Assembly of membrane-bound polyribosomes

Where has all the message gone?

We provide a brief history of polyribosomes, ergosomes, prosomes, informosomes, maternal mRNA, stored mRNA, and RNP particles. Even though most published research focuses on total mRNA rather than polysomal mRNA and often assumes they are synonymous - i.e., if a functional mRNA is present, it must be translated - results from our laboratories comparing polysomal RNA and total mRNA in a range of "normal" issues show that some transcripts are almost totally absent from polysomes while others are almost entirely associated with polysomes. We describe a recent model from yeast showing various destinies for polysomal mRNA once it has been released from polysomes. The main points we want to emphasize are; a) when mRNA leaves polysomes to go to prosomes, P-bodies, stress granules, etc., it is not necessarily destined for degradation - it can be re-utilized; b) "normal" tissue, not just seeds and stressed tissue, contains functional non-polysomal mRNA; c) association of mRNA with different classes of polysomes affects their sub-cellular location and translatability; and d) drawbacks, misinterpretations, and false hopes arise from analysis of total mRNA rather than polysomal mRNA and from presuming that all polysomes are "created equal".

A platform for compartmentalized protein synthesis: protein translation and translocation in the ER

Recent advances in the study of protein translocation across the membrane of the endoplasmic reticulum include insights into the mechanism of signal-sequence function. Biochemical and genetic studies have provided further evidence that lumenal proteins perform direct roles in secretory protein translocation and in the regulation of protein-conducting-channel permeability during membrane protein integration. A hypothesis identifying the endoplasmic reticulum as a site of mRNA localization and compartmentalized protein synthesis has been suggested.

The fate of membrane-bound ribosomes following the termination of protein synthesis

Contemporary models for protein translocation in the mammalian endoplasmic reticulum (ER) identify the termination of protein synthesis as the signal for ribosome release from the ER membrane. We have utilized morphometric and biochemical methods to assess directly the fate of membrane-bound ribosomes following the termination of protein synthesis. In these studies, tissue culture cells were treated with cycloheximide to inhibit elongation, with pactamycin to inhibit initiation, or with puromycin to induce premature chain termination, and ribosome-membrane interactions were subsequently analyzed. It was found that following the termination of protein synthesis, the majority of ribosomal particles remained membrane-associated. Analysis of the subunit structure of the membrane-bound ribosomal particles remaining after termination was conducted by negative stain electron microscopy and sucrose gradient sedimentation. By both methods of analysis, the termination of protein synthesis on membrane-bound ribosomes was accompanied by the release of small ribosomal subunits from the ER membrane; the majority of the large subunits remained membrane-bound. On the basis of these results, we propose that large ribosomal subunit release from the ER membrane is regulated independently of protein translocation.

Characterization of secretory protein translocation: ribosome-membrane interaction in endoplasmic reticulum

Secretory proteins are synthesized on ribosomes bound to the membrane of the endoplasmic reticulum (ER). After the selection of polysomes synthesizing secretory proteins and their direction to the membrane of the ER via signal recognition particle (SRP) and docking protein respectively, the polysomes become bound to the ER membrane via an unknown, protein-mediated mechanism. To identify proteins involved in protein translocation, beyond the (SRP-docking protein-mediated) recognition step, controlled proteolysis was used to functionally inactivate rough microsomes that had previously been depleted of docking protein. As the membranes were treated with increasing levels of protease, they lost their ability to be functionally reconstituted with the active cytoplasmic fragment of docking protein (DPf). This functional inactivation did not correlate with a loss of either signal peptidase activity, nor with the ability of the DPf to reassociate with the membrane. It did correlate, however, with a loss of the ability of the microsomes to bind ribosomes. Ribophorins are putative ribosome-binding proteins. Immunoblots developed with monoclonal antibodies against canine ribophorins I and II demonstrated that no correlation exists between the protease-induced inability to bind ribosomes and the integrity of the ribophorins. Ribophorin I was 85% resistant and ribophorin II 100% resistant to the levels of protease needed to totally eliminate ribosome binding. Moreover, no direct association was found between ribophorins and ribosomes; upon detergent solubilization at low salt concentrations, ribophorins could be sedimented in the presence or absence of ribosomes. Finally, the alkylating agent N-ethylmaleimide was shown to be capable of inhibiting translocation (beyond the SRP-docking protein-mediated recognition step), but had no affect on the ability of ribosomes to bind to ER membranes. We conclude that potentially two additional proteinaceous components, as yet unidentified, are involved in protein translocation. One is protease sensitive and possibly involved in ribosome binding, the other is N-ethylmaleimide sensitive and of unknown function.

