Study of electrophoretic mobility of cellular membranes isolated from rat liver.

Plasma membranes as well as mitochondrial and microsomal subfractions were subjected to zone electrophoresis. Treatment with neuraminidase, phospholipase A or C does not influence the movement of plasma membranes and smooth microsomes. Trypsin increases mobility of plasma membranes and smooth by about 20%, and further treatment with phospholipase C decreases mobility of plasma membranes, total smooth and smooth I microsomes, which, however, is not the case with smooth II microsomes. Low concentrations of trypsin also solubilize enzyme proteins of smooth microsomes from phenobarbital-treated rat liver, but electrophoretic mobility is not increased, indicating structural differences in induced membranes. The mobility of the outer and inner mitochondrial membranes is significantly higher than that of submitochondrial particles. For microsomes the negative surface charge density occurs in the decreasing order of: ribosomes--rough--smooth I--smooth II. A 10 mM CsCl gradient decreases the mobility of rough microsomes by 40% and of ribosomes by 20% but has no effect on total smooth micromes. On the other hand, 5mM MgCl2 decreased the mobility of all three fractions. EDTA-treated rough and EDTA-treated smooth microsomes have the same electrophoretic mobilities. However, the mobilities of non-treated rough and smooth microsomes differ significantly from each other.     

Characterization of the ribosomal binding site in rat liver rough microsomes: Ribophorins I and II,two integral membrane proteins related to ribosome binding

Rat liver rough endoplasmic reticulum membranes (ER) contain two characteristic transmembrane glycoproteins which have been designated ribophorins I and II and are absent from smooth ER membranes. These proteins (MW 65,000 and 63,000 respectively) are related to the binding sites for ribosomes, as suggested by the following findings: (i) The ribophorin content of the rough ER membranes corresponds stoichiometrically to the number of bound ribosomes; (ii) ribophorins are quantitatively recovered with the bound polysomes after most other ER membrane proteins are dissolved with the nonionic detegent Kyro EOB; (iii) in intact rough microsomes ribophorins can be crosslinked chemically to the ribosomes and therefore are in close proximity to them. Treatment of rough microsomes with a low Triton X-100 concentration leads to the lateral displacement of ribosomes on the microsomal surface and to the formation of aggregates of bound ribosomes in areas of membranes which frequently invaginate into the microsomal lumen. Subfractionation of Triton-treated microsomes containing invaginations led to the recovery of smooth and “rough-inverted” vesicles. Ribophorins were present only in the latter fraction, indicating that both proteins are displaced together with the ribosome-binding capacity of rough and smooth microsomal membranes reconstituted after solubilization with detergents sugest that ribophorins are necessary for in vitro ribosome binding. Ribophorin-like proteins were found in rough microsomes obtained from secretory tissues of several animal species. The two proteins present in rat lacrimal gland microsomes have the same mobility as hepatocyte ribophorins and cross-react with antisera against them.     

Characterization of microsomal subfractions from porcine endometrium cells

Crude microsomes from porcine endometrium and three subfractions obtained by a modification of Rothschild's technique were characterized by RNA/protein ratio, marker enzyme activities and morphological appearance. The microsomes were devoid of glucose-6-phosphatase activity. They contained approximately 10% of arylesterase-, approximately 30% of both NADPH-cytochrome reductase- and UDPgalactose-N-acetyl-glucosamine beta-D-galactosyltransferase- and approximately 60% of 5'-nucleotidase activities present in the homogenates. Subfraction I (smooth membranes) had twice the galactosyltransferase activity of Subfraction II (smooth and rough membranes + free ribosomes); both subfractions were rich in 5'-nucleotidase and cytochrome reductase activities. Subfraction III (rough membranes) had very low marker activities but exhibited the highest RNA/protein ratio, which was lowest in I.     

