Characterization of ribonucleoproteins and ribosomes isolated from lymphocytic choriomeningitis virus.

Disruption of purified lymphocytic choriomeningitis (LCM) virus with Nonidet P-40 in 0.5 M KCl followed by sucrose gradient centrifugation in 0.3 M KCl led to the isolation of two viral nucleoproteins (RNPs) as well as 40S and 60S ribosomal subunits. The largest viral RNP sedimented heterogenously at 123S to 148S and was associated with 23S and 31S viral RNA. The other viral RNP sedimented at 83S and was associated with 23S viral RNA. The buoyant density in CsCl was determined to be 1.32 g/cm3 for the viral RNP. Densities of 1.52 and 1.60 g/cm3 were determined for the 40S and 60S subunits, similar to those of the BHK-21 cells subunits dissociated by 0.5 M KCl. The viral RNPs were partly sensitive to RNase.     

Characterization of ribonucleoprotein particles released from isolated nuclei of regenerating rat liver in two different in vitro systems.

The ribonucleoprotein particles released from isolated nuclei of regenerating rat liver in two in vitro systems were studied and the following results were obtained. 1. When the isolated nuclei of regenerating rat liver labeled in vivo with [14C] orotic acid were incubated in medium containing ATP and an energy-regenerating system (medium I) release of labeled 40-S particles was observed. Analysis of these 40-S particles showed that they contained heterogeneous RNA but no 18 S or 28 S ribosomal RNAs and their buoyant density in CsCl was 1.42-1.45 g/cm3, suggesting that they were nuclear informosome-like particles released during incubation. 2. When the same nuclei were incubated in the same medium fortified with dialyzed cytosol, spermidine and yeast RNA (medium II), release of labeled 60-S and 40-S particles was observed. Using CsCl buoyant density gradient centrifugation, two components were found in the labeled ribonucleoprotein particles released from nuclei in this medium. The labeled 60-S particles were found to contain 28-S RNA as the main component and their buoyant density in CsCl was 1.61 g/cm3, suggesting that they were labeled large ribosomal subunits. The labeled 40-S particles contained both 18 S RNA and heterogeneous RNA and they formed two discrete bands in CsCl, at 1.40 and 1.56 g/cm3, suggesting that they contained small ribosomal subunits and nuclear informosome-like particles. 3. These results clearly indicate that addition of dialyzed cytosol, spermidine and low molecular yeast RNA to medium I causes the release of ribosomal subunits or their precursors from isolated nuclei in the in vitro system.     

Structural characterization of polysomal poly(A)-protein particles in rat liver

Poly(A)-protein particles were prepared from rat liver polyribosomes, washed with 0.5 M KCl or unwashed, after digestion with pancreatic ribonuclease and ribonuclease T1 by two successive rounds of sucrose gradient centrifugation. The particles were sedimented in a range of 5--13 S with a peak at about 9 S. The KCl wash of polysomes had no effect on the sedimentation properties of the particles. The particles isolated in this manner were 99% resistant to further pancreatic ribonuclease treatment and contained about 96% adenylic acid. The length of the poly(A) molecules prepared from the poly(A)-protein particles showed a broad distribution of about 70--290 nucleotides with a peak around 130 nucleotides, as measured by polyacrylamide gel electrophoresis. In CsCl density gradient the poly(A)-protein particles banded in a density range of 1.30--1.42 g/cm3 with a peak at 1.36 g/cm3, which amounts to about 80% of the protein content. Sodium dodecyl sulfate/polyacrylamide and urea/sodium dodecyl sulfate/polyacrylamide gel electrophoresis demonstrated six polypeptides with molecular weights of 50 000, 54 000, 58 000, 63 000, 76 000 and 90 000 in the poly(A)-protein particles, but the main components were dependent on the method. The treatment of polysomes with KCl resulted in a loss of the 90 000-molecular-weight component. Amino acid analysis of the polypeptides bound to poly(A) revealed that they contained a relatively large amount of aspartic plus glutamic acid (21.6%) as well as hydrophobic amino acids (41.4%). Digestion of glutaraldehyde-fixed particles with ribonuclease T2 showed that about 50% of poly(A) was accessible to the enzyme, thus this part of poly(A) was located on the surface of the particles. In the electron micrographs the shadowed poly(A)-protein particles appeared in a globular, somewhat elongated form and were mostly 14-18 nm in diameter. On the basis of the results a model for the 'average' 9-S particles was constructed.     

