to examine the mechanisms of penetration of viruses of this family (polio-, echo 11-, entero 71- and coxsackie B1-viruses) into resident macrophages. After attachment to the plasma membrane of macrophages the enterovirus 71 and coxsackievirus B1 penetrated into macrophages by invagination of the plasma membrane and formation of intracytoplasmic vesicules - caveoles. The poliovirus entered macrophages both by caveols formation and local destruction of plasma membranes of the host cells. Macropinocytos of polioviruses was observed after 45 min contact. The echovirus 11 entered in host macrophages by local destruction of their plasma membranes during first 15 min. Then the formation of endocytosed vesicles with included viruses was observed. The echovirus 11 went out of endocytosed vesicles by local destruction of membrane vesicles.     

Ca2+/H+-exchange mechanisms in myometrial plasmalemma cells

Transport of 45Ca2+ into vesicules of hog myometrium plasmolemma under dissipation conditions of opposite-directed transmembrane gradient of protons (delta pH) was investigated. When studying some time regularities of the process, H+ dissipation was determined to have little effect on the initial velocity Vo (18 and 25 nmol Ca2+/1 mg of protein per 1 min at delta pH = 0 and delta pH = 1.5, respectively) and the time of semiaccumulation of cation (1.1 and 2.1 min). Estimation of Ca2+ accumulation concentrational dependence in the vesicules in Vo (30 s) revealed that Ca2+ input into vesicules was limited by binding the cation with carboxyl residues of Ca2+ channel external part. This effect is a consequence of the absence of Ca(2+)-transport systems in the vesicules on the background of quick filling of the intervesicular space by the cation as well as discrimination of Ca2+ sorption process by the vesicules inner surface under operating in the Vo regime. The value K0.5 = 0.5 microM for Ca2+ obtained conforms to physiological meaning of the imagined Kd, Ca2+ binding with four glutamate residues of Ca2+ channel external part. Dissipation of the artificial delta pH = 1.5 on the vesicular membrane leads to increasing the affinity for Ca2+ (to 0.1 microM at constant value of Vmax (40 nmol Ca2+/1 mg of protein per 1 min). We have also demonstrated irreversibility of the process tested and substrate specificity. The results obtained permit to suppose that delta pH dissipation provides for some conformational changes of the channel structure resulting in increasing Ca2+ affinity for the transporting system as well as increases the membrane permeability for the cation. The latter means the interrelation of two most important signal molecules such as Ca2+ and H+ in the cell is capable to occur on the level on Ca2+ separate channels.     

Developmental mechanisms in heterospory. II. Evidence for pinocytosis in the microspores of Selaginella

At a stage in ontogeny while they are still held together in tetrads, but before the formation of the exine, the microspores of Selaginella brooksii Hieron. show features of the cell surface which suggest that material is being taken up by pinocytosis. These features, which are confined to the proximal face of the spore, are: (1) cytoplasmic fringes which arise near, arch over and enclose membrane-bound particles on the cell surface, (2) invaginations of the plasma membrane which form smooth-surfaced vesicles, and (3) invaginations of the plasma membrane to form coated vesicles. The membranes which limit all three kinds of vesicle are asymmetrical. Sections that cut the surface of the microspore tangentially at or in the vicinity of this surface activity show a hexagonal lattice which is a surface specialization possibly connected with pinocytosis. There are indications that the pinocytosed material is digested by lysosomal enzymes; myelin-like residual bodies are formed which migrate to the periphery of the cell. These observations are discussed in relation to the nutritional explanation of heterospory in the pteridophytes.     

Subcellular imaging of dynamic protein interactions by bioluminescence resonance energy transfer

Despite the fact that numerous studies suggest the existence of receptor multiprotein complexes, visualization and monitoring of the dynamics of such protein assemblies remain a challenge. In this study, we established appropriate conditions to consider spatiotemporally resolved images of such protein assemblies using bioluminescence resonance energy transfer (BRET) in mammalian living cells. Using covalently linked Renilla luciferase and yellow fluorescent proteins, we depicted the time course of dynamic changes in the interaction between the V2-vasopressin receptor and β-arrestin induced by a receptor agonist. The protein-protein interactions were resolved at the level of subcellular compartments (nucleus, plasma membrane, or endocytic vesicules) and in real time within tens-of-seconds to tens-of-minutes time frame. These studies provide a proof of principle as well as experimental parameters and controls required for high-resolution dynamic studies using BRET imaging in single cells.     