Spin label studies of microsomal membranes from Acanthamoeba castellanii in different states of differentiation

Two fatty acid spin labels—[I(1,14)], stearic acid bearing a paramagnetic nitroxide group on carbon 16, and [I(12,3)], stearic acid bearing a paramagnetic nitroxide group on carbon 5—have been used to compare the physical properties of lipid in rough and smooth microsomal membranes from trophozoites and cysts of Acanthamoeba castellanii. Arrhenius plots of rotational correlation times (τ_c) calculated from the spectra for I(1,14) showed an abrupt discontinuity in slope for membranes from both trophozoites and cysts. This occurred at temperatures ranging from ?3 to 1 °C for smooth microsomes and from 8 to 11 °C for rough microsomes for both cysts and amoebae. The value of τ_c at 29 °C, the culturing temperature, in effect scores fluidity of the membrane matrix, and did not show any significant difference for either rough or smooth microsomes during the transition from exponential to stationary phase growth. However, smooth microsomes from cysts showed a 14% increase in fluidity relative to trophozoites, and the fluidity of rough microsomes from cysts tended to be lower. An order parameter (S) calculated from spectra for I(12,3) did not change as a function of encystment for the smooth membranes and increased only slightly for rough microsomes. The activation energy (E_a) for Arrhenius plots of τ_c above the inflection temperature increased as a result of encystment, indicating a greater degree of molecular interaction within the cyst membranes. Moreover, the τ_c plots for both rough and smooth microsomal membranes from trophozoites tended to converge at 29 °C, the growth temperature, whereas plots for cyst membranes were virtually parallel, bracketing those for the trophozoite membranes. This suggests that the trophozoite is able to regulate its membrane fluidity and that cysts, which are resting cells, have lost this regulatory capacity.     

RIBOSOME-MEMBRANE INTERACTION : Nondestructive Disassembly of Rat Liver Rough Microsomes into Ribosomal and Membranous Components

In a medium of high ionic strength, rat liver rough microsomes can be nondestructively disassembled into ribosomes and stripped membranes if nascent polypeptides are discharged from the bound ribosomes by reaction with puromycin. At 750 mM KCl, 5 mM MgCl₂, 50 mM Tris·HCl, pH 7 5, up to 85% of all bound ribosomes are released from the membranes after incubation at room temperature with 1 mM puromycin. The ribosomes are released as subunits which are active in peptide synthesis if programmed with polyuridylic acid. The ribosome-denuded, or stripped, rough microsomes (RM) can be recovered as intact, essentially unaltered membranous vesicles Judging from the incorporation of [³H]puromycin into hot acid-insoluble material and from the release of [³H]leucine-labeled nascent polypeptide chains from bound ribosomes, puromycin coupling occurs almost as well at low (25–100 mM) as at high (500–1000 mM) KCl concentrations. Since puromycin-dependent ribosome release only occurs at high ionic strength, it appears that ribosomes are bound to membranes via two types of interactions: a direct one between the membrane and the large ribosomal subunit (labile at high KCl concentration) and an indirect one in which the nascent chain anchors the ribosome to the membrane (puromycin labile). The nascent chains of ribosomes specifically released by puromycin remain tightly associated with the stripped membranes. Some membrane-bound ribosomes (up to 40%) can be nondestructively released in high ionic strength media without puromycin; these appear to consist of a mixture of inactive ribosomes and ribosomes containing relatively short nascent chains. A fraction (~15%) of the bound ribosomes can only be released from membranes by exposure of RM to ionic conditions which cause extensive unfolding of ribosomal subunits, the nature and significance of these ribosomes is not clear.     

Subcellular structure of bovine thyroid gland. A study on bovine thyroid membranes by buoyant-density-gradient centrifugation in a B-XIV zonal rotor.

