Grafting of different glycosides on the surface of liposomes and its effect on the tissue distribution of 125I-labelled γ-globulin encapsulated in liposomes

Different glycosides were grafted on the surface of liposomes containing ¹²⁵I-labelled γ-globulin by two ways: (1) by using glycolipid and (2) by covalent coupling of $\text{p-}\text{aminophenyl-}\text{d}\text{-glycosides}$ to phosphatidylethanolamine liposomes using glutaraldehyde. The distribution of ¹²⁵I-labelled γ-globulin was determined in mouse tissues from 5–60 min after a single injection of these liposomes. The liver uptake of encapsulated ¹²⁵I-labelled γ-globulin was highest from liposomes having galactose and mannose on the surface. Competition experiments and cross-inhibition studies indicate that this uptake are mediated by specific recognition of the surface galactose and mannose residues of liposomes by the receptors present on the plasma membrane of liver cells. Stearylamine-containing liposomes were found to be more efficient in mediating the uptake of ¹²⁵I-labelled γ-globulin by the lung, whereas in the case of spleen, phosphatidylethanolamine liposomes were more efficient. The extent of uptake of ¹²⁵I-labelled γ-globulin from all types of liposome decreases as the amount of given liposomes increases. The uptake of ¹²⁵I-labelled γ-globulin from liposomes containing asialogangliosides depends upon the phospholipid/ glycolipid ratio. These experiments clearly demonstrate that enhanced liposome uptake by liver cells could be achieved by grafting galactose and mannose on the liposomal surface.     

Effect of liposomes containing cholesterol on adenylate cyclase activity of cultured mammalian fibroblasts

Liposomes prepared with cholesterol and dipalmitoyl phosphatidylcholine were incubated with a clone of normal rat kidney fibroblast of cells in culture. The cells took up [¹⁴C]cholesterol in proportion to the concentration of liposomes in the incubation medium, and the uptake increased with time over the four hours of study. Two cell membrane enzymes, adenylate cyclase and ($\text{Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}\text{)-ATPase}$, exhibited decreased activity after treatment with cholesterol-containing liposomes. The decrease in adenylate cyclase activity was directly proportional to the uptake of [¹⁴C]cholesterol. When a variety of subclones of NRK 5W were examined some were found to respond to cholesterol treatment and some did not. These data are consistent with the view that membrane cholesterol content plays a role in controlling the activity of some plasma membrane enzymes.     

Permeability changes of erythrocytes and liposomes by 5-(n-alk(en)yl) resorcinols from rye

$\text{5-(n-}\text{Alk(en)yl}\text{)}$ resorcinols can induce potassium release from liposomes and erythrocytes. The results suggest that $\text{5-(n-}\text{pentyl)resorcinol}$ can induce a specific permeability to protons as well as to potassium and other small molecules. The highest permeability changes were found in the presence of $\text{5-(n-}\text{pentadecyl)resorcinol}$ and alkenyl resorcinols. Orcin and resorcin were without effect. The size of permeant as investigated by turbidity measurements indicated that Ca²⁺ and Mg²⁺ cannot pass through the alkyl resorcinol-modified membrane but can pass through the alkenyl resorcinol-modified membrane. It was observed that alkenyl resorcinol at a concentration of 15 μM induced not only potassium release but also lysis of erythrocytes.     

Differences in lipid fluidity among isolated plasma membranes of normal and leukemic lymphocytes and membranes exfoliated from their cell surface

