Partial reconstitution of 60S ribosomal subunits from yeast

Summary Ribosomal 60S subunits active in polyphenylalanine synthesis can be reconstituted from core particles lacking 20–40% of the total protein. These core particles were obtained by treatment of yeast 60S subunits with dimethylmaleic anhydride, a reagent for protein amino groups. Upon reconstitution a complementary amount of split proteins is incorporated into the ribosomal particles, which have the sedimentation coefficient of the original subunits. Ribosomal protein fractions obtained by extraction with 1.25 M NH₄Cl, 4 M LiCl, 7 M LiCl, or 67% acetic acid, are much less efficient in the reconstitution of active subunits from these core particles than the corresponding released fraction prepared with dimethylmaleic anhydride. Attempts to reconstitute active subunits from protein-deficient particles obtained with 1.25 M NH₄Cl plus different preparations of ribosomal proteins, including the fraction released with dimethylmaleic anhydride, were unsuccessful. Therefore, under our conditions, of the disassembly procedures assayed only dimethylmaleic anhydride allows partial reconstitution of active 60S subunits.Abbreviation DMMA dimethylmaleic anhydride     

Disassembly and reconstitution of yeast 60S ribosomal subunits

Summary Yeast 60S ribosomal subunits have been dissociated by reversible modification with dimethylmaleic anhydride. Treatment with 40 mol reagent/ml releases 35% of the protein, producing core particles inactive in polyphenylalanine synthesis, which are totally or highly deficient in 17 different proteins. This preparation of residual particles recovers 45% of the original activity upon incubation with the released proteins. The reconstituted particles can be isolated by centrifugation without loss of activity, having the protein composition of the original subunits.Abbreviations DMMA Dimethylmaleic Anhydride     

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.     

Partial reassembly of active 60S ribosomal subunits from rat liver following treatment with dimethylmaleic anhydride

Rat liver 60S ribosomal subunits were treated with dimethylmaleic anhydride, a reagent for protein amino groups, at a 1/15,000 mol/mol ratio. This caused the dissociation of specific proteins, which were separated from the 56S residual core particles by centrifugation and identified by two-dimensional gel electrophoresis. The core particles lacking 30% of the total proteins retained most of the initial activity measured by the puromycin reaction but only small percentages of activities measured by polyphenylalanine synthesis, elongation-factor-2(EF-2)-dependent GTP hydrolysis and EF-2-mediated GDP binding. Upon reconstitution, the complementary amount of split proteins was incorporated into ribosomal particles, which had almost the same catalytic activities and biophysical properties (density, sedimentation coefficient and capability to reassociate to 40S subunits) as the original subunits.     

The binding site of ribosomal protein L10 in eubacteria and archaebacteria is conserved: reconstitution of chimeric 50S subunits.

It has been shown by electron microscopy that the selective removal of the stalk from 50S ribosomal subunits of two representative archaebacteria, namely Methanococcus vaniellii and Sulfolobus solfataricus, is accompanied by loss of the archaebacterial L10 and L12 proteins. The stalk was reformed if archaebacterial core particles were reconstituted with their corresponding split proteins. Next, structurally intact chimeric 50S subunits have been reconstituted in vitro by addition of Escherichia coli ribosomal proteins L10 and L7/L12 to 50S core particles from M vaniellii or S solfataricus, respectively. In the reverse experiment, using core particles from E coli and split proteins from M vaniellii, stalk-bearing 50S particles were also obtained. Analysis of the reconstituted 50S subunits by immunoblotting revealed that E coli L10 was incorporated into archaebacterial core particles in both presence or absence of E coli L7/L12. In contrast, incorporation of E coli L7/L12 into archaebacterial cores was only possible in the presence of E coli L10. Our results suggest that in archaebacteria - as in E coli - the stalk is formed by archaebacterial L12 proteins that bind to the ribosome via L10. The structural equivalence of eubacterial and archaebacterial L10 and L12 proteins has thus for the first time been established. The chimeric reconstitution experiments provide evidence that the domain of protein L10 that interacts with the ribosomal particle is highly conserved between eubacteria and archaebacteria.     