Comparative study of the ultrastructure of vibrioid green sulfur bacteria]

The fine structure of the cells was investigated on the ultrathin sections of green sulphur bacteria, two strains of Chlorobium vibrioforme, two strains of Pelodictyon luteolum, and one strain of Pelodictyon phaeum. All strains possess similar photosynthetic structures --"chlorobium-vesicules" underlying the cytoplasmic membrane. Irregularly localized, gaseous vesicules of the rhombic shape were discerned in the cytoplasm of P. luteolum and P. phaeum. The vesicules were surrounded by a unilayer membrane. The cytoplasmic membrane produced invaginations of the mesosomal type. Elementary sulphur as a product of oxidation of hydrogen sulphide, is presumed to be liberated from the cells by means of sacs, or invaginations, formed by the cytoplasmic membrane. The taxonomy of the vibrioid green sulphur bacteria is discussed.     

Reversible pinocytosis of horseradish peroxidase in lymphoid cells

A detailed study of fluid phase endocytosis of horseradish peroxidase (HRP) in rat lymph node cells (LNC) is presented in this paper. Preliminary experiments have shown that HRP was internalized by non-receptor-mediated endocytosis and interacted minimally or not at all with plasma membrane of LNC, and can then be considered as a true fluid phase marker for these cells. Kinetics of uptake of HRP was found not to be linear with incubation time at 37 degrees C and deviation from linearity can be attributed to constant exocytosis of HRP. The kinetics of exocytosis cannot be described by a single exponential process. Rather, a minimum of two exponentials is required to account for exocytosis. This suggests that at least two intracellular compartments are involved in this process. The first turns over very rapidly with a t 1/2 release of about 3 min and is saturated after 10 min of exposure with HRP. The second, which turns over very slowly, is characterized by a t 1/2 release of about 500 min and accounts for the intracellular accumulation of HRP. Similar biphasic kinetics of exocytosis were observed with unfractionated LNC, with T lymphocyte-enriched LNC and with lymphocytes purified according to their density. This suggests that most, if not all, LNC are able to release HRP and that each cell type is endowed with the two intracellular compartments. Kinetics of uptake of HRP in these two compartments indicated that they are probably filled by two endocytic pathways, at least partially independent. Taken together, these results seem to indicate that a rapid membrane recycling occurs in lymphocytes. Furthermore, the weak base ammonium chloride and the carboxylic ionophore monensin were shown in our study to inhibit fluid phase endocytosis of HRP. The inhibition was time-dependent and required a preincubation of the cells with the drugs to be observed. Our results suggest that a perturbation of the vesicular traffic or a sequestration of membranes involved in HRP uptake is induced by these drugs. Under these conditions the release of cell-associated HRP was also reduced and to the same extent as the inhibition of uptake. Distribution of HRP between the two compartments and the t 1/2 release of HRP from either compartment were not perturbed. Taken together these results seem to indicate that exocytosis is not specifically affected by these drugs. Inhibition of uptake in drug-treated cells could result from a general decrease of membrane recycling or to the formation of smaller pinocytic vesicles with a different surface to volume ratio.     

A possible physico-chemical mechanism of cell fusion in skeletal muscle myogenesis by means of intercellular pinocytosis

The fusion mechanism of cells in myogenesis of skeletal muscle is proposed on the basis of capacity of forming intercellular contacts with pentalamellar structure to invaginate up to the formation of free vesicles, i.e. the intercellular pinocytosis. This process leads to a "loss" of the membrane material with the following perforation and rupture of the membrane at the site of cell contact. The formation of invaginations is connected with the clusterization of proteins on the cytoplasmic surface of plasmalemma, accompanied by an alteration of Gibbs' surface energy with the appearance of chemically induced and bending moments. The transition from the invagination to the vesicle depending on osmotic gradient of pressure between the fusing cells was estimated quantitatively. This gradient is determined by the mechanism of polymerization of protein subunits during the assembly of contractile elements in one of fusing cells.     