The fluorescence polarization technique with 1,6-diphenyl 1,3,5-hexatriene as a probe was used to determine the lipid microviscosity, $\text{η}$, of isolated plasma membranes of mouse thymus-derived ascitic leukemia (GRSL) cells and of extracellular membraneous vesicles exfoliated from these cells and occurring in the ascites fluid. For comparison, $\text{η}$ was also determined in isolated plasma cell supernatants.For isolated plasma membranes of thymocytes and GRSL cells $\text{η}$ values at 25° C amounted to 4.67 and 3.28 P, respectively, which were higher than the microviscosities of the corresponding intact cells, 3.24 and 1.73 P, respectively.Microviscosities inextracellular membranes of thymocytes and GRSL cells were 5.96 and 5.83 P, respectively. The fluidity difference between these membranes and plasma membranes was most pronounced for the leukemic cells and was thereby correlated with a large difference in cholesterol/phospholipid molar ratio (1.19 for extracellular membranes and 0.37 for plasma membranes). It is proposed that extracellular membraneous vesicles are shed from the surface of GRSL cells similar to the budding process of viruses, that is by selection of the most rigid parts of the host cell membrane.Liposomes of total lipid extracts of plasma membranes and extracellular membranes of both cell types exhibited about the same microviscosity as the corresponding intact membranes, indicating virtually no contribution of (glyco)-protein to the lipid fluidity as measured by the fluorescence polarization technique. For both cell types $\text{η}$ (25° C) values of liposomes consisting of membrane phospholipids varied between 1.5 and 1.9 P, much lower than the values for total lipids, indicating a significant rigidizing effect of cholesterol in each type of membrane.     

Comparison of cholesterol-phospholipid interaction in bilayers of liposomes and the red cell membrane

The energetics of interactions of cholesterol with phospholipid in simple liposome bilayers were compared with those in the bilayer of the human erythrocyte membrane, by measuring cholesterol distribution between erythrocytes and liposomes prepared from their whole phospholipid extract. With liposomes of a range of initial cholesterol contents, the equilibrium value for $\text{r}$, the ratio of cholesterol/phospholipid in the liposomes to that in the cells, is in the range 1.1–1.2. The closeness of this value to 1.0 indicates that overall cholesterol-phospholipid interaction in the cell membrane is similar to that in liposomes. However, while the deviation from 1.0 is small, and could arise from average cholesterol-phospholipid interactions in the membrane being only 0.06 to 0.1 kcal · mol^?1 weaker than in liposomes, it could also result from 10 to 20% of the cell membrane phospholipid being unavailable to mix with cholesterol.     

Lipid bilayers and liposomes in reconstitution experiments with cholinergic proteolipid from torpedo electroplax

The cholinergic proteolipid from $\text{Torpedo}$ electroplax was used in reconstitution experiments in artificial membranes being incorporated directly into the membrane-forming solution or into liposomes (proteoliposomes) which interacted with lecithin bilayers. In both cases the membrane became reactive to acetylcholine by a decrease in resistance and an increase in the frequency and amplitude of minute current fluctuations of 3·10^?11 to 4·10^?10mho. The injection of d-tubocurarine prod$\text{u}$ ced an increase in membrane resistance and a decrease in the amplitude of the current fluctuations. These results suggest that the cholinergic proteolipid is reconstituted in an active form in the bilayer.     

Difference in microviscosity induced by different cholesterol levels in the surface membrane lipid layer of normal lymphocytes and malignant lymphoma cells

Microviscosity ($\text{}\text{?}$gh) in the surface membrane lipid layer of normal lymphocytes and malignant lymphoma cells, and in liposomes prepared from their lipid extracts, was determined with the aid of the fluorescence polarization properties of 1,6-diphenyl 1,3,5-hextriene embedded in it. The $\text{}\text{?}$gh values, both in intact cells and in the liposomes, are distinctively greater for normal lymphocytes than for the lymphoma cells, whereas the fusion activation energy in both types of cells and liposomes is 8 ± 0.5 kcal/mol. Determination of cholesterol revealed that its relative amount in a lymphoma cell is about half of that of a normal lymphocyte, a difference that may account for the above difference in fluidity. This thesis is supported by the observed changes in $\text{}\text{?}$gh, which follow artificial changes in cholesterol contents in the surface membrane of both cell types. Introduction of exogeneous cholesterol into the cell surface membranes was performed with lecithin-cholesterol (1:1) liposomes, and in lymphoma cells resulted in an increase of $\text{}\text{?}$gh to a level of normal lymphocytes. Extraction of native cholesterol from the cell surface membranes was carried out with lecithin liposomes, and in normal lymphocytes results in a decrease of $\text{}\text{?}$gh to a value similar to that of lymphoma cells. The induced changes in cholesterol contents are practically reversible for both cell types. By virtue of controlling the microviscosity of lipid layers, the level of cholesterol in cell surface membranes may play an important role in determining biological activities of normal and malignant cells.     

