Binding of rat liver and hepatoma polyribosomes to stripped rough endoplasmic reticulum in vitro. Biological or an artifact?

Exposed thiol groups do not appear to be related to the binding of (32)P-labelled polyribosomes to stripped rough endoplasmic reticulum in vitro. Treating stripped rough endoplasmic reticulum with GSSG did not diminish binding of polyribosomes, suggesting that binding in vitro has no correlation with the inhibition of protein synthesis in vitro reported by Kosower et al. (1971). Thiol reagents, which are known to dissociate ribosomes, did not significantly decrease binding of (32)P-labelled polyribosomes to stripped rough endoplasmic reticulum. Denaturing the protein of (32)P-labelled polyribosomes or stripped rough endoplasmic reticulum of liver or hepatoma with heat, trichloroacetic acid, or HClO(4) did not alter the binding in vitro. Therefore, the practice of measuring the binding of (32)P-labelled polyribosomes to stripped rough endoplasmic reticulum in vitro (Shires et al., 1971b) is an unsuitable indicator of biological significance in the intact cell.     

The synthesis of α-amylase by rough and in vitro reconstituted rough endoplasmic reticulum derived from rat parotid gland

Summary The isolation of rough and smooth endoplasmic reticulum from rat parotid salivary gland is described. The rough membrane was stripped of its bound ribosomes using the KCl-puromycin method. Rough endoplasmic reticulum was reconstituted from stripped-rough membrane and polyribosomes. The reconstituted rough membrane resembled the native rough membrane in the following aspects: RNA/protein ratio, buoyant density in a continuous sucrose gradient and amino acid incorporation capacity. The in vitro synthesis of -amylase by both rough and in vitro reconstituted rough membrane was demonstrated using SDS polyacrylamide gel electrophoresis. The reconstituted rough membrane could be restripped by KCl-puromycin. The in vitro synthesized -amylase remained associated with the rough or the in vitro reconstituted rough membrane, even after these membranes were stripped of their bound ribosomes.Abbreviations Fp Free polyribosomes - Bp Membrane-bound polyribosomes released by DOC - RM Rough membrane - SM Smooth membrane - RMst Rough membrane stripped - RMrec In vitro reconstituted rough membrane - DOC Sodium deoxycholate     

The association in vitro of polyribosomes with ribonuclease-treated derivatives of hepatic rough endoplasmic reticulum. Characteristics of the membrane binding sites and factors influencing association

1. Pancreatic ribonuclease in dilute EDTA has been shown to condition rough-microsomal membranes from adult rat liver to accept exogenously added rat liver polyribosomes in vitro at 0-4 degrees C. Treated smooth membranes would not significantly interact with polyribosomes. 2. The conditioning process decreased the membrane RNA content and removed polyribosomes from vesicle surfaces as viewed electron-microscopically. 3. Binding to these conditioned membranes was shown to be uninfluenced by changes of temperature (0-37 degrees C) and pH (6.9-7.8) or the presence of cell sap, but was inhibited by increasing the concentration of potassium chloride. 4. Possession of a polyribosome-binding capacity by conditioned rough membranes was not dependent on adventitious materials that could be dislodged by high ionic strengths. 5. Trypsin treatment under mild conditions destroyed the binding capacity of ribonuclease-conditioned rough membranes. 6. A 2-10S residual RNA was recovered from ribonuclease-conditioned membranes, but its partial removal had no effect on the capacity of membranes to accept polyribosomes. However, some role for this residual RNA in attaching polyribosomes could not be discounted. 7. Evidence is considered that polyribosome-binding sites are intrinsic features of conditioned membranes isolated from rough-microsomal fractions, and that long-range ionic bonding is a primary factor in polyribosome interaction with these binding sites.     