Divalent cations and nifedipine action on Ca(2+) transport into myometrial plasmalemma vesicles

While using 45Ca2+ on the model of "outside-out configuration" vesicules of the myometrium cells sarcolemma an investigation of Cd2+, Zn2+, Co2+ and niphedipin on Ca2+ transport into the vesicules in the conditions of protons gradient transmembrane dissipation has been conducted. The above listed substances blocking effect corresponds to their physicochemical properties. Cadmium and zinc ions are considerably more effective in suppressing Ca2+ transport into the vesicules under the dissipation of delta pH on the membrane if compare with the case of delta pH = 0. In the case of niphedipin inhibiting action an opposite result is observed. The hypothesis has been made, that dissipation of delta pH on the sarcolemma is capable to strengthen the transmembrane Ca2+ transport by means of changing the channel structures conformation.     

Early glycation products of endothelial plasma membrane proteins in experimental diabetes

The participation of glucose and two intermediates of glucose metabolism: glucose-6-phosphate (G6P) and glyceraldehyde-3-phosphate (Gald3P) to the formation of early glycation products was comparatively evaluated in the endothelial plasma membrane of streptozotocin-induced diabetic rats. Antibodies risen to a carrier protein reductively glycated by each of the sugars mentioned above were used to probe by immunoblotting the proteins of the lung microvascular endothelium plasmalemma purified from normal and diabetic rats. The amount of glycated endothelial plasma membrane proteins was below the limit of detection in normoglycemic animals but increased dramatically in diabetic animals for glucose and G6P. In contrast, no signal was found in diabetic rats for Gald3P, indicating that either the contribution of this phosphotriose to the glycation of intracellular proteins is negligible in vivo, or the Schiff base generated by this sugar transforms very rapidly into products of advanced glycation. Globally, the endothelial plasma membrane proteins bound on average 300 times more glucose than G6P proving that, in spite of its low in vitro potency as glycating agent, glucose represents the main contributor to the intracellular formation of early glycation products. The most abundant glycated proteins of the lung endothelial plasma membrane were separated by two dimensional electrophoresis and identified by mass spectrometry.     

Regulation of tumor phenotypes by caveolin-1 and sphingolipid-controlled membrane signaling complexes

Aberrant (glyco)sphingolipid expression deeply affects several properties of tumor cells that are involved in tumor progression and metastasis formation: cell adhesion (to the extracellular matrix or to the endothelium of blood vessels), motility, recognition and invasion of host tissues. In particular, (glyco)sphingolipids might contribute to the modulation of integrin-dependent interactions of tumor cells (determining their adhesion, motility and invasiveness) with the extracellular matrix as well as with host cells present in the stromal compartment of the tumor. A model based on solid experimental evidence has been proposed: (glyco)sphingolipids at the cell surface interact with plasma membrane receptors (e.g., integrin receptors and growth factor receptors) and adapter molecules (including tetraspanins) forming signaling complexes that are able to influence the activity of signal transduction molecules oriented at the cytosolic surface of the plasma membrane (mainly the Src kinases pathway members). The function of these signaling complexes appears to be strictly dependent on their (glyco)sphingolipid composition, and likely on specific sphingolipid-protein interactions. From this point of view, particularly intriguing is the connection between (glyco)sphingolipids and caveolin-1, a membrane protein that plays multiple roles as a suppressor of tumor growth and metastasis in ovarian, breast and colon human carcinomas.     