Characterization of the protein moiety of messenger ribonucleoprotein complexes from duck reticulocytes by two-dimensional polyacrylamide gel electrophoresis.

The protein moiety of duck globin messenger ribonucleoprotein complexes isolated by oligo(dT)-cellulose chromatography or by sucrose gradient centrifugation was analysed by two-dimensional polyacrylamide gel electrophoresis under conditions where the separation in the first dimension occurs according to charge and in the second according to molecular weight. By comparing the pattern of protein from the mRNA - protein complex with that of ribosomal subunits we found that two acidic proteins with an identical molecular weight of about 49 000 and three basic proteins of about Mr 56 000, 64 000 and 73 000 were associated with the duck globin mRNA but were absent from either puromycin/high-salt-derived or 'run-off' ribosomal subunits. The comparison of the proteins from the complex with mRNA with those found in the 0.5 M KCl wash, commonly used as the source of initiation factors, showed also that only the 49 000-Mr protein from the complex could possibly be present in the 0.5 M KCl wash of polyribosomes; proteins with mobilities similar to the other three proteins complexed with mRNA were not detected in the salt wash of polyribosomes.     

Activity of partially purified protein chain initiation factors from the livers of dimethylnitrosamine-treated rats

Partially purified polypeptide chain initiation factors were prepared from the 0.5 M KCl wash of rat liver microsomes. Their activities in connection with dimethylnitrosamine (DMNA)-induced inhibition of protein synthesis were studied by use of the following reactions: (1) poly(U)-directed binding of Phe-tRNA to ribosomes, (2) formation of a GTP-dependent ternary initiation complex with Met-tRNAf, (3) binding of Met-tRNAf to 40-S ribosomal subunits, (4) assembly of a Met-tRNAf containing 80-S ribosomal initiation complex and (5) ribosome-dependent GTPase activity. The inhibition of protein synthesis with DMNA was not associated with a loss of factor activity in any of these reactions. In the binding of Met-tRNAf to 40-S subunits there was a noticeable increase, probably related to the stability of the resulting complex. The Met-tRNA deacylase activity was also increased.     

Reconstitution of the active rat liver 60 S ribosomal subunit from different preparations of core particles and split proteins

Proteins extracted from the 60 S rat liver ribosomal subunit with 50% ethanol/0.5 M K Cl produced only a partial reactivation of the corresponding core particles. In contrast, the same split proteins were able to reactivate the core particles prepared with dimethyl-maleic anhydride (DMMA) to the same level as that observed using the DMMA-split proteins, i.e. 60-80% of the control according to the catalytic activities tested. Comparative analysis of the two split protein fractions showed only four common proteins: P1-P2, which alone restored part of the activities, especially the EF-2-dependent GTPase one, and L10a, L12, which must be responsible for the additional reactivation. The poor ability of the ethanol/KCl core particles to be reactivated was shown to be probably related to a conformational alteration which destabilized the 5 S RNA-protein complex. Proteins present in the ethanol/KCl wash of Saccharomyces cerevisiae 60 S subunits were found to be partly active in subunit reconstitution using rat liver DMMA core particles.     

Ribosomal subunit localization of hemoglobin messenger RNA.

When rabbit reticulocyte polyribosomes are treated with 0.5 M KCl, they dissociate into subunits and release a protein fraction which is required for peptide chain initiation in a cell-free system using KCl-treated subunits as the source of ribosomes. Three independent methods were used to determine the fate of mRNA after KCl treatment of the subunits. These three methods (sucrose gradient analysis of RNA after dissociating it from protein with sodium dodecylsulfate, acrylamide gel electrophoresis of RNA and electron microscopic analysis of subunits) all showed the 8--9-S mRNA to be associated with the small subunit, but not the large subunit. Furthermore, no mRNA was found to be associated with either "native" ribosomal subunit in a reticulocyte lysate.     

Semliki Forest virus capsid protein associates with the 60S ribosomal subunit in infected cells.