A combined mitochondrial and light mitochondrial fraction and a microsomal fraction were isolated from bovine thyroid gland and fractionated further in a B-XIV zonal rotor. A density gradient ranging from 20 to 50% (w/w) sucrose was used. The rotor was operated for 3 h at 45 000 rev./min. All manipulations were performed at 4 degrees C and at pH 7.4. 2. Membranous material was recovered in two zones: zone I, containing microsomal material derived from both smooth endoplasmic reticulum and plasma membranes and probably also from other smooth membranes; zone II, containing material from rough endoplasmic reticulum. 3. Increasing the pH of the medium up to 8.6, or the addition of Mg2+ to the medium resulted in the formation of a single zone at intermediate densities (aggregation of membranes?). An analogous effect was obtained after treatment with Pb (NO3) 2. 4. In the presence of heparin (50 i.u./ml) the bulk of the membranes was found in zone I. This was due to the release of ribosomes from the rough endoplasmic reticulum.     

Lipid composition and turnover of rough and smooth microsomal membranes in rat liver

Subfractions of rat liver microsomes (rough, smooth I, and smooth II), isolated in a cation-containing sucrose gradient system, were analyzed. After removal of adsorbed and luminal protein, these subfractions had the same phospholipid/protein ratio, about 0.40. Both the classes and the relative amounts of phospholipids were similar in the three subfractions, but the relative amounts of neutral lipids (predominantly free cholesterol and triglycerides) were higher in smooth I and especially in smooth II than in rough microsomes. Various pieces of evidence indicate that the neutral lipids are tightly bound to the membranes. Glycerol-(3)H was incorporated into the phospholipids of the rough and smooth I microsomes significantly faster than into those of the smooth II membranes; (32)P incorporation followed a similar but less pronounced pattern. Acetate-(3)H was incorporated into the free cholesterol of smooth I microsomes only half as fast as into the other two subfractions. Injection of phenobarbital increased the cellular phospholipid and neutral lipid content in the rough and smooth I, but not in the smooth II microsomes. Consequently, the neutral lipid/phospholipid ratio of all three subfractions remained unchanged after phenobarbital treatment. It is concluded that the membranes of the rough and the two smooth microsomal subfractions from rat liver have a similar phospholipid composition, but are dissimilar in their neutral lipid content and in the incorporation rate of precursors into membrane lipids.     

Electrokinetic properties of synaptic vesicles and synaptosomal membranes.

Using the technique of electrophoretic light scattering, we have measured the electrophoretic mobilities of synaptic vesicles and synaptosomal plasma membranes isolated from guinea-pig cerebral cortex. The electrophoretic mobility of synaptic vesicles is slightly greater than that of synaptosomal plasma membranes. Ca+2 and Mg+2 reduced the mobility of both species to the same extent at physiologically relevant concentrations (0-1 mM) and near-physiologic ionic strength. The extent of the reduction was not large (approximately 6% for synaptic vesicles in the presence of 100 mM KCl) at 1 mM divalent cation concentrations. At concentrations of approximately 2 mM and higher, Ca+2 reduced the mobility of synaptic vesicles more than did Mg/2. A similar but much smaller effect was observed in the case of synaptosomal plasma membranes. The addition of 1 mM Mg+2-ATP had no effect upon synaptic vesicle mobility either in the presence or absence of the ionophores nigericin or valinomycin. These data, together with earlier work (Siegel et al., 1978, Biophys. J. 22:341-346), demonstrate that substantial reduction of the average electrostatic surface charge density is not the most important role of divalent cations in promoting close approach of secretory granules and secretory cell membranes, and that it is certainly not the Ca+2-specific step in exocytosis.     

High affinity specific antiestrogen binding sites are concentrated in rough microsomal membranes of rat liver

Saturation and competitive binding analyses demonstrated the presence of a high affinity (K_D = 0.92 nM), specific antiestrogen binding site (AEBS) in rat liver microsomes and at least 75% of total liver AEBS was recovered in this fraction. When microsomes were further separated into smooth and rough fractions, AEBS was concentrated in the latter. Subsequent dissociation of ribosomes from the rough membranes revealed that AEBS was associated with the membrane and not the ribosomal fraction. Antiestrogen binding activity could not be extracted from membranes with 1 M KCl or 0.5 M acetic acid but could be solubilized with sodium cholate. These data indicate that AEBS is an integral membrane component of the rough microsomal fraction of rat liver.     