Partial reassembly of yeast 60 S ribosomal subunits in vitro following controlled dissociation under nondenaturing conditions

Previously it has been shown that 12 of the yeast ribosomal proteins were extractable from 60 S subunits under a specific nondenaturing condition [J. C. Lee, R. Anderson, Y. C. Yeh, and P. Horowitz (1985) Arch. Biochem. Biophys. 237, 292-299]. In the present paper, we showed that these proteins could be reassembled with the corresponding protein-deficient core particles to form biologically active ribosomal subunits. Effects of time, temperature, and varying concentrations of monovalent cations, divalent cations, cores, and ribosomal proteins on reconstitution were examined. Reconstitution was determined by binding of radiolabeled proteins to the nonradiolabeled cores as well as activity for polypeptide synthesis in a cell-free protein-synthesizing system. The optimal conditions for reconstitution were established. Whereas the core particles were about 10-20% as active as native 60 S subunits in an in vitro yeast cell-free protein-synthesizing system, the reconstituted particles were 80% as active. The activity of the reconstituted particles was proportional to the amount of extracted proteins added to the reconstitution mixture. About 55 +/- 7% of the core particles recombined with the extracted proteins to form reconstituted particles. These reconstituted particles cosedimented with native 60 S subunits in glycerol gradients and contained all of the 12 extractable proteins.     

Immunochemical analysis of the structure of eukaryotic ribosomes

Summary Antibodies were prepared in rabbits and sheep to rat liver ribosomes, ribosomal subunits, and to mixtures of proteins from the particles. The antisera were characterized by quantitative immunoprecipitation, by passive hemagglutination, by immunodiffusion on Ouchterlony plates, and by immunoelectrophoresis. While all the antisera contained antibodies specific for ribosomal proteins, none had precipitating antibodies against ribosomal RNA. Rat liver ribosomal proteins were more immunogenic in sheep than rabbits, and the large ribosomal subunit and its proteins were more immunogenic than those of the 40S subparticle. Antisera specific for one or the other ribosomal subunit could be prepared; thus it is unlikely that there are antigenic determinants common to the proteins of the two subunits. When ribosomes, ribosomal subunits, or mixtures of proteins were used as antigens the sera contained antibodies directed against a large number of the ribosomal proteins.Abbreviations TP total proteins—used to designate mixtures of proteins from ribosomal particles, hence TP80 is a mixtures of all the proteins from 80S ribosomes - TP60 the proteins from 60S subunits - TP40 the proteins from 40S particles     

Protein-deficient ribosomal particles obtained by reversible modification with dimethylmaleic anhydride

Preparation of protein-deficient ribosomal particles from Escherichia coli ribosomes by reversible modification of protein amino groups with dimethylmaleic anhydride (J. A. Pintor-Toro, D. Vázquez, and E. Palacián, 1979, Biochemistry18, 3219) is accompanied by degradation of r-RNA and reagent-independent inactivation. Alternative conditions to regenerate the modified amino groups have been found, which reduce the time needed to prepare the ribosomal “cores” from 9 to 3 days, and prevent RNA degradation and inactivation. The ribosomal particles obtained from 70 S ribosomes and 50 S subunits by this modified procedure show no extensive degradation of RNA and very little reagent-independent inactivation, which allow good recovery of the polypeptide synthesizing activity when incubated with the corresponding split proteins.     

The accessibility of antigenic determinants of ribosomal protein s4 in situ

Antibodies to Escherichia coli ribosomal protein S4 react with S4 in subribosomal particles, eg, the complex of 16S RNA with S4, S7, S8, S15, S16, S17, and S19 and the RI* reconstitution intermediate, but they do not react with intact 30S subunits. Antibodies were isolated by three different methods from antisera obtained during the immunization of eight rabbits. Some of these antibody preparations, which contained contaminant antibodies directed against other ribosomal proteins, reacted with subunits, but this reaction was not affected by removal of the anti-S4 antibody population. Other antibody preparations did not react with subunits. It is concluded that the antigenic determinants of S4 are accessible in some protein deficient subribosomal particles but not in intact 30S subunits.     