Semlike forest virus capsid protein cosedimented with the large ribosomal subunit at 60S in sucrose gradients after treatment of cytoplasm from infected cells with Triton X-100 and EDTA. In CsCl gradients the capsid protein banded with the subunit at a density of 1.56 to 1.57 g/cm3. Most of the capsid protein could be detached from the 60S structure by treatment with 0.8 M KCl. The ribonucleoprotein of the 26S RNA had a sedimentation value of 53S and a density of 1.50 g/cm3 and could thus be separated from the 60S structure. The data suggest that the capsid protein binds to the large ribosomal subunit, but not to the viral 26S RNA.     

Study of the regulation of plastid development in Euglena gracilis. II. Functional localisation and synthesis of ribosomal chloroplast particles (author's transl)]

Chloroplast ribosomes in greening cells of Euglena gracilis are found either in the stroma or bound to thylakoid membranes. The membrane-bound chloroplast ribosomes are of two main types: those which can be released by 0.5 M KCl or by puromycin and 0.5 M KCl, and those which are released by detergent (deoxycholate or Triton X-100) and KCl. The ribosomes which are released by puromycin are presumably bound to chloroplast membrane by nascent peptide chains. Ribosomes released by puromycin are found only during the course of plastidial differentiation at the time of active thylacoid membrane synthesis. Following greening, those ribosomes remain bound to the membranes but can be removed by KCl alone. An analysis of RNA labelling showed that 30-S but not 53-S subunits of membrane-bound ribosomes are of uniform specific activity. This suggests that 30-S subunit exchange in a common pool while 53 S subunits remain membrane bound and do not exchange in a common pool. Membrane-bound chloroplast ribosomes which are released either by puromycin or by detergent are originally derived from loosely bound particles, released by 0.5 M KCl.     

Control of peptide-chain initiation in rat skeletal muscle. Development of methods for preparation of native ribosomal subunits and analysis of the effect of insulin on formation of 40 S initiation complexes

A method was developed for isolation of native ribosomal subunits from rat gastrocnemius muscle. Native 40 S subunits which were isolated by this method retained their associated nonribosomal proteins and consisted primarily of particles with equilibrium densities of 1.41 and 1.48 g/cm3. Based on the binding of radiolabeled Met-tRNAmeti, the 1.41 g/cm3 particle was identified as the 40 S initiation complex. Insulin deficiency in vivo resulting from either diabetes or fasting led to a 2-fold increase in 75 S monomers but had no effect on the numbers of native 40 and 60 S subunits or the relative distribution of the 1.41 and 1.48 g/cm3 particles. The rate of protein synthesis in perfused muscle preparations derived from insulin-deficient rats was reduced to about half the control value. Addition of insulin to the perfusate restored protein synthesis and 75 S monomers to control levels. The effect of insulin on protein synthesis was associated with a 1.5-fold increase in the amount of Met-tRNAmeti bound to the 1.41 g/cm3 particle. These findings identify formation of 40 S initiation complexes as a site of action of insulin on protein synthesis in skeletal muscle.     

The binding of Met-tRNAf to isolated 40-S ribosomal subunits and the formation of Met-tRNAf - 80-S-ribosome initiation complexes.