Pinocytosis and locomotion of amoebae: XII. Dynamics and motive force generation during induced pinocytosis in A. proteus

Summary The mechanism of induced pinocytosis was investigated in Amoeba proteus by light and electron microscopy. The application of nine different inducing substances revealed that pinocytotic channel formation, elongation, vesiculation, shortening and disappearance are the result of the successive or simultaneous action of both traction and pressure forces, which are produced by the contractile activity of a plasma membrane-associated layer of filaments ranging from a few hundred nm to several in thickness. The initial phase of channel formation is caused by traction forces according to the membrane flow concept, whereas channel elongation and vesiculation mainly result from pressure forces in conjunction with the extrusion of small hyaline pseudopodia. Shortening and disappearance of the pinocytotic channels are brought about by local contractions of the cortical filament layer in the basal region of the hyaline pseudopodia. Experiments using latex beads as marker particles together with inducing substances show that a rapid membrane turnover during pinocytosis can be excluded, and that the plasma membrane slides as an entire structure over the underlying cytoplasm.The authors are most grateful to Mrs. J. Ruch for technical assistance     

Quantitative studies of pinocytosis. II. Kinetics of protein uptake and digestion by rat yolk sac cultured in vitro

Pinocytic uptake of 125I-labeled bovine serum albumin by 17.5-day rat visceral yolk sac cultured in vitro has been examined. Uptake was followed by intracellular digestion and, after an initial period, the content of radioactivity in the tissue itself remained constant during the incubation. Radiolabel was returned to the culture medium predominantly as (125I)iodotyrosine; exocytosis of undigested protein did not occur. The rate of uptake of labeled protein, which was constant within an experiment and reproducible between experiments, was much higher than that of a nondigestible macromolecule, 125I-labeled polyvinylpyrrolidone. The higher rate of uptake was a consequence of the protein entering the cells chiefly by adsorption to the plasma membrane being internalized; 125I-labeled albumin did not stimualte, nor did 125I-labeled polyvinylpyrrolidone inhibit pinocytosis. Different preparations of 125I-labeled albumin had characteristically different rates of uptake, probably reflecting differences in affinity for plasma membrane receptors. The physiological significance of the findings is discussed.     

Induction of pinocytosis in rat hepatocytes by partial hepatectomy

Rat hepatocytes, normally not highly pinocytic cells, becomes so after partial hepatectomy when about two-thirds of the liver is removed. Droplets, up to 20 mum in diameter, develop, initially by addition to smaller pinocytic structures and later by fusion with lysosomes. The droplets contain a material with an electron microscope periodicity characteristic of fibrin; they are periodic acid Schiff-positive as is plasma. It is therefore reasonable to consider plasma glycoproteins to be major components of the droplets. The droplets are at all times membrane delimited, an observation possible only after perfusion fixation. The droplets are positive for three lysosomal hydrolases identified cytochemically: acid phosphatase, N-acetyl-beta-glucosaminidase, and beta-glucuronidase. From light and electron microscopy it is evident that these activities are acquired by fusion with lysosomes, mostly autophagic vacuoles and residual bodies both of which become very numerous after partial hepatectomy. Pinocytic structures are seen relatively infrequently in the hepatocytes of normal rats but a great many are present after partial hepatectomy. They are most easily observed if horseradish peroxidase (HRP) is intravenously injected before sacrifice and sections are incubated for HRP cytochemistry. The low dose of HRP employed (10 mg/100 g body weight) does not induce pinocytosis in controls, either untreated rats or rats subjected to laparotomy, including palpation of the liver. However, in partially hepatectomized rats even a much smaller dose of intravenous HRP (3.3 mg/100 g) visualizes the pinocytic structures in hepatocytes (coated vesicles, channels, cuplike bodies, and droplets). Kupffer cells pinocytose much HRP in both control and partially hepatectomized rats.     

Identification of lysosomal sialidase NEU1 and plasma membrane sialidase NEU3 in human erythrocytes

The sialylation level of molecules, sialoglycoproteins and gangliosides, protruding from plasma membranes regulates multiple facets of erythrocyte function, from interaction with endothelium to cell lifespan. Our results demonstrate that: (a) Both sialidases NEU1 and NEU3 are present on erythrocyte plasma membrane; (b) NEU1 is kept on the plasma membrane in absence of the protective protein/cathepsin A (PPCA); (c) NEU1 and NEU3 are retained on the plasma membrane, as peripheral proteins, associated to the external leaflet and released by alkaline treatments; (d) NEU1 and NEU3 are segregated in Triton X‐100 detergent‐resistant membrane domains (DRMs); (e) NEU3 shows activity also at neutral pH; and (f) NEU1 and NEU3 are progressively lost during erythrocyte life. Interestingly, sialidase activity released from erythrocyte membranes after an alkaline treatment preserves its functionality and recognizes sialoglycoproteins and gangliosides. On the other hand, the weak anchorage of sialidases to the plasma membrane and their loss during erythrocyte life could be a tool to preserve the cellular sialic acid content in order to avoid the early ageing of erythrocyte and processes of cell aggregation in the capillaries. J. Cell. Biochem. 114: 204–211, 2012. © 2012 Wiley Periodicals, Inc.     