Association of sialic acid with microsomal membrane structures in rat liver

The amount of sialic acid on phospholipid basis increases from rough, through smooth II and smooth I microsomes, to Golgi membranes, all of them free from most of the adsorbed and luminal protein. The incorporation rate of glucosamine-³H into sialic acid also follows a similar order. Deoxycholate removes phospholipid and sialic acid to an identical extent, and a significant part of the latter remains after trypsin and neuraminidase treatment. The sialic acid/phospholipid ratio decreases in phenobarbital-induced smooth but not in rough membranes, while the incorporation rate of glycosamine-³H into sialic acid decreases in both subfractions.     

Biosynthesis of cytochrome P-450 on membrane-bound ribosomes and its subsequent incorporation into rough and smooth microsomes in rat hepatocytes

Intracellular sites of synthesis of cytochrome P-450 and the subsequent incorporation of it into membrane structures of the endoplasmic reticulum (ER) in rat hepatocytes have been studied using an antibody monospecific for phenobarbital-inducible cytochrome P-450. The cytochrome is synthesized mainly on the "tightly bound" type of membrane-bound ribosomes whose release from the membrane requires treatment with puromycin in a high salt buffer (500 mM KCI, 5mM MgCl2, and 50 mM Tris-HCL [pH 7.5]). Subsequently the cytochrome is incorporated directly into the rough ER membranes with its major part exposed to the outer surface to the membrane and accessible to proteolytic enzymes added externally. The newly synthesized molecules, which appeared first in the rough membrane, are translocated to the smooth membrane, and are then distributed evenly between the two types of microsomeal membranes in approximately 1 h. Administration of cycloheximide, an inhibitor of protein biosynthesis, did not significantly inhibit the transfer of the enzyme from the rough to the smooth ER. It is suggested, therefore, that the translocation of the newly synthesized cythochrome P-450 between the rough and smooth microsomes is mainly due to the lateral movement of the molecules in the plane of the membranes rather than to the attachment and detachment of the ribosomes on the microsomal membranes after the ribosomal cycle for protein synthesis.     

Mobility of ribosomes bound to microsomal membranes. A freeze-etch and thin-section electron microscope study of the structure and fluidity of the rough endoplasmic reticulum

The lateral mobility of ribosomes bound to rough endoplasmic reticulum (RER) membranes was demonstrated under experimental conditions. High- salt-washed rough microsomes were treated with pancreatic ribonuclease (RNase) to cleave the mRNA of bound polyribosomes and allow the movement of individual bound ribosomesmfreeze-etch and thin-section electron microscopy demonstrated that, when rough microsomes were treated with RNase at 4 degrees C and then maintained at this temperature until fixation, the bound ribosomes retained their homogeneous distribution on the microsomal surface. However, when RNase- treated rough microsomes were brought to 24 degrees C, a temperature above the thermotropic phase transition of the microsomal phospholipids, bound ribosomes were no longer distributed homogeneously but, instead, formed large, tightly packed aggregates on the microsomal surface. Bound polyribosomes could also be aggregated by treating rough microsomes with antibodies raised against large ribosomal subunit proteins. In these experiments, extensive cross-linking of ribosomes from adjacent microsomes also occurred, and large ribosome-free membrane areas were produced. Sedimentation analysis in sucrose density gradients demonstrated that the RNase treatment did not release bound ribosomes from the membranes; however, the aggregated ribosomes remain capable of peptide bond synthesis and were released by puromycin. It is proposed that the formation of ribosomal aggregates on the microsomal surface results from the lateral displacement of ribosomes along with their attached binding sites, nascent polypeptide chains, and other associated membrane proteins; The inhibition of ribosome mobility after maintaining rough microsomes at 4 degrees C after RNase, or antibody, treatment suggests that the ribosome binding sites are integral membrane proteins and that their mobility is controlled by the fluidity of the RER membrane. Examination of the hydrophobic interior of microsomal membranes by the freeze-fracture technique revealed the presence of homogeneously distributed 105-A intramembrane particles in control rough microsomes. However, aggregation of ribosomes by RNase, or their removal by treatment with puromycin, led to a redistribution of the particles into large aggregates on the cytoplasmic fracture face, leaving large particle-free regions.     