Different forms of 40-S ribosomal subunit, distinguishable by their buoyant densities on CsCl equilibrium density gradients, are formed when derived 40-S ribosomal subunits are incubated with partially purified reticulocyte ribosomal wash proteins. One of these subunits, the 1.37-g-cm-3 form is not present in the cell but the other two forms, the 1.40-g-cm-3 and 1.40-g-cm-3 subunits, are present in cell extracts. 35S label is bound to 1.37-g-cm-3 and 1.40-g-cm-s subunits when [35S]Met-tRANf, GTP and poly(A,U,G) are included in the incubations. The 35S-labelled 40-S subunits recovered, and the amount of 35S label bound to them, are changed if the [35S]Met-tRNAf-40-S-subunit-poly(A,U,G) complexes are first purified on sucrose gradients before analysing them on CsCl. The 1.37-g-cm-3 particle is no longer seen and the total quantity of 35S label on the 40-S subunits is 90% lower after sucrose gradient purification. Between 30% and 40% of the 40-S subunits bind [35S]Met-tRNAf when 1 mM GTP, an excess of ribosomal wash proteins and [35S]Met-tRNAf over derived 40-S subunits, and poly(A,U,G) or AUG is included in the incubations. The omission of poly(A,U,G) or AUG from the incubations substantially lowers the amount of subunit-bound 35S label ultimately recovered. With these incubations less than 10% of the 40-S subunits have bound [35S]Met-tRNAf. [35S]Met-tRNAf binding is affected by the nature of the RNA added. The addition of poly(U), rRNA and native 9-S golbin mRNA is without effect, whereas denatured globin mRNA is stimulatory. Maximum binding is obtained however with AUG. Poly(A,U,G) is less stimulatory than AUG but more stimulatory than denatured mRNA, suggesting that the number as well the accessibility of the AUG initiations condons determines the amount of 35S label bound. Similar results are obtained for the ribosomal-wash-dependent binding of [35S]Met-tRNAf to 80-S ribosomes. Contrary to the binding results, the ability of mRNA to stimulate protein synthesis is dependent on the integrity of the mRNA. Thus, native 9-S globin mRNA but not poly(A,U,G) stimulatex protein synthesis in the wheat germ system. HCHO-treated globin mRNA, although stimulatory, is 45% less effective than native mRNA. The addition of AUG, derived 60-S subunits and extra ribosomal wash is required for the formation of [35S]Met-tRNAf-80-S-ribosome complexes from sucrose-gradient-purified [35S]Met-tRNAf-40-S-subunit complexes. The 80-S ribosome complexes are able to form peptide bonds. Thus, if puromycin is added to the full incubations at zero time, no 35S label is present on the 80-S ribosome. 35S label is released as methionyl-puromycin. If the [35S]Met-tRNAf-40-S-subunit complexes are assembled with poly(A,U,G) or AUG in the incubations and then purified, only derived 60-S subunits are required to form [35S]Met-tRNAf-80-S-ribosome complexes. 35S label is not released from them when puromycin is added to the incubations unless extra ribosomal wash is also added.     

Cycloheximide enhances factor binding to the native 40S ribosomal subunit of Microsporum canis

Native and derived ribosomal particles from the mycelial cells of Microsporum canis grown in the presence and absence of cycloheximide were compared by CsCl equilibrium density gradient centrifugation. Since the buoyant densities of ribonucleoprotein complexes are dependent on the protein-RNA ratio, they reflect the composition of these particles. The native monosomes from cells grown in the presence and absence of cycloheximide had a buoyant density of 1.585 g/cc. The native 60S subunits showed a density of 1.540 g/cc from cells grown in both presence and absence of cycloheximide, while the derived subunits showed a density of 1.610 g/cc. The derived 40S subunits had a density of 1.550 g/cc while the native 40S showed a major species of density 1.535 g/cc with three other minor species ranging in densities from 1.450-1.390 g/cc. The mycelia grown in the presence of cycloheximide showed an increased proportion of native 40S subunits in the density range of 1.450-1.390 g/cc, indicating that the drug enhances factor binding to native ribosomal subunits in M. canis.     

Cell-free translation of frog virus 3 messenger RNAs. Initiation factors from infected cells discriminate between early and late viral mRNAs

Cell-free protein-synthesizing extracts prepared from rabbit reticulocytes, wheat germ, or cultured baby hamster kidney cells efficiently translated frog virus 3 early mRNAs; in contrast, late mRNAs were translated poorly under similar conditions. However, the translational efficiency of the late viral mRNAs was markedly enhanced in cell-free extracts prepared from frog virus 3 (FV 3)-infected baby hamster kidney cells and in nuclease-treated rabbit reticulocyte extracts by the addition of a 0.5 M KCl wash from FV 3-infected cell ribosomes; the 0.5 M KCl wash (initiation factors) from uninfected cells had no such effect. Total cytoplasmic RNA from infected cells was fractionated according to size on sucrose gradients and fractions containing different concentrations, and relative proportions of early and late mRNAs were translated in either native or initiation factor-supplemented extracts. Under these conditions, the translation efficiency of early mRNAs was unchanged, while the translation of late mRNAs increased 2-7-fold. Thus, the in vitro discriminatory activity of the 0.5 M wash was not dependent on the complexity of the mRNAs present in the translation mixture. We show also that in native extracts, under conditions of blocked polypeptide chain elongation, early mRNAs are initiated preferentially. However, late as well as early mRNAs are initiated equally well in reticulocyte extracts under similar experimental conditions when supplemented with crude initiation factors from infected cells. These data support the conclusion that the translational enhancement of FV 3 mRNAs in vitro is mediated by a virus-specified or virus-modified initiation factor(s) and likely represents a regulatory mechanism of protein synthesis operative in vivo (Willis, D. B., Goorha, R., Miles, M., and Granoff, A. (1977) J. Virol. 24, 326-342).     