Effect of ethionine on the rough endoplasmic reticulum from male and female rat liver

Ethionine causes a decrease in the amount of rough endoplasmic reticulum in rat liver, the effect being greater in female than in male rats. Rough endoplasmic reticulum isolated from rat liver 24 hr after ethionine injection and stripped of its ribosomes partially lost itsin vitro ribosome binding capacity. However, no differences were detected between the binding affinities of ribosomes, isolated from either untreated animals or intoxicated rats, to stripped rough membranes derived from normal rats. Structural changes occur in the rough endoplasmic reticulum of the ethionine treated rats, while the ribosomes are still bound to the membrane.     

Isolation and characterization of membrane proteins responsible for attachment of polyribosomes to rough microsomal fraction of rat liver.

A protein fraction which has a high affinity for polyribosomes was isolated from rough microsomal membranes of rat liver. The mode of polyribosome binding to this fraction (R-fraction) was studied by using CsCl equilibrium centrifugation and compared with that for stripped rough microsomal membranes. The following were found. (1) The polyribosome-binding cpacity of the R-fraction was heat-labile and sensitive to trypsin, and was suppressed by increasing KCl concentration and addition of 0.1 mM-aurintricarboxylic acid. (2) Of the four subfractions obtained by gel filtration of the R-fraction on a Sephadex G-200, only the R1-fraction, eluted at the void volume, showed a high affinity for polyribosomes. The polyribosome-binding capacity of the R1-fraction decreased with time on storage at 4 degrees C. (3) The R1-fraction contained three major proteins with mol. wts. 108,000, 99,000 and 65,000.     

Interactions of liver encoplasmic reticulum membranes and polysomes in vitro.

The interactions of various preparations of endoplasmic reticulum membranes and polysomes have been studied by means of a sandwich sucrose gradient that clearly isolates free ribosomes, smooth endoplasmic reticulum (S.E.R.) and rough endoplasmic reticulum (R.E.R.) from the microsomal fraction of rat liver homogenates. Reconstructed rough membranes separate well from the native R.E.R. but occupy the same position along the gradient as the S.E.R. and the rough membranes, stripped of their ribosomes by means of LiCl. Native R.E.R. and S.E.R. do not bind any added labeled polysomes at 0 degree C; previous treatment with LiCl does not modify the behavior of S.E.R. The presence of cell sap during the binding reaction does not increase polysome fixation by stripped-rough membranes but protects in some way the polysomes and preserves all their original functional capacity of amino acid incorporation into protein.     

Interactions of liver endoplasmic reticulum membranes and polysomesin vitro

Summary The interactions of various preparations of endoplasmic reticulum membranes and polysomes have been studied by means of a sandwich sucrose gradient that clearly isolates free ribosomes, smooth endoplasmic reticulum (S.E.R.) and rough endoplasmic reticulum (R.E.R.) from the microsomal fraction of rat liver homogenates. Reconstructed rough membranes separate well from the native R.E.R. but occupy the same position along the gradients as the S.E.R. and the rough membranes, stripped of their ribosomes by means of LiCl. Native R.E.R. and S.E.R. do not bind any added labeled polysomes at 0°C; previous treatment with LiCl does not modify the behavior of S.E>R. The presence of cell sap during the binding reaction does not increase polysome fixation by stripped-rough membranes but protects in some way the polysomes and preserves all their original functional capacity of amino acid incorporation into protein.     

The in vitro reconstitution of a functional rough membrane active in protein synthesis

Rough endoplasmic reticulum was reconstituted from free polyribosomes and rough membrane stripped from its ribosomes by KCl and puromycin. The reconstituted rough membrane resembled the native rough membrane in the following aspects: RNA/protein ratio, buoyant density in a continuous sucrose gradient, amino acid incorporation capacity and sensitivity towards protein synthesis inhibitors. When the reconstitution was done with double labelled polyribosomes ([³²P] polyribosomes, [³H] leucine labelling of nascent peptide chain before or after the attachment of the polyribosomes to the membrane) both labels banded together with the reconstituted rough membrane band. Hybrid rough membrane could be formed from rat liver stripped rough membrane and wheat germ ribosomes. This hybrid membrane could translate globin mRNA.     