The reversible dissociation and activity of ribosomal subunits of liver and skeletal muscle from rats

Ribosomal subunits were prepared from rat liver and skeletal muscle after incubation with puromycin and treatment at low concentrations of Mg²⁺. After isolation the resulting subunits could be recombined and the particles effected the synthesis of polyphenylalanine in the presence of polyuridylic acid. Hybrid particles formed from subunits of liver and muscle respectively were also active. The homogeneity of the isolated subunits was checked by polyacrylamide-gel–agarose electrophoresis. The method is shown to be a reliable and comparatively simple way of preparing active ribosomal subunits from skeletal muscle.     

Structure of functional a salina – E Coli hybrid ribosome by electron microscopy

Small 40S Artemia salina and large 50S Escherichia coli ribosomal subunits can be assembled into 73S hybrid monosomes active in model assays for protein synthesis. The reciprocal combination–small 30S E coli and large 60S A salina–fails to form hybrids. The 73S hybrid particles strongly resemble homologous 70S E coli and 80S A salina monosomes. The morphologic differences between the corresponding eukaryotic and prokaryotic ribosomal particles, established by electron microscopy, do not significantly affect the assembly and mutual orientation of 40S A salina and 50S E coli subunits in the heterologous monosome. The fact that the structure of the interface, the supposed site of protein synthesis, is preserved in the active hybrid implies that retention or loss of biologic activity of hybrid ribosomes is determined by the extent of conformational changes in the interface.     

Reversible modification of 50S ribosomal subunits with dimethylmaleic anhydride

Summary The reversible modification of protein amino groups with dimethylmaleic anhydride, which had already been used to dissociate proteins from the 70S ribosomes of Escherichia coli (Pintor-Toro, J. A., et al. (1979) Biochemistry 18, 3219) was applied to the preparation of protein-deficient particles from the 50S subunits. Three successive cycles of treatment with dimethylmaleic anhydride, separation of dissociated proteins and regeneration of the modified amino groups produce partially inactivated ribosomal cores lacking proteins L7, L11 and L12, and having very small amounts of L1, L6 and L10. Incubation of these cores with the corresponding split proteins is accompanied by complete reactivation of the polypeptide synthesizing activity as compared with control 50S subunits.Abbreviation DMMA 2,3-dimethylmaleic anhydride     

Site of synthesis of spinach chloroplast ribosomal proteins and formation of incomplete ribosomal particles in isolated chloroplasts

Chloroplast ribosomal proteins from spinach have been prepared in the presence of a protease inhibitor and some modifications have been introduced to the previous characterization of the 50S subunits (Mache et al., MGG, 177, 333, 1980): 33 ribosomal proteins are detected instead of 34. No change has been observed for the 30S subunits.Using a light-driven system of protein synthesis it is shown that up to ten ribosomal proteins of the 30S and eight proteins of the 50S subunits are made in the chloroplast.Newly synthesized ribosomal subunits have been analysed on CsCl gradients after sedimentation at equilibrium, allowing the separation of fully assembled subunits from incomplete ribosomal particles. Most of the newly made 50S subunits are fully assembled (=1.634). A small amount of incomplete 50S particles (=1.686) is detectable. Newly made 30S subunits (=1.598) and incomplete 30S particles (=1.691) are also observed. The ribosomal proteins of the incomplete 30S have been determined. They contain eight or nine of the 30S-proteins, seven of which are synthesized within the chloroplast. It is suggested that incomplete ribosomal particles resulted from a step in the assembly of ribosomal subunits.     

Spot position of rat liver ribosomal proteins by four different two-dimensional electrophoreses in polyacrylamide gel

Summary Separation of the proteins from rat liver 40S and 60S ribosomal subunits and polysomes was done in four different two-dimensional polyacrylamide gel electrophoresis systems. The first dimension was run at acidic or basic pH, the second dimension either with sodium dodecyl sulphate or at acidic pH in 18% acrylamide. The position of each individual protein of both subunits and polysomes was determined in each system. This identification resulted from a new method avoiding any previous purification of individual proteins. The new proposed uniform nomenclature for mammalian ribosomal proteins (McConkey et al. in press) was used for numbering the proteins in the four systems.     