Role of the plasma membrane in the mechanism of cholesterol efflux from cells

In order to investigate the role of the plasma membrane in determining the kinetics of removal of cholesterol from cells, the efflux of [³H]cholesterol from intact cells and plasma membrane vesicles has been compared. The release of cholesterol from cultures of Fu₅AH rat hepatoma and WIRL-3C rat liver cells to complexes of egg phosphatidylcholine (1 mg / ml) and human high-density apolipoprotein is first order with respect to concentration of cholesterol in the cells, with half-times ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$) for at least one-third of the cell cholesterol of 3.2 ± 0.6 and 14.3 ± 1.5 h, respectively. Plasma membrane vesicles (0.5–5.0 μm diameter) were produced from both cell lines by incubating the cells with 50 mM formaldehyde and 2 mM dithiothreitol for 90 min. The efflux of cholesterol from the isolated vesicles follows the same kinetics as the intact, parent cells: the $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ values for plasma membrane vesicles of Fu₅AH and WIRL cells are 3.9 ± 0.5 and 11.2 ± 0.7 h, respectively. These $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ values reflect the rate-limiting step in the cholesterol efflux process, which is the desorption of cholesterol molecules from the plasma membrane into the extracellular aqueous phase. The fact that intact cells and isolated plasma membranes release cholesterol at the same rate indicates that variations in the plasma membrane structure account for differences in the kinetics of cholesterol release from different cell types. In order to investigate the role of plasma membrane lipids, the kinetics of cholesterol desorption from small unilamellar vesicles prepared from the total lipid isolated from plasma membrane vesicles of Fu₅AH and WIRL cells were measured. Half-times of cholesterol release from plasma membrane lipid vesicles of Fu₅AH and WIRL cells were the same, with values of 3.1 ± 0.1 and 2.9 ± 0.2 h, respectively. Since bilayers formed from isolated plasma membrane lipids do not reproduce the kinetics of cholesterol efflux observed with the intact plasma membranes, it is likely that the local domain structure, as influenced by membrane proteins, is responsible for the differences in $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ values for cholesterol efflux from these cell lines.     

Canine traceealis membrane fractionation and characterization

Canine trachealis was homogenized and the various membrane fractions isolated by differential centrifugation and discontinuous sucrose gradient centrifugation. A membrane fraction enriched in the plasma membrane marker enzymes 5′-nucleotidase (5-fold) and K⁺-activated ouabain sensitive p-nitrophenylphosphatase (3-fold) was obtained. The fraction contained very low levels of the inner mitochondrial marker succinate: cytochrome c oxidoreductase. These plasma membrane vesicles showed higher ATP-dependent Ca-uptake (20 μmoles/g protein) than any other submicrosomal fraction. The active Ca-uptake was enhanced by oxalate. The Ca taken up by the plasma membrane vesicles was released instantaneously by dilution in 5m$\text{M}$ EGTA and 10μ$\text{M}$ A23187 and more slowly by dilution only in 5m$\text{M}$ EGTA.     

Isolation of plasma membrane vesicles,derived from transverse tubules,by selective homogenization of subcellular fractions of frog skeletal muscle in isotonic media

A new technique for isolating fragmented plasma membranes from skeletal muscle has been developed that is based on gentle mechanical disruption of selected homogenate fractions. $\text{(Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}\text{)-stimulated}$, Mg²⁺-dependent ATPase was used as an enzymatic marker for the plasma membrane, Ca²⁺-stimulated, Mg²⁺-dependent ATPase as a marker for sarcoplasmic reticulum, and succinate dehydrogenase for mitochondria. Cell Cell segments in an amber low-speed ($\text{800 × g}$) pellet of a frog muscle homogenate were disrupted by repeated gentle shearing with a Polytron homogenizer. Sarcoplasmic reticulum was released into the low-speed supernatant, whereas most of the plasma membrane marker remained in a white, fluffy layer of the sediment, which contained sarcolemma and myofibrils. Additional gentle shearing of the white low-speed sediment extracted plasma membranes in a form that required centrifugation at $\text{100 000 × g}$ for pelleting. This pellet, the fragmented plasma membrane fraction, had a relatively high specific activity of $\text{(Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}\text{)-stimulated}$ ATPase compared with the other fractions, but it had essentially no Ca²⁺-stimulated ATPase activity and only a small percentage of the succinate dehydrogenase activity of the homogenate.Experimental evidence suggests that the fragmented plasma membrane fraction is derived from delicate transverse tubules rather than from the thicker, basement membrane-coated sarcolemmal sheath of muscle cells. Electron microscopy showed small vesicles lined by a single thin membrane. Hydroxyproline, a characteristic constituent of collagen and basement membrane, could not be detected in this fraction.     