Effect of ribosome stripping procedures on antigenicity and conformation of endoplasmic reticulum membrane.

The effects of 3 different procedures for stripping ribosomes from membranes on theantigeniticity and conformation of isolated rough and smooth endoplasmic reticulum from rat liver were examined by microcomplement fixation and circular dichroism. Some of the blocked antigenic binding sites in rough endoplasmic reticulum became available after stripping of ribosomes. None of the 3 methods used is capable of stripping ribosomes completely from rough endoplasmic reticulum without the concomitant removal of protein from the membrane. Such loss of membrane protein by the stripping treatments is probably involved in the observed changes in rough endoplasmic reticulum, since a marked reduction in complement fixing capacity and in ellipticity of circular dichroism is observed also in smooth endoplasmic reticulum after similar treatments.     

Segregation of the polypeptide translocation apparatus to regions of the endoplasmic reticulum containing ribophorins and ribosomes. I. Functional tests on rat liver microsomal subfractions

A preparation of rat liver microsomes containing 70% of the total cellular endoplasmic reticulum (ER) membranes was subfractionated by isopycnic density centrifugation. Twelve subfractions of different ribosome content ranging in density from 1.06 to 1.29 were obtained and analyzed with respect to marker enzymes, RNA, and protein content, as well as the capacity of these membranes to bind 80S ribosomes in vitro. After removal of native polysomes from these microsomal subfractions by puromycin in a buffer of high ionic strength their capacity to rebind 80S ribosomes approached levels found in the corresponding native membranes before ribosome stripping. This indicates that in vitro rebinding of ribosomes occurs to the same sites occupied in the cell by membrane-bound polysomes. Microsomes in the microsomal subfractions were also tested for their capacity to effect the translocation of nascent secretory proteins into the microsomal lumen utilizing a rabbit reticulocyte translation system programmed with mRNA coding for the precursor of human placental lactogen. Membranes from microsomes with the higher isopycnic density and a high ribosome content showed the highest translocation activity, whereas membranes derived from smooth microsomes had only a very low translocation activity. These results indicate the membranes of the rough and smooth portions of the endoplasmic reticulum are functionally differentiated so that sites for ribosome binding and the translocation of nascent polypeptides are segregated to the rough domain of the organelle.     

Electrophoretic studies on liver endoplasmic reticulum membrane polypeptides and on their phosphorylation in vivo and in vitro

Sodium dodecyl sulfate-polyacrylamide gel electrophoresis was used to examine the polypeptide patterns of rat liver rough and smooth endoplasmic reticulum (ER) membrane fractions stripped of ribosomes. Approximately 67 polypeptides were resolved from the rough ER membrane fraction. The polypeptide pattern of the smooth ER membrane fraction was similar to that of the rough ER membrane fraction, but exhibited substantially lower amounts of some seven polypeptides. Three of these polypeptides, of apparent molecular weights 63,000, 65,000, and 87,000, were of particular interest, as they could not be ascribed to contamination of stripped rough ER membrane fractions by residual ribosomal polypeptides. Conditions of treatment with low concentrations of trypsin were established that markedly diminished the capacity of the stripped rough ER membrane fraction to bind ribosomes in vitro and that also effected a partial detachment of ribosomes from nonstripped rough ER membranes; the results of electrophoretic analyses of rough ER membrane fractions treated in these manners are described. Comparison of the polypeptide patterns of guinea pig, mouse, and rabbit liver ER membrane fractions with rat liver ER membrane fractions revealed considerable variations in the distribution of the polypeptides of 63,000, 65,000, and 87,000 molecular weight among the ER membrane fractions of these species. The combined results of these studies indicate that the polypeptide of 87,000 molecular weight, although particularly sensitive to attack by trypsin, is not involved in the binding of ribosomes to the rough ER membrane fraction. Studies by others (cf. Kreibich, G., Grebenau, R., Mok, W., Pereyra, B., Rodriguez-Boulan, E., and Sabatini, D. D. (1977) Fed. Proc. 36, 656) have implicated the polypeptides of 63,000 and 65,000 molecular weight in this process. The patterns of phosphorylated polypeptides of rough and smooth ER membrane fractions of rat and mouse liver were also examined, using labeling in vivo with sodium [32p]phosphate or in vitro with [gamma-32P]ATP. Approximately 25 phosphorylated components were resolved by electrophoresis in the ER membrane fractions of both species. Evidence is presented that suggests that the great majority of these components are phosphopolypeptides. Differences were noted in the patterns of phosphorylation produced by in vivo and in vitro labeling; minor differences were also observed between the patterns of phosphorylation of the rough and smooth ER membrane fractions in either situation. The overall results afford an indirect approach toward evaluating the possible involvement of specific rough ER membrane polypeptides in ribosome-binding and reveal that liver ER membranes contain a substantially greater number of phosphorylated polypeptides thatn previously reported.     