Study on mammalian ribosomal protein reactivity in situ. III. Effect of trypsin on 40S and 60S subunits.

Rat liver 40S and 60S ribosomal subunits were treated with increasing concentrations of trypsin. The activity of both trypsin-treated subunits, when assayed for polyphenylalanine synthesis, progressively decreased, but the 60S subunits were inactivated at much lower trypsin concentrations than were the 40S ones. The sedimentation coefficients of trypsin-treated subunits were identical to those of control subunits when sucrose gradients containing 0.5 M KCl were used. When the sucrose gradients were prepared with a low salt buffer (80 mM KCl), dimer formation was observed with control subunits, but not with trypsin-treated ones. Two-dimensional gel electrophoresis analysis of the proteins extracted from trypsin-treated subunits revealed that all ribosomal proteins in the subunits were accessible to the enzyme. However, several proteins were more resistant to trypsin in compact subunits than when they were free or in unfolded subunits. Proteins of the 60S subunits were generally digested by lower trypsin concentrations than those of the 40S subunits. From the quantitative measurements of the undigested proteins, a classification of the proteins from both subunits according to their trypsin sensitivity was established. These results were compared with those previously obtained concerning ribosomal protein reactivity to chemical reagents.     

Reconstitution of Bacillus stearothermophilus 50 S ribosomal subunits from purified molecular components.

Bacillus stearothermophilus 50 S ribosomal subunits have been reconstituted from a mixture of purified RNA and protein components. The protein fraction of 50 S subunits was separated into 27 components by a combination of various methods including ion exchange and gel filtration chromatography. The individual proteins showed single bands in a variety of polyacrylamide gel electrophoresis systems, and nearly all showed single spots on two-dimensional polyacrylamide gels. The molecular weights of the proteins were determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. An equimolar mixture of the purified proteins was combined with 23 S RNA and 5 S RNA to reconstitute active 50 S subunits by the procedure of Nomura and Erdmann (Nomura, M., and Erdmann, V. A. (1970) Nature 226, 1214-1218). Reconstituted 52 S subunits containing purified proteins were slightly more active than subunits reconstituted with an unfractionated total protein extract in poly(U)-dependent polyphenylalanine synthesis and showed comparable activity in various assays for ribosomal function. The reconstitution proceeded more rapidly with the mixture of purified proteins than with the total protein extract. Reconstituted 50 S subunits containing purified proteins co-sedimented with native 50 S subunits on sucrose gradients and had a similar protein compsoition. Initial experiments on the roles of the individual proteins in ribosomal structure and function were performed. B. stearothermophilus protein 13 was extracted from 50 S subunits under the same conditions as escherichia coli L7/L12, and the extraction had a similar effect on ribosomal function. When single proteins were omitted from reconstitution mixtures, in most cases the reconstituted 50 S subunits showed decreased activity in polypheylalanine synthesis.     

Identification of proteins crosslinked to RNA in 40S ribosomal subunits of Saccharomyces cerevisiae

RNA-protein crosslinks were introduced into the 40S ribosomal subunits from Saccharomyces cerevisiae by mild UV treatment. Proteins crosslinked to the 18S rRNA molecule were separated from free proteins by repeated extraction of the treated subunits and centrifugation in glycerol gradients. After digestion with RNase to remove the RNA molecules, proteins were radio-labeled with ¹²⁵I and identified by electrophoresis on two-dimensional polyacrylamide gels with carrier total 40S ribosomal proteins and autoradiography. Proteins S2, S7, S13, S14, S17/22/27, and S18 were linked to the 18S rRNA. A shorter period of irradiation resulted in crosslinking of S2 and S17/22/27 only. Several of these proteins were previously demonstrated to be present in ribosomal core particles or early assembled proteins.     