Effects of inhibitors on the plasma membrane and mitochondrial adenosine triphosphatases of Neurospora crassa

A comparative study has been made of the effects of a variety of inhibitors on the plasma membrane ATPase and mitochondrial ATPase of Neurospora crassa. The most specific inhibitors proved to be vanadate and diethylstilbestrol for the plasma membrane ATPase and azide, oligomycin, venturicidin, and leucinostatin for mitochondrial ATPase. $\text{N,N′-}\text{Dicyclohexylcarbodiimide}$, octylguanidine, triphenylsulfonium chloride, and quercetin and related bioflavonoids inhibited both enzymes, although with different concentration dependences. Other compounds that were tested (phaseolin, fusicoccin, deoxycorticosterone, alachlor, salicyclic acid, $\text{N-1-}\text{napthylphthalamate}$, triiodobenzoic acid, cyclic AMP, cyclic GMP, theobromine, theophylline, and histamine) had no significant effect on either enzyme. Overall, the results indicate that the plasma membrane and mitochondrial ATPases are distinct enzymes, in spite of the fact that they may play related roles in H⁺ transport across their respective membranes.     

Mechanism of action of cesalin, an antitumor protein.

A protein, cesalin, isolated from $\text{Caesalpinia}$$\text{gilliesii}$ is cytotoxic to KB cells in tissue culture. It has been shown to bind to the plasma membrane of this cell line and to inhibit Na⁺, K⁺-ATPase (ATP phosphohydrolase EC 3.6.1.3). Similar studies with HTC cells show no cytotoxicity or inhibition of plasma membrane Na⁺, K⁺-ATPase. The Na⁺, K⁺-ATPase of human erythrocytes and rat brain and kidney tissues are not inhibited. 5′-Nucleotidase and Mg⁺⁺-ATPase are not inhibited by cesalin in any cells tested.     

The surface membrane of the small intestinal epithelial cell. I. Localization of adenyl cyclase

The subcellular distribution of adenyl cyclase was investigated in small intestinal epithelial cells. Enterocytes were isolated, disrupted and the resulting membranes fractionated by differential and sucrose gradient centrifugation. Separation of luminal (brush border) and contra-luminal (basolateral) plasma membrane was achieved on a discontinuous sucrose gradient.The activity of adenyl cyclase was followed during fractionation in relation to other enzymes, notably those considered as markers for luminal and contraluminal plasma membrane. The luminal membrane was identified by the membrane-bound enzymes sucrase and alkaline phosphatase and the basolateral region by ($\text{Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}$)-ATPase. Enrichment of the former two enzymes in purified luminal plasma membrane was 8-fold over cells and that of ($\text{Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}$)-ATPase in purified basolateral plasma membranes was 13-fold. F^?-activated adenyl cyclase co-purified with ($\text{Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}$)-ATPase, suggesting a common localization on the plasma membrane. The distribution of K⁺-stimulated phosphatase and 5′-nucleotidase also followed ($\text{Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}$)-ATPase during fractionation.     