The selectivity and stoicheiometry of membrane binding sites for polyribosomes, ribosomes and ribosomal subunits in vitro.

Differences in the binding sites for polyribosomes, template-depleted ribosomes and large ribosomal subunits were found in microsomal derivatives of the rough endoplasmic reticulum. 1. The stoicheiometry of polyribosome and ribosome interaction in vitro with membranes was shown to be influenced by the relative concentration of interactants and the duration of their mixing. Large ribosomal subunits required a more prolonged mixing schedule to achieve saturation of membranes than did polyribosomes. 2. By using a procedure which minimized the effects on binidng by the stoicheiometric variables, competition between populations of polyribosomes, ribosomes and subunits for membrane sites showed that subunits, and to a lesser extent ribosomes, failed to block polyribosome attachment. 3. Polyribosomes isolated from liver, kidney and hepatoma 5123C entirely bound to a common membrane site, but some polyribosomes from myeloma MOPC-21 bound to other sites, perhaps influenced by their unique nascent proteins. 4. Subunit-binding sites appear on rough membranes only after endogenous polyribosomes have been removed, but no evidence that resulting changes in surface constituents are responsible was found. Large-subunit binding was largely abolished by lowering MgC12 concentration of 0.1 mM, whereas under the same conditions polyribosome binding was undiminished. 5. The large-subunit site appears to be distinct from the polyribosome site not only in the restriction of its affinity for particles but also spatially, to the extent that bound subunits do not hinder access of polyribosomes to their sites.     

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.     

The formation, distribution and function of ribosomes and microsomal membranes during induced amphibian metamorphosis

1. A lag period of about 4 days preceded the onset of metamorphosis precociously induced by tri-iodothyronine in tadpoles of the giant American bullfrog (Rana catesbeiana). It was established by the accelerated synthesis or induction of carbamoyl phosphate synthetase and cytochrome oxidase in the liver, serum albumin and adult haemoglobin in the blood, acid phosphatase in the tail, and the increase in the hindleg/tail length ratio. 2. A 4- to 6-fold stimulation, 2 days after the induction of metamorphosis, of the rate of synthesis of rapidly labelled nuclear RNA in liver cells was followed by an increasing amount of RNA appearing in the cytoplasm. Most of the newly formed RNA on induction of metamorphosis was of the ribosomal type. An accelerated turnover at early stages of development preceded a net accumulation of RNA in the cytoplasm, with no change in the amount of DNA per liver. 3. Most hepatic ribosomes of the pre-metamorphic tadpoles were present as 78s monomers and 100s dimers; metamorphosis caused a shift towards larger polysomal aggregates with newly formed ribosomes that were relatively more tightly bound to membranes of the endoplasmic reticulum. 4. The appearance of new polyribosomes in the cytoplasm on induction of metamorphosis was co-ordinated in time with a stimulation of synthesis of phospholipids of the smooth and rough endoplasmic reticulum, followed by a gradual shift in preponderance from the smooth to the rough type of microsomal membranes. 5. Electron- and optical-microscopic examination of intact hepatocytes revealed a striking change in the distribution and nature of ribosomes and microsomal membranes during metamorphosis. 6. Ribosomes prepared from non-metamorphosing and metamorphosing animals were identical in their sedimentation coefficients and in the structural ribosomal proteins. The base composition and sedimentation coefficients of ribosomal RNA were also identical. Induction of metamorphosis also did not alter the incorporation of (32)P into the different phospholipid constituents of microsomal membranes. 7. Nascent (14)C-labelled protein with the highest specific activity was recovered in the ;heavy' rough membrane fraction of microsomes, whereas little (14)C was associated with ;free' polysomes. Protein synthesis in vivo was most markedly stimulated during metamorphosis in the tightly membrane-bound ribosomal fraction after the appearance of new ribosomes. 8. The rate of synthesis of macromolecules in vivo could not be followed beyond 7-8 days after induction because of variable shifts in precursor pools due to regression of larval tissues. 9. The stimulation of RNA and ribosome formation was specifically associated with the process of metamorphosis since no similar response to thyroid hormones occurred in those species (Axolotl and Necturus) in which the hormones failed to induce metamorphosis.     