Protein translocation across and integration into membranes

This review concentrates mainly on the translocation of proteins across the endoplasmic reticulum membrane and cytoplasmic membrane in bacteria. It will start with a short historical review and will pinpoint the crucial questions in the field. Special emphasis will be given to the present knowledge on the molecular details of the first steps, i.e., on the function of the signal recognition particle and its receptor. The knowledge on the signal peptidase and the ribosome receptor(s) will also be summarized. The various models for the translocation of proteins across and the integration of proteins into membranes will be critically discussed. In particular, the function of signal, stop-transfer, and insertion sequences will be dealt with and molecular differences discussed. The cotranslational mode of membrane transfer will be compared with the post-translational transport found for mitochondria and chloroplasts. This review will conclude with open questions and an outlook.

Subcellular compartmentation of albumin and globin made in oocytes under the direction of injected messenger RNA

The Xenopus oocyte can be used to study the nature and specificity of the translational and post-translational systems of a normal living cell. We describe experiments combining messenger RNA microinjection and subcellular fractionation. Total Xenopus liver RNA directs the synthesis of albumin and vitellogenin contained within membrane vesicles; similarly, guinea pig mammary gland mRNA codes for membrane-bound protease-resistant milk proteins. In contrast, iodinated albumin protein injected into oocytes remains in the supernatant fraction, as does globin made on mRNA. The information encoded in the albumin messenger is therefore sufficient to specify synthesis of a membrane-bound product; moreoever, this highly efficient coupled translation-processing system may be of use in the study of the transfer of newly made proteins across membranes. A significant proportion (up to 20%) of newly made oocyte proteins enter a light membrane fraction, and many remain there. We speculate that these vesicles represent part of an important storage system.

Comparison between the ribosomal ribonucleic acids from free and membrane-bound ribosomal fractions of HeLa cells

The rRNA species from the total cytoplasmic, free and membrane-bound fractions of HeLa cells were compared. With the use of T1 ribonuclease and combined T1 ribonuclease plus pancreatic ribonuclease 'fingerprinting' procedures, no significant differences were found between the rRNA species from the different subcellular fractions.

Structure of rough, smooth, stripped and reconstituted rough membranes derived from rat liver as visualized by the freeze fracture technique

The structure of purified fractions of rough, smooth, stripped rough and reconstituted rough membranes have been investigated by the freeze etching technique. Preparations of rough and reconstituted rough membranes, active in protein synthesis, show vesicles whose outer surface is covered with ribosome-like particles. The inner surface of these vesicles contains also numerous particles of the same size. The particles located on the outer surface are largely absent in the stripped rough membrane preparations which, however, retain the particles located on the inner face. Particles were not seen either on the outer nor on the inner face of the smooth membranes. The possibility is considered that the particles located on the inner face are specific to the rough membranes and might play a role in the specific binding of ribosomes to the membranes.