Recovery of ribophorins and ribosomes in "inverted rough" vesicles derived from rat liver rough microsomes

Treatment of rat liver rough microsomes (3.5 mg of protein/ml) with sublytical concentrations (0.08%) of the neutral detergent Triton X-100 caused a lateral displacement of bound ribosomes and the formation of ribosomal aggregates on the microsomal surface. At slightly higher detergent concentrations (0.12-0.16%) membrane areas bearing ribosomal aggregates invaginated into the microsomal lumen and separated from the rest of the membrane. Two distinct classes of vesicles could be isolated by density gradient centrifugation from microsomes treated with 0.16% Triton X-100: one with ribosomes bound to the inner membrane surfaces ("inverted rough" vesicles) and another with no ribosomes attached to the membranes. Analysis of the fractions showed that approximately 30% of the phospholipids and 20-30% of the total membrane protein were released from the membranes by this treatment. Labeling with avidin-ferritin conjugates demonstrated that concanavalin A binding sites, which in native rough microsomes are found in the luminal face of the membranes, were present on the outer surface of the inverted rough vesicles. Freeze-fracture electron microscopy showed that both fracture faces had similar concentrations of intramembrane particles. SDS PAGE analysis of the two vesicle subfractions demonstrated that, of all the integral microsomal membrane proteins, only ribophorins I and II were found exclusively in the inverted rough vesicles bearing ribosomes. These observations are consistent with the proposal that ribophorins are associated with the ribosomal binding sites characteristic of rough microsomal membranes.     

Ribosomal-membrane interaction: in vitro binding of ribosomes to microsomal membranes

Rat liver rough microsomal membranes were stripped of bound ribosomes by treatment with puromycin and high concentrations of monovalent ions. Ribosomal subunits labeled in the RNA were detached from rough microsomes by the same procedure, recombined into monomers, and then incubated with stripped membranes in a medium of low ionic strength (25 mm-KCl, 50 mm-Tris-HCl, 5 mm-MgCl₂). These ribosomes readily attached to the stripped membranes, as determined by isopycnic flotation of the reconstituted microsomes. The binding reaction was complete after incubation for five minutes at 37 °C, but also proceeded at 0 °C, at a lower rate. Scatchard plots showed a binding constant of ~8 × 10⁷m^?1 and ~5 × 10^?8 mol binding sites per gram of membrane protein. Native rough microsomes showed a much lower binding capacity at 0 °C than stripped rough microsomes, but showed considerable uptake of ribosomes at 37 °C. Smooth microsomes, treated for stripping and incubated at 0 °C, accepted less than half as many ribosomes as stripped rough microsomes. Erythrocyte ghosts were incapable of binding ribosomes. Microsomal binding sites were heat sensitive, were destroyed by a brief incubation with a mixture of trypsin and chymotrypsin in the cold, and were unaffected by incubation with phospholipase C.Ribosome binding was decreased by increasing the concentration of monovalent ions and was strongly inhibited by 10^?4m-aurintricarboxylic acid. Experiments with purified ribosomal subunits revealed that at concentrations of monovalent ions close to physiological concentrations (100 to 150 mm-KCl), microsomal binding sites had a greater affinity for 60 S than for 40 S subunits.Stripped rough microsomes were also capable of accepting polysomes obtained from rough microsomes by detergent treatment. Although this binding presumably involves the correct membrane binding sites, polypeptides discharged from re-bound polymers were not transferred to the vesicular cavities, as in native microsomes. The released polypeptides remained firmly associated with the outer microsomal face, as shown by their accessibility to proteases.     