Peptidyl - tRNA hydrolase and RNase activities in cell fractions of rat liver used in in vitro reconstitution of rough membrane.

Peptidyl-tRNA hydrolase and RNase activities have been studied in those fractions of rat liver, which are used in in vitro reconstitution of rough membrane, because these enzymes may interfere with the in vitro reconstitution. It was found that smooth membrane has an active peptidyl-tRNA hydrolase, while the other fractions tested, polyribosomes, rough membrane, stripped rough membrane and the post-microsomal supernatant had no, or very low, peptidyl-tRNA hydrolase activity. Polyribosomes, rough and stripped rough membrane have RNase activity; this activity could be completely inhibited by rat liver RNase inhibitor. It is shown that RNase inhibitor is an obligatory component in in vitro experiments, in which rough membrane is reconstituted from stripped rough membrane, ribosomes and mRNA.     

Physiological concentrations of GTP stimulate fusion of the endoplasmic reticulum and the nuclear envelope

Incubation of highly purified nuclei with rough microsomes stripped of associated ribosomes and physiological concentrations of guanosine triphosphate (GTP) led to the fusion of outer membranes of nuclei with microsomes to form large irregular membrane extensions. Measurement of membrane profiles in electron micrographs revealed that the outer membranes of nuclei incubated under these conditions increased significantly in length compared with that of outer membranes of unincubated or control incubated nuclei. This morphometric assay for fusion was used to check membrane and tissue specificity. It was found that GTP did not stimulate fusion between other intracellular membranes (e.g. mitochondrial or Golgi) or between such membranes and nuclear envelopes. GTP did, however, stimulate fusion between stripped rough microsomes from rat liver and outer membranes of nuclei from rat brain. These studies have revealed that membranes of the rough endoplasmic reticulum and nuclear envelope possess unique recognition and fusion properties and as such constitute the first demonstration of membrane interaction specificity at the intracellular level.     

Differences in the association of ribosomes with heavy rough and light rough endoplasmic reticulum membranes of MPC-11 cells

The treatment of total endoplasmic reticulum membranes of mouse plasmacytoma cells with EDTA resulted in an abolition of the heavy rough (HR) subfraction, while there was a large increase in smooth (S) membranes. When HR and light rough (LR) endoplasmic reticulum membranes were treated individually with EDTA and re-centrifuged on discontinuous sucrose gradients it was observed that HR were converted into S membranes, i.e. membranes virtually devoid of ribosomes. LR membranes were not affected to the same extent but there was a shift to a somewhat lower density. A quantitation of ribosomes released by EDTA showed that 95% of 60 S and 72% of 40 S subunits were removed from HR membranes while for LR membranes the corresponding values were 8.5 and 22.6% respectively. Ratios of radioactivity to absorbance at 260 nm calculated for 40 S and 60 S subunits isolated from HR and LR membranes show that 60 S subunits from LR membranes, in contrast to those from HR membranes, equilibrate only slowly with the free pool of ribosomal subunits. The results indicate that the ribosomes associated with HR membranes are 'loosely bound' and those with LR membranes 'tightly bound'. When poly(A)-containing mRNA isolated from HR and LR membranes was translated in vitro and the products analysed for light-chain immunoglobulin content, it was found that the HR fraction was enriched in light-chain mRNA.     