Lactosylceramide-induced stimulation of liposome uptake by Kupffer cells in vivo

Incorporation of 8 mol percent lactosylceramide into small unilamellar vesicles consisting of cholesterol and sphingomyelin in an equimolar ratio and containing [³H]inulin as a marker resulted in an increase in total liver uptake and a drastic change in intrahepatic distribution of the liposomes after intravenous injection into rats. The control vesicles without glycolipid accumulated predominantly in the hepatocytes, but incorporation of the glycolipid resulted in a larger stimulation of Kupffer-cell uptake (3.2-fold) than of hepatocyte uptake (1.2-fold). Liposome preparations both with and without lactosylceramide in which part of the sphingomyelin was replaced by phosphatidylserine, resulting in a net negative charge of the vesicles, were cleared much more rapidly from the blood and taken up by the liver to higher extents. The negative charge had, however, no influence on the intrahepatic distributions. The fast hepatic uptake of the negatively charged liposomes allowed competition experiments with substrates for the galactose receptors on liver cells. Inhibition of blood clearance and liver uptake of lactosylceramide-containing liposomes by $\text{N-}\text{acetyl-}\text{d}\text{-galactosamine}$ indicated the involvement of specific recognition sites for the liposomal galactose residues. This inhibitory effect of $\text{N-}\text{acetyl-}\text{d}\text{-galactosamine}$ was shown to be mainly the result of a decreased liposome uptake by the Kupffer cells, compatible with the reported presence of a galactose specific receptor on this cell type (Kolb-Bachofen et al. (1982) Cell 29, 859–866). The difference between the results on sphingomyelin-based liposomes as described in this paper and those on phosphatidylcholine-based liposomes as published previously (Spanjer and Scherphof (1983) Biochim. Biophys. Acta 734, 40–47) are discussed.     

The occurrence of phosphatidyl choline exchange protein in leaves

The transfer of phosphatidyl choline between liposomes was stimulated by the protein fractions from spinach leaves, etiolated and greening leaves of $\text{Avena}$ seedlings. This is confirmed by the transfer of [¹⁴C]phosphatidyl choline or spin-labeled phosphatidyl choline between donor and acceptor liposomes. ESR spectrum changes also indicated that no spin-labeled phosphatidyl choline was released from donor liposomes by spinach leaf protein unless acceptor liposomes were present. [¹⁴C]phospholipids were transferred from liposomes to both spinach chloroplasts and $\text{Avena}$ etiochloroplasts by phosphatidyl choline exchange protein from germinated castor bean endosperms and further from liposomes to spinach chloroplasts by spinach leaf protein. These results support the view that phosphatidyl choline in the plastid is supplied from the synthesis site, the endoplasmic reticulum, by phospholipid exchange protein.     

Interaction of cholesterol,phospholipid and apoprotein in high density lipoprotein recombinants

To examine the effect of incorporation of cholesterol into high density lipoprotein (HDL) recombinants, multilamellar liposomes of ³H cholesterol/¹⁴C dimyristoyl phosphatidylcholine were incubated with the total apoprotein (apoHDL) and principal apoproteins (apoA-1 and apoA-2) of human plasma high density lipoprotein. Soluble recombinants were separated from unreacted liposomes by centrifugation and examined by differential scanning calorimetry and negative stain electron microscopy. At 27°C, liposomes containing up to approx. 0.1 mol cholesterol/mol dimyristoyl phosphatidylcholine (DMPC) were readily solubilized by apoHDL, apoA-1 or apoA-2. However, the incorporation of DMPC and apoprotein into lipoprotein complexes was markedly reduced when liposomes containing a higher proportion of cholesterol were used. For recombinants prepared from apoHDL, apoA-1 or apoA-2, the equilibrium cholesterol content of complexes was approx. 45% that of the unreacted liposomes. Electron microscopy showed that for all cholesterol concentrations, HDL recombinants were predominantly lipid bilayer discs, approx. $\text{160 × 55}\text{A}\text{?}$. Differential scanning calorimetry of cholesterol containing recombinants of DMPC/cholesterol/apoHDL or DMPC/cholesterol/apoA-1 showed, with increasing cholesterol content, a linear decrease in the enthalpy of the DMPC gel to liquid crystalline transition, extrapolating to zero enthalpy at 0.15 cholesterol/DMPC. The enthalpy values were markedly reduced compared to control liposomes, where the phospholipid transition extrapolated to zero enthalpy at approx. 0.45 cholesterol/DMPC. The calorimetric and solubility studies suggest that in high density lipoprotein recombinants cholesterol is excluded from 55% of DMPC molecules bound in a non-melting state by apoprotein.     