Membrane-bound ribosomes of myeloma cells. II. Kinetic studies on the entry of newly made ribosomal subunits into the free and the membrane-bound ribosomal particles

The kinetics of appearance of newly made 60S and 40S ribosomal subunits in the free and membrane-bound ribosomal particles of P3K cells were explored by determining the specific radioactivities of their 18S and 28S RNA after various lengths of [3H]uridine pulse. Both 40S and 60S subunits enter free and membrane-bound polyribosomes at comparable rates from the cytoplasmic pool of newly made, free native subunits, the 40S subunits entering the native subunit pool and the polyribosomes slightly earlier than the 60S subunits. At all times, the specific radioactivity of the membrane-bound native 60S subunits was slightly lower than that of the polyribosomal 60S subunits. This indicates that the membrane-bound native 60S subunits are not precursors destined to enter membrane-bound polyribosomes and suggests that they result from the dissociation of ribosomes after chain termination. The results observed also suggest that the membrane-bound native 60S subunits are not reutilized before their release from the membranes, which probably takes place shortly after dissociation from their 40S subunits. The monoribosomes, both free and membrane-bound, had the lowest specific radioactivities in their subunits. Finally, a small amount of newly made native 40S subunits, containing 18S RNA of high specific radioactivity, and apparently also newly made messenger RNA were detected on the membranes. The high turnover of these membrane-bound native 40S subunits suggests that they may represent initiation complexes formed with mRNA which has just reached the membranes and which has not yet given rise to polyribosomes.

Membrane-bound ribosomes of myeloma cells. I. Preparation of free and membrane-bound ribosomal fractions. Assessment of the methods and properties of the ribosomes

A cell fractionation procedure is described which allowed, by use of MOPC 21 (P3K) mouse plasmocytoma cells in culture, the separation of the cytoplasmic free and membrane-bound ribosomes in fractions devoid of mutual cross-contamination, and in which the polyribosomal structure was entirely preserved. This was achieved by sedimentation on a discontinuous sucrose density gradient in which the two ribosome populations migrate in opposite directions. A variety of controls (electron microscopy, labeling of membrane lipids, further repurification of the isolated fractions) provided no evidence of cross-contamination of these populations. However, when an excess of free 60S or 40S subunits, labeled with a different isotope, was added to the cytoplasmic extract before fractionation, the possibility of a small amount of trapping and/or adsorption of free ribosomal particles by the membrane fraction was detected, especially in the case of the 60S subunits; this could be entirely prevented by the use of sucrose gradients containing 0.15 M KC1. EDTA treatment of the membrane fraction detached almost all the 40S subunits, and about 70% of the 60S subunits. 0.5 M KC1 detached only 10% of the ribosomal particles, which consist of the native 60S subunits and the monoribosomes, i.e. the bound particles inactive in protein synthesis. Analysis in CsC1 buoyant density gradients of the free and membrane-bound polyribosomes and of their derived 60S and 40S ribosomal subunits showed that the free and membrane-bound ribosomal particles have similar densities.

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.

Characterization of light chain and light chain constant region fragment mRNAs in MPC 11 mouse myeloma cells and variants

Cultured MPC 11 mouse myeloma cells synthesize not only gamma2b heavy and kappa light chains but also a carboxyl terminal (constant region) fragment of kappa light chain. In vitro translational analysis of total cytoplasmic and microsomal RNA indicates that these cells contain RNA which directs synthesis of both a light chain precursor and a light chain fragment precursor. Variant clones which do not synthesize either heavy or light chains continue to synthesize the light chain fragment. One such "nonproducing" variant was studied in detail. It does not contain translatable mRNA for the intact light chain but does contain RNA which is translated into the light chain fragment precursor. Nucleic acid hybridization analysis with a cDNA probe specific for the constant region of kappa light chains revealed that microsomal RNA from the wild-type cell contains both 14S and a 10S species of kappa specific RNA, whereas the variant contains only the 10S species. Translational analysis of these same RNAs indicates that the 14S species codes for the light chain precursor, while the 10S RNA codes for the light chain fragment precursor.