Distribution of protein-bound sugar residues in microsomal subfractions and Golgi membranes

Liver microsomal subfractions and Golgi membranes free from adsorbed and secretory proteins have a characteristic sugar composition. The ratio of mannose to galactose is largest in rough microsomes, smaller in smooth I microsomes, still smaller in smooth II microsomes, and smallest in Golgi membranes. There is about twice as much glucosamine in Golgi membranes and 3 times as much in smooth II microsomes as in the other microsomal subfractions. Golgi membranes are rich in sialic acid in comparison to rough microsomes and it is present at even higher levels in the two smooth microsomal subfractions. Increasing concentrations of deoxycholate preferentially remove protein-bound mannose and glucosamine, while releasing significantly less galactose. About half of the microsomal mannose and galactose can be liberated from the surface of intact microsomal vesicles by treatment with trypsin. When trypsin is added to permeable vesicles where the inside surface can be also attacked, an additional 20% of the total mannose but no additional galactose is liberated.     

Distribution of protein-bound sugar residues in microsomal subfractions and Golgi membranes.

Liver microsomal subfractions and Golgi membranes free from adsorbed and secretory proteins have a characteristic sugar composition. The ratio of mannose to galactose is largest in rough microsomes, smaller in smooth I microsomes, still smaller in smooth II microsomes, and smallest in Golgi membranes. There is about twice as much glucosamine in Golgi membranes and 3 times as much in smooth II microsomes as in the other microsomal subfractions. Golgi membranes are rich in sialic acid in comparison to rough microsomes and it is present at even higher levels in the two smooth microsomal subfractions. Increasing concentrations of deoxycholate preferentially remove protein-bound mannose and glucosamine, while releasing significantly less galactose. About half of the microsomal mannose and galactose can be liberated from the surface of intact microsomal vesicles by treatment with trypsin. When trypsin is added to permeable vesicles where the inside surface can be also attacked, an additional 20% of the total mannose but no additional galactose is liberated.     

Membranes of Tetrahymena. IV. Isolation and characterization of temperature-responsive smooth and rough microsomal subfractions.

Temperature-responsive microsomes of the ciliate protozoan Tetrahymena have been originally fractionated by step centrifugation on two-layered, Mg2+-containing sucrose gradients. Three fractions have been obtained, which are termed smooth I, smooth II and rough according to the appearance of the membrane vesicles upon electron-microscopy. Smooth I, smooth II, and rough microsomes exhibit RNA/protein ratios of 0.09, 0.20, and 0.34; their phospholipid/protein ratios and their neutral lipid/phospholipid ratios were 0.52, 0.43 and 0.25, and 0.17, 0.18 and 0.13, respectively. All three fractions contain equivalent, low succinic dehydrogenase and 5'-nucleotidase activities. Glucose-6-phosphatase and acid phosphatase are more concentrated in smooth I membranes than in rough membranes. The reverse is true for ATPase. The smooth II membranes occupy an intermediate position except that their ATPase activity is the lowest of the three fractions. The specific activities of these enzymes of the three microsomal fractions are compared to those of homogenates of whole cells. Thin-layer chromatography reveals a very similar polar and nonpolar lipid pattern of the three microsomal fractions. The major phospholipid compounds are phosphatidlethanolamine, glycerideaminoethylphosphonate and phosphatidylcholine, while diglycerides, an unknown NL-compound, and triglycerides are the major apolar lipids. Gas liquid chromatography shows that the fatty acids are mainly even-numbered ranging between C12 and C18. The smooth I, smooth II and rough membranes contain 65.2, 69.3 and 72.7% unsaturated fatty acids in their polar lipids, whereas only 52.7, 49.7 and 48.3% unsaturated acids are found in their apolar lipids, respectively. The fatty acids are more unevenly distributed among the individual polar lipids than in the apolar ones.     