Protein synthesis in brine shrimp embryos. Dormant and developing embryos of Artemia salina contain equivalent amounts of chain initiation factors 2.

Dormant and developing embryos of Artemia salina contain equivalent amounts of eIF-2, the eukaryotic initiation factor which forms a ternary complex with GTP and Met-tRNAf. The factor was purified from 0.5 M NH4Cl ribosomal washes by (NH4)2SO4 fractionation, followed by chromatography on heparin-Sepharose, DEAE-cellulose, hydroxyapatite and phosphocellulose. Purified preparations from dormant and developing embryos have similar specific activities and nucleotide requirements. The mobility of both proteins in dodecylsulfate gel electrophoresis is indistinguishable, and each contains three major polypeptide chains of molecular weight 52 000, 45 000 and 42 000. Both proteins are also immunologically identical, and each stimulates amino acid incorporation in a cell-free system of protein synthesis. The binding of [35S]Met-tRNAf to 40-S ribosomal subunits is catalyzed by eIF-2 isolated from dormant or developing embryos and is dependent upon GPT and AUG. Binding of [35S]Met-tRNAf to 40-S ribosomal subunits, and ternary complex formation with eIF-2, GTP, and [35S]Met-tRNAf is stimulated 2--3-fold by a factor present in the 0.5 M NH4Cl ribosomal wash and which elutes from DEAE-cellulose at 50 mM KCl. This protein does not exhibit GTP-dependent binding of [35S]Met-tRNAf. Binding of GDP and GTP was investigated with purified eIF-2 from developing embryos. The factor forms a binary complex with GDP or GTP, and eIF-2-bound [3H]GDP exchanges very slowly with free nucleotides. Our results suggest that eIF-2 does not limit resumption of embryo development following encystment, nor does it limit mRNA translation in extracts from dormant embryos.     

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.     

Photo-induced protein-RNA cross-linking in mammalian 60-S ribosomal subunits.

Rat liver 60-S ribosomal subunits were submitted to increasing doses of radiation (253.7 nm), at 4 degrees C and 25 degrees C, as previously reported fro 40-S subunits. The existence of protein-RNA cross-linking was demonstrated by two methods. The first consisted in the separation of protein-RNA complex; the second was indirect, and took into account alteration either in the electrophoretic mobility of cross-linked proteins or the separability of 28-S RNA in a 4 M urea/3 M LiCl buffer. The peptide synthetase activity and the sedimentation characteristics of the particles irradiated at 4 degrees C were well preserved, but at 25 degrees C the large subunits were progressively inactivated and unfolded for doses higher than 2 x 10(18) quanta. The dose-dependent variations of protein cross-linkage determined by two-dimensional gel electrophoresis allowed us to distinguish those proteins which reacted at the lowest doses with a first-order reaction from those which cross-linked to RNA after a subtle modification of the subunit structure. At 25 degrees C, all proteins became low-dose reactive. The curve obtained for 28-S RNA cross-linkage was similar to that of the total protein moiety, while those obtained fro the 5-S and 5.8-S RNA (which were parallel) suggest a lower reactivity of these RNAs. As a general rule, proteins from the large subunits were more reactive to RNA than those from the small subunits. This could indicate differences in the organisation of the two subunits.     

Ribosomal subunits from Tetrahymena pyriformis. Isolation and properties of active 40-S and 60-S subunits.

Tetrahymena pyriformis ribosomal subunits were obtained by incubation of post-mitochondrial supernatant in the presence of 0.2 mM GTP and 0.1 mM puromycin for 45 min at 28 degrees C, followed by sucrose density gradient centrifugation. Isolated 40-S subunits were able to reassociate in vitro in the presence of 5 mM MgCl2 and 50 mM KCl and to perform poly(U)-dependent protein synthesis. The 60-S subunit carries the peptidyl transferase activity. The number of proteins in T. pyriformis ribosomal subunits was determined by two-dimensional polyacrylamide gel electrophoresis. The 40-S subunit contains 30 different protein species (including two acidic proteins). The 60-S subunit contains 35 different protein species (including two acidic proteins). The proteins were numbered following the system of Kaltschmidt and Wittmann.     