In vitro binding of ribosomes to the beta subunit of the Sec61p protein translocation complex

The Sec61p complex forms the core element of the protein translocation complex (translocon) in the rough endoplasmic reticulum (rough ER) membrane. Translating or nontranslating ribosomes bind with high affinity to ER membranes that have been stripped of ribosomes or to liposomes containing purified Sec61p. Here we present evidence that the beta subunit of the complex (Sec61beta) makes contact with nontranslating ribosomes. A fusion protein containing the Sec61beta cytoplasmic domain (Sec61beta(c)) prevents the binding of ribosomes to stripped ER-derived membranes and also binds to ribosomes directly with an affinity close to the affinity of ribosomes for stripped ER-derived membranes. The ribosome binding activity of Sec61beta(c), like that of native ER membranes, is sensitive to high salt concentrations and is not based on an unspecific charge-dependent interaction of the relatively basic Sec61beta(c) domain with ribosomal RNA. Like stripped ER membranes, the Sec61beta(c) sequence binds to large ribosomal subunits in preference over small subunits. Previous studies have shown that Sec61beta is inessential for ribosome binding and protein translocation, but translocation is impaired by the absence of Sec61beta, and it has been proposed that Sec61beta assists in the insertion of nascent proteins into the translocation pore. Our results suggest a physical interaction of the ribosome itself with Sec61beta; this may normally occur alongside interactions between the ribosome and other elements of Sec61p, or it may represent one stage in a temporal sequence of binding.     

Biogenesis of endoplasmic reticulum membrane in rat liver cells. II. Discharge of the nascent peptides of NADPH-cytochrome c reductase and cytochrome b5 on the cytoplasmic side of the endoplasmic reticulum membrane.

The direction of discharge of the nascent peptides of NADPH-cytochrome c reductase and cytochrome b5 from bound polyribosomes of rough microsomes was investigated in order to elucidate the mechanism of separation of these membrane proteins from secretory proteins, which are also synthesized by the same class of ribosomes of rough endoplasmic reticulum. The nascent peptides of NADPH-cytochrome c reductase and cytochrome b5 in intact rough microsomes were accessible to externally added 125I-Fab's against these proteins, and were susceptible to trypsin digestion, whereas the nascent peptides of serum albumin were not. The nascent peptides of these two microsomal proteins were released into the cytoplasm by puromycin treatment of intact rough microsomes, while the nascent peptides of serum albumin were retained in the microsomal lumen. These observations suggest that the nascent peptides of microsomal proteins, which are present on the cytoplasmic surface of the endoplasmic reticulum membrane, are exposed on the surface of microsomal vesicles, while those of secretory proteins are enclosed inside the vesicles. Therefore, the topographical separation of microsomal membrane proteins from secretory proteins is accomplished at the step of their synthesis by the bound polyribosomes of rough endoplasmic reticulum.     

IUPAC Commission on the Nomenclature of Organic Chemistry (CNOC) and IUPAC-IUB Commission on Biochemical Nomenclature (CBN). Nomenclature of cyclitols. Recommendations, 1973.

The amino acid-incorporating activities of free polyribosomes, rough membranes and rough membranes reconstituted in vitro, derived from rat liver, were compared. The amino acid-incorporating activity of the two membrane fractions were very similar in their response towards changes in pH, Mg2+ concentration and temperature, but differed from the response of the amino acid-incorporating activity of free polyribosomes. Free polyribosomes irreversibly lost part of their amino acid-incorporating capacity after they had become bound to rough membrane, from which the original ribosomes had been removed. Ribonuclease activity present in the membrane fraction may be responsible for this loss.