Enzymac characterization and lipid composition of rat liver subcellular membranes

1.

1. Mitochondria, inner and outer mitochondrial membranes, microsomes, smooth and rough endoplasmic reticulum membranes and plasma membranes were isolated from rat liver.     

Proteins of rough microsomal membranes related to ribosome binding. II. Cross-linking of bound ribosomes to specific membrane proteins exposed at the binding sites

Two proteins (ribophorins I and II), which are integral components of rough microsomal membranes and appear to be related to the bound ribosomes, were shown to be exposed on the surface of rat liver rough microsomes (RM) and to be in close proximity to the bound ribosomes. Both proteins were labeled when intact RM were incubated with a lactoperoxidase iodinating system, but only ribophorin I was digested during mild trypsinization of intact RM. Ribophorin II (63,000 daltons) was only proteolyzed when the luminal face of the microsomal vesicles was made accessible to trypsin by the addition of sublytical detergent concentrations. Only 30--40% of the bound ribosomes were released during trypsinization on intact RM, but ribosome release was almost complete in the presence of low detergent concentrations. Very low glutaraldehyde concentrations (0.005--0.02%) led to the preferential cross-linking of large ribosomal subunits of bound ribosomes to the microsomal membranes. This cross-linking prevented the release of subunits caused by puromycin in media of high ionic strength, but not the incorporation of [3H]puromycin into nascent polypeptide chains. SDS-acrylamide gel electrophoresis of cross-linked samples a preferential reduction in the intensity of the bands representing the ribophorins and the formation of aggregates which did not penetrate into the gels. At low methyl-4-mercaptobutyrimidate (MMB) concentrations (0.26 mg/ml) only 30% of the ribosomes were cross-linked to the microsomal membranes, as shown by the puromycin-KCl test, but membranes could still be solubilized with 1% DOC. This allowed the isolation of the ribophorins together with the sedimentable ribosomes, as was shown by electrophoresis of the sediments after disruption of the cross-links by reduction. Experiments with RM which contained only inactive ribosomes showed that the presence of nascent chains was not necessary for the reversible cross-linking of ribosomes to the membranes. These observations suggest that ribophorins are in close proximity to the bound ribosomes, as may be expected from components of the ribosome-binding sites.     

Studies on membrane proteins involved in ribosome binding on the rough endoplasmic reticulum. Ribophorins have no ribosome-binding activity.

A membrane protein fraction showing affinity for ribosomes was isolated from rat liver microsomes (microsomal fractions) in association with ribosomes by treatment of the microsomes with Emulgen 913 and then solubilized from the ribosomes with sodium deoxycholate. This protein fraction was separated into two fractions, glycoproteins, including ribophorins I and II, and non-glycoproteins, virtually free from ribophorins I and II, on concanavalin A-Sepharose columns. The two fractions were each reconstituted into liposomes to determine their ribosome-binding activities. The specific binding activity of the non-glycoprotein fraction was approx. 2.3-fold higher than that of the glycoprotein fraction. The recovery of ribosome-binding capacity of the two fractions was about 85% of the total binding capacity of the material applied to a concanavalin A-Sepharose column, and about 90% of it was found in the non-glycoprotein fraction. The affinity constants of the ribosomes for the reconstituted liposomes were somewhat higher than those for stripped rough microsomes. The mode of ribosome binding to the reconstituted liposomes was very similar to that to the stripped rough microsomes, in its sensitivity to proteolytic enzymes and its strong inhibition by increasing KCl concentration. These results support the idea that ribosome binding to rat liver microsomes is not directly mediated by ribophorins I and II, but that another unidentified membrane protein(s) plays a role in ribosome binding.