Methionyl-tRNA-Met-f deacylase. Purification, characterization, and effects on translational initiation complexes.

A methionyl-tRNA-Met-f deacylase was found in ribosomal salt wash from cultured human cells of the HeLa line. This enzyme was purified by the use of DEAE-cellulose, ammonium sulfate precipitation, gel filtration and isoelectric focusing, and appears to be a protein with a native molecular weight of 80,000, which consists of two 40,000-Mr subunits. The mechanism of the Met-tRNA-Met-f deacylase is shown to involve end-product inhibition by the deacylated form of Met-tRNA-Met-f. The methionyl-tRNA-Met-f deacylase is rather specific for Met-tRNA-Met-f as opposed to Met-tRNA-Met-m, has a KCl optimum of 85 mM, is inhibited by MgCl2 and is inhibited by GTP and NAD+ at physiological concentration. 40-S and 60-S subunits inhibit the enzyme, possibly by binding to it. The stability of translational initiation complexes, containing methionyl-tRNA-Met-f, was investigated in the presence of the enzyme. Purified ternary complex was slowly broken down by the enzyme, while the 40-S-subunit . Met-tRNA-Met-f complex was stable in the presence of enzyme. The 80-S complex formed with A-U-G trinucleotide as the message molecule was broken down, whereas the 80-S complex formed with globin mRNA was stable in the presence of the enzyme. The physiological role of this enzyme is unclear, but it might act to regulate initiation by deacylating Met-tRNA-Met-f.     

In vitro translation studies of the cytoplasmic nonpolysomal particles containing messenger RNA.

We analyzed the translational capacity of different kinds of free cytoplasmic messenger ribonucleoprotein complexes (free mRNP) in a Hela cell cell free system. Native free mRNP are not translated although free mRNP washed with 0.5 M KC1 can direct polypeptide synthesis. Furthermore, the 0.5 M KC1 wash possesses a factor which inhibits the translation of 0.5 M KC1 washed free mRNP as well as globin mRNA naked mRNA from plasmocytoma, or Hela cells. We also demonstrated that native free mRNP are able to form a complex with ribosomal subunits in the presence of initiation factors. This indicates that inhibition of translation by the 0.5 M KC1 wash occurs either at some point after initiation complex formation or at the elongation step.     

Characterization of 20-S and 40-S non-polysomal cytoplasmic messenger ribonucleoprotein particles from rat liver

Two populations of free messenger ribonucleoprotein (mRNP) particles, sedimenting at 20 S and 40 S respectively, were isolated from a rat liver postpolysomal supernatant. After treatment with 0.5 M KCl and recentrifugation through a sucrose layer, the mRNP particles were characterized with respect to their low-molecular-weight RNA and protein components. 40-S and 20-S particles show very different RNA patterns. Four distinct low-molecular-weight RNA species of approximately 105, 139, 187 and 256 nucleotides were found as components of the 40-S mRNPs. The 20-S mRNP particles contain one major low-Mr RNA species of approximately 243 nucleotides and a characteristic pattern of low-Mr RNAs similar to the one found in nuclear ribonucleoprotein particles. In contrast to the low-Mr RNAs found in nuclear RNP particles most of the low-Mr RNA species present in 20-S and 40-S mRNP particles are rapidly labeled after [3H]orotate administration. Whereas the low-Mr RNA composition of 20-S and 40-S mRNP particles is very different, the protein patterns of both mRNP complexes are very similar. Six major polypeptides with the following molecular weights of 117000, 79800, 76700, 53800, 43900, 36300 and several minor ones were found in both 20-S and 40-S mRNPs. In a cell-free system from wheat germs neither 20-S nor 40-S mRNP particles stimulated the incorporation of [3H]leucine into proteins. However, phenol-extracted RNA from 20-S and 40-S mRNPs stimulated total protein synthesis 16-fold and 3-fold, respectively. Furthermore, the RNA from both mRNP pools directed the synthesis of albumin in vitro.