Ribosome crystallization in chicken embryos. I. Isolation, characterization, and in vitro activity of ribosome tetramers

Isolated tetrameric particles (166S) derived from the crystalline lattices known to appear in hypothermic chicken embryos consist of mature 80S ribosomes which contain all species of ribosomal RNA and a complete set of ribosomal proteins. Ribosome tetramers are not a special type of polysomes since in solutions of high ionic strengths (500 mM KCl and 50 nM triethanolamine-HCl buffer) containing 5 mM MgCl₂ they dissociate into 40S and 60S ribosomal subunits, without the need of puromycin, and at a concentration of Mg⁺⁺ higher than 3 mM they are not disassembled by mild RNase treatment. Tetramers spontaneously disassemble into 80S monomers when the Mg⁺⁺ concentration is lowered to 1 mM at relatively low ionic strength. Tetramers failed to couple in vitro puromycin-³H into an acid-insoluble product, indicating the lack of nascent polypeptide chains. Although tetramers have no endogenous messenger RNA activity, they can be programmed in vitro with polyuridylic acid (poly U) to synthesize polyphenylalanine. All ribosomes within a tetramer can accept poly U, without the need of disassembly of the tetramers into monomers or subunits.     

Enzymic iodination of eukaryotic ribosomal subunits. Characterization and analysis by two-dimensional gel electrophoresis

1. Conditions are described for the enzymic iodination of ribosomal subunits from rat liver. The reaction is relatively insensitive to broad changes in the concentration of KCl, allowing subunits to be studied under conditions which minimize their dimerization. 2. Mixtures of extracted ribosomal proteins were iodinated with (125)I, the proteins separated by two-dimensional gel electrophoresis and the radioactivity in each protein was determined. Thus 19 out of 23 of the proteins of the small subunit and 25 out of 33 of the proteins of the large subunit were labelled. Iodination should therefore be a suitable method for studying the topography of the ribosomal proteins of rat liver. 3. When the intact 40S subunit (rather than the extracted mixture of proteins) was iodinated, 18 of the 19 proteins were still labelled. However five of these were labelled less strongly than before. When the intact 60S subunit was iodinated, 17 of the 25 proteins were still labelled, although six of these were labelled less strongly. 4. These results show that in rat liver most of the ribosomal proteins of both subunits are at least partially at the surface of the particles. They are also consistent with the idea that the proportion of the ribosomal proteins in the interior of the particle may be greater for the 60S subunit than for the 40S subunit.     

Assembly analysis of ribosomes from a mutant lacking the assembly-initiator protein L24: lack of L24 induces temperature sensitivity

Summary Previously, we have shown that the ribosomal protein L24 is one of two assembly-initiator proteins. L24 is essential for early steps of the assembly of the 50S ribosomal subunit but it is not involved in both the late assembly and the ribosomal functions. Surprisingly, an E. coli mutant (TA109-130) exists which lacks L24. This apparent paradox is analyzed and resolved in this paper. The phenotypic features of the mutant lacking L24, are a temperature sensitivity (growth severely reduced beyond 34° C), a very low growth rate already at permissive temperatures (at least six-fold slower than wild type) and an underproduction of 50S subunits (molar ratio of 30S to 50S about 1:0.5). The S value of the mutant large subunits is 47S, and they are normally active in poly(Phe) synthesis. The total protein of the mutant large subunits show negligible activity in the total reconstitution assay using the standard two-step procedure. Number analysis of the assembly-initiator proteins revealed that only one initiator protein is effective, as expected. The activity is restored upon addition of wild-type L24. However, when the temperature of the first step is lowered from 44° to 36° C, reconstitution of active particles occurs with a 50% efficiency in the absence of L24. The recovery of activity is accompanied by the appearance of again two initiator proteins, when the mutant TP50 lacking L24 is used in the reconstitution assay at the permissive temperature of 36° C during the first step. These findings indicate that at least another protein or, alternatively, two other proteins take over the function of the assembly initiation at the lower temperature. Although the extent of the formation of active particles becomes independent of L24 below 36° C, the rate of formation is still strongly affected even at permissive temperatures. The presence of L24 reduces the activation energy of the rate-limiting step of the early assembly, i.e., the activation energy of RI ₅₀ ^* (1) formation is 43±4 kcal/mol in the presence and 83±9 kcal in the absence of L24. The results presented provide an explanation of the phenotypic features of the mutant solely due to the assembly effects caused by the lack of L24.