Free and membrane-bound ribosomes. II. Two-dimensional gel electrophoresis of proteins from free and membrane-bound rabbit reticulocyte ribosomes

Free and membrane-bound polysomes were isolated from rabbit reticulocytes. The membrane-bound polysomes were liberated form the membrane with deoxycholate. Monosomes were prepared from the two types of polysomes by incubation with puromycin. The ribosomal proteins were extracted and analyzed by two-dimensional gel electrophoresis. Two proteins of the large subunit, L11 and L17 present in the free monosomes were not found in the membrane-bound monosomes. On the other hand, four additional spots were found in the protein pattern of the membrane-bound monosomes.

Virus-specific messenger RNA and nascent polypeptides in polyribosomes of cells replicating murine sarcoma-leukemia viruses

We present evidence that virus-specific RNA is present in polyribosomes of transformed cells replicating the murine sarcoma-leukemia virus complex and that it serves as messenger RNA for the synthesis of viral-coded proteins. Both virus-specific RNA (detected by hybridization with the [(3)H]DNA product of the viral RNA-directed DNA polymerase) and nascent viral polypeptides (measured by precipitation with antiserum to purified virus) were found in membrane-bound and free polyribosomes. Membrane-bound polyribosomes contained a higher content of both virus-specific RNA and nascent viral polypeptides. From 60 to 70% of viral RNA sequences were released from polyribosomes with EDTA, consistent with a function as messenger RNA. Maximum amounts of both virus-specific RNA and nascent viral polypeptides were found in the polyribosome region sedimenting at about 350 S.

The binding of polyribosomes to smooth and rough endoplasmic-reticulum membranes

In vitro the binding of polyribosomes to smooth endoplasmic-reticulum membranes is more sensitive to ionic strength than is the binding to rough endoplasmic-reticulum membranes. Polyribosomes from the free and membrane-bound fractions bind with equal efficiency to endoplasmic-reticulum membranes.

Estimation of light-chain gene reiteration of mouse immunoglobulin by DNA-RNA hybridization

A 12S species of RNA has been isolated from membrane-bound polyribosomes of MPC-11 mouse myeloma cells. This 12S RNA is translated by an extract of Krebs-II mouse ascites cells into immunoglobulin light chain. Labeled 12S RNA has been prepared by incubation of myeloma cells with [(3)H]uridine in the presence of low concentrations of actinomycin D and ethidium bromide. This RNA has been hybridized under conditions of DNA excess to mouse myeloma DNA and to liver DNA. A C(0)t(1/2) of about 150 has been obtained, corresponding to a reiteration frequency of about 40. Unlabeled 12S RNA competes with the labeled species in hybridization experiments, whereas globin mRNA or mouse ascites 12S RNA does not. It is suggested that 12S RNA hybridizes only to V(kappa)-genes of the same subclass, and that there may be several hundred genes coding for V(kappa)-regions of all subclasses in a mouse genome. Moreover, gene amplification in myeloma cells is not detected.

The binding of ribosomal subunits to endoplasmic reticulum membranes

The binding of ribosomes and ribosomal subunits to endoplasmic reticulum preparations of mouse liver was studied. (1) Membranes prepared from rough endoplasmic reticulum by preincubation with 0.5m-KCl and puromycin bound 60-80% of added 60S subunits and 10-15% of added 40S subunits. Membranes prepared with pyrophosphate and citrate showed less clear specificity for 60S subunits particularly when assayed at low ionic strengths. (2) Ribosomal 40S subunits bound efficiently to membranes only in the presence of 60S subunits. The reconstituted membrane-60S subunit-40S subunit complex was active in synthesis of peptide bonds. (3) No differences in binding to membranes were seen between subunits derived from free and from membrane-bound ribosomes. (4) It is concluded that the binding of ribosomes to membranes does not require that they be translating a messenger RNA, and that the mechanism whereby bound and free ribosomes synthesize different groups of proteins does not depend on two groups of ribosomes that differ in their ability to bind to endoplasmic reticulum.