Pulmonary edema: ischemia reperfusion endothelial injury and its reversal by c-AMP.

A review of the factors that oppose pulmonary edema formation (alveolar flooding) when capillary pressure is elevated are presented for a normal capillary endothelial barrier and for damaged endothelium associated with ischemia/reperfusion in rabbit, rat, and dog lungs. Normally, tissue pressure, the plasma protein osmotic pressure gradient acting across the capillary wall and lymph flow (Edema Safety Factors) increase to prevent the build-up of fluid in the lung's interstitium when capillary pressure increases. No measureable alveolar edema fluid accumulates until capillary pressure exceeds 30 mmHg. When the capillary wall has been damaged, interstitial edema develops at lower capillary pressures because the plasma protein osmotic pressure will not change greatly to oppose capillary filtration, but lymph flow increases to very high levels to remove the increased filtrate and the result is that capillary pressures can increase to 20-25 mmHg before alveolar flooding results. In addition, the mechanisms responsible for producing pulmonary endothelial damage with ischemia/reperfusion are reviewed and the effects of O2 radical scavengers, neutrophil depletion or altering their adherence to the endothelium, and increasing cAMP on reversing the damage to the pulmonary endothelium is presented.     

Localization of inositol 1,4,5-trisphosphate receptor-like protein in plasmalemmal caveolae

Activation of various receptors by extracellular ligands induces an influx of Ca2+ through the plasma membrane, but its molecular mechanism remains elusive and seems variable in different cell types. In the present study, we utilized mAbs generated against the cerebellar type I inositol 1,4,5-trisphosphate (InsP3) receptor and performed immunocytochemical and immunochemical experiments to examine its localization in several non-neuronal cells. By immunogold electron microscopy of ultrathin frozen sections as well as permeabilized tissue specimens, we found that a mAb to the type I InsP3 receptor (mAb 4C11) labels the plasma membrane of the endothelium, smooth muscle cell and keratinocyte in vivo. Interestingly, the labeling with the antibody was confined to caveolae, smooth vesicular inpocketings of the plasma membrane. The reactive protein, with an M(r) of 240,000 by SDS-PAGE, could be biotinylated with a membrane-impermeable reagent, sulfo-NHS-biotin, in intact cultured endothelial cells, and recovered by streptavidin-agarose beads, which result further confirmed its presence on the cell surface. The present findings indicate that a protein structurally homologous to the type I InsP3 receptor is localized in the caveolar structure of the plasma membrane and might be involved in the Ca2+ influx.     

A quantitative study of pinocytosis and intracellular proteolysis in rat peritoneal macrophages.

A method for the culture of rat peritoneal macrophages in vitro is described, in which pinocytic uptake of colloidal [198 Au]gold, 125I--labelled poly(vinylpyrrolidone) and [14C]sucrose proceeds at contant and fairly reproducible rates for several hours. The rat of uptake of colloidal [198 Au]gold, which wxhibited some inter-batch variation, was approx. 100 times that of the other two substrates. Colloidal gold did not affect the rate of uptake of 125I-labelled poly(vinylpyrrolidone) and therefore its own high rate of uptake could not be attributed to a stimulation of the formation of pinocytic vesicles. It conclude that uptake of collodial gold is highly dependent on adsorption on binding sites on the plasma membrane. Uptake of formaldehyde-treated 125I-labelled bovine serum albumin was followed by the release of [125I]iodo-L-tyrosine into the culture medium and took place at a rate intermediate between those of collodial [198Au]gold and the other two non-digestible substrates, 125I-labelled poly(vinylpyrrolidone) and [14C]sucrose.