DDT inhibition of Ca-Mg ATPase from peripheral nerves and muscles of lobster, Homarus americanus

Sensitivity of CaMg ATPase from axonic plasma membrane (APM) and sarcoplasmic reticulum (SR) of lobster, $\text{Homarus}\text{,}\text{americanus}$, to DDT was studied. The CaMg ATPase found in SR with the high Ca²⁺ affinity is sensitive to DDT while the portion of ATPase related to the low Ca²⁺ affinity site is not inhibited by DDT. Also, DDT is more inhibitory against the CaMg ATPase prepared from APM than the one obtained from SR. The relationship between inhibition of the CaMg ATPase by DDT in the axonic nerve membrane and $\text{in}\text{,}\text{vivo}$ poisoning symptoms of the nervous system is discussed.     

A new assay system of phospholipid exchange activities using concanavalin a in the separation of donor and acceptor liposomes

A new assay system of phospholipid exchange activities is described. The exchange activities were quantitated by measuring the stimulation of phospholipid transfer between two separate populations of liposomes, which contained, as the major constituents, phosphatidylcholine, phosphatidylethanolamine, phosphatidylinositol, sphingomyelin, and cholesterol in molar ratios of 6: 2: 1: 1: 5. One population of the liposomes was made reactive to concanavalin A by the incorporation of 1.8 mol% $\text{α-}\text{d}\text{-mannosyl}\text{-(1 → 3)-α-}\text{d}\text{- mannosyl}\text{-sn-}\text{1,2-diglyceride}$ from Micrococcus lysodeikticus. The concanavalin A-reactive liposomes, a phospholipid donor, were doubly labelled with [6-³H]galactosylglucosyl ceramide and that class of ³²P-labelled phospholipids whose exchange was being measured. The ³H-labelled glycolipid served as a non-exchangeable reference marker. The other population of the liposomes, a phospholipid acceptor, was concanavalin A nonreactive. These two populations of liposomes were incubated with the cytosol protein of rat liver in a total volume of 0.2 ml.After the incubation, two different procedures were used to separate the two liposomal populations. In one procedure concanavalin A was added to agglutinate the reactive liposomes; the flocculated lectin-liposome complex was separated from the non-reactive liposomes by brief centrifugation. In the other procedure the reactive liposomes were trapped by binding to concanavalin A covalently coupled to Sepharose 2B; the complex was separated from the nonreactive liposomes by filtration through a filter paper under suction. In both assay procedures the amount of phospholipid transferred from the donor to the acceptor liposomes was calculated from the decrease of ³²P/³H ratio of the concanavalin A-reactive liposomes during the incubation. By the assay system it is possible to determine phosphatidylcholine and phosphatidylinositol exchange activities in 100 μg of rat liver cytosol protein.     

Identification and partial characterization of plasma membrane polypeptides of Trypanosoma brucei

A plasma membrane-enriched vesicle fraction has been prepared from Trypanosoma brucei by sonication and differential centrifugation on sucrose gradients. This fraction is enriched 5-fold in the plasma membrane marker enzymes adenyl cyclase (EC 4.6.1.1) and ouabain-inhibitable, ($\text{Na}{}^{\mathrm{+}}\text{+}\text{K}{}^{\mathrm{+}}$)-dependent adenosine triphosphatase (EC 3.6.1.3). It is also enriched up to 14-fold in iodinated surface proteins, and up to 4-fold in [³H]mannose-labeled glycoproteins, of which the major variable surface coat glycoprotein is the main constituent. Proteins of the plasma membrane fraction and other subcellular fractions have been identified by electrophoretic analysis in sodium dodecyl sulfate-polyacrylamide gradient slab gels. Several high molecular weight surface glycopeptides have been selectively investigated and partially characterized by a combination of metabolic labeling with [³H]mannose, lactoperoxidase-catalyzed surface iodination, and affinity chromatography on Con A-Sepharose. In addition to the major variable surface coat glycoprotein (estimated $\text{M}{}_{\mathrm{<mtext>r</mtext>}}\text{= 58 000}$), there are several minor surface glycopeptides ($\text{M}{}_{\mathrm{<mtext>r</mtext>}}\text{= 76 000, 86 000}\text{and}\text{92 000–100 000}$) which are apparent extrinsic membrane components, and two surface glycopeptides ($\text{M}{}_{\mathrm{<mtext>r</mtext>}}\text{= 42 000}\text{and}\text{130 000}$) which are intrinsic membrane components.