Affinity labeling at the A-site of Escherichia coli ribosomes by a non-hydrolyzable gamma-amide analog of GTP

gamma-Amides of GTP and affinity and photoaffinity derivatives of gamma-amides of GTP: gamma-anilide of GTP, gamma-(4-azido)anilide of GTP, gamma-[N-(4-azidobenzyl)-N-methyl]amide of GTP, gamma[4-N-(2-chloroethyl)-N-methylaminobenzyl]amide of GTP and gamma-[4-N-(2-oxoethyl)-N-methylaminobenzyl]amide of GTP substituted efficiently for GTP in the EF-Tu-dependent transfer of aminoacyl-tRNA to the ribosome but, in contrast to GTP, they were not hydrolyzed in this process. They represent a new class of non-hydrolyzable GTP analogs with preserved gamma-phosphodiester bond. The radioactive analog of GTP: gamma-[4-N-(2-chloroethyl)-N-methylamino[14C]benzyl]amide of GTP was used as an affinity labeling probe for the identification of components of the GTPase center formed in the EF-Tu-dependent transfer reaction of aminoacyl-tRNA to the ribosomal A-site. Within a six-component complex of poly(U)-programmed E. coli ribosomes with elongation factor Tu, Phe-tRNA(Phe) (at the A-site), tRNA(Phe) (at the P-site) and the [14C]GTP analog, mainly the ribosomal 23S RNA and to a lesser extent the ribosomal proteins L17, L21, S16, S21 and the ribosomal 16S RNA were labeled by the reagent. No significant modification of EF-Tu was detected.     

Affinity modification of Escherichia coli ribosomes with photoactivated analogs of mRNA

Oligoribonucleotide derivatives containing the photoactivated arylazidogroup at 5'-end of the oligonucleotide fragment [2-(N-2,4-dinitro-5-azidophenyl) aminoethyl] phosphamides of the oligoribonucleotides, azido-NH (CH2)2NHpN (pN) n-1, were prepared. It was demonstrated that azido-NH(CH2)2NHpA(pA)4 and azido-NH (CH2)2NHpU (pU)3 stimulate the binding of the codonspecific aminoacyl-tRNA with ribosome. After irradiation of the ternary complex ribosome-azido-NH (CH2)2NHpU (pU) n-1 X tRNA with UV-light (lambda greater than 350 nm) covalent binding of the reagent to ribosome occurs. Up to 10% of the reagent, bound in the ternary complex with ribosome, is cross-linked with the ribosomal proteins of 30S and 50S subunits. The ribosomal RNA are not modified by azido-NH (CH2)2NHpU (pU) n-1. The proteins of 30S and 50S subunits, modified with azido-NH (CH2)2NHpU (pU) n-1 with n = 4,7 and 8, were identified. It is shown that proteins of 30S subunits S3, S4, S9, S11, S12, S14, S17, S19, S20 undergo modification. The proteins of 50S subunits L2, L13, L16, L27, L32, L33 are modified. The set of the modified proteins essentially depends on the length of the oligonucleotide part of the reagent and on occupancy of ribosome A-site by a molecule of tRNA.     

Molecular cloning of some components of the translation apparatus of fission yeast Schizosaccharomyces pombe and a list of its cytoplasm ic proteins genes]

Full-length cDNAs of four new genes encoding cytoplasmic ribosomal proteins L14 and L20 (large ribosomal subunit) and S1 and S27 (small ribosomal subunit) were isolated and sequenced during the analysis of the fission yeast Schizosaccharomyces pombe genome. One of the Sz. pombe genes encoding translation elongation factor EF-2 was also cloned and its precise position on chromosome I established. A unified nomenclature was proposed, and the list of all known genetic determinants encoding cytoplasmic ribosomal proteins of Sz. pombe was compiled. By now, 76 genes/cDNAs encoding different ribosomal proteins have been identified in the fission yeast genome. Among them, 35 genes are duplicated and three homologous genes are identified for each of the ribosomal proteins L2, L16, P1, and P2.     

Covalent modifications of ribosomal proteins in growing and aggregation-competent dictyostelium discoideum: phosphorylation and methylation

Phosphorylated and methylated ribosomal proteins were identified in vegetatively growing amoebae and in the starvation-induced, aggregation-competent cells of Dictyostelium discoideum. Of the 15 developmentally regulated cell-specific ribosomal proteins reported earlier, protein A and the acidic proteins A1, A2, and A3 were identified as phosphoproteins, and S5, S6, S10, and D were identified as methylated proteins. Three other ribosomal proteins were phosphorylated and 19 others methylated. S19, L13, A1, A2, and A3 were the predominant phosphoproteins in growing amoebae, whereas S20 and A were the predominant ones in the aggregation-competent cells. Among the methylated proteins, eight (S6, S10, S13, S30, D, L1, L2, and L31) were modified only during growth phase, six (S5, S7, S8, S24, S31, and L36) were altered only during aggregation-competent phase, and nine (S9, S27, S28, S29, S34, L7, L35, L41, and L42) were modified under both phases. Five proteins (S6, S24, L7, L41, and L42) were heavily methylated and of these, the large subunit proteins were present in both growing amoebae and aggregation-competent cells. These findings demonstrate that covalent modification of specific ribosomal proteins is regulated during cell differentiation in D. discoideum.     

A chemical mapping technique for exploring the location of proteins along the ribosome-bound peptide chain

A series of peptidyl-tRNA analogs with varying peptide chain length, BrAc(Gly) _nPhe-tRNA^phe, n = 0 to 16 has been prepared. When bound to Escherichia coli 70 S ribosomes these all react covalently with certain ribosomal proteins. The overwhelming majority of the reaction is with 50 S ribosomal proteins L2, L16, L24, L26–L27 and L32–L33. The extent of reaction with each protein is a function of peptide chain length, making it possible to estimate the relative proximity of these proteins to the 3′-terminus of tRNA bound in the ribosomal P site. This fact, coupled with the findings of others about the length dependence of the binding and peptide donor activity of peptidyl-tRNAs suggests that there is actually a binding site for the growing peptide chain. If this is true, the results presented here permit the ordering of the proteins in this site: L2 is closest to the 3′-end of tRNA followed by L26–L27, L32–L33 and last L24. Evidence is also given that the direction of the growing peptide chain must point away from the A site.     

The complex between ribosomal proteins and aminoacyl-tRNA: the interactions and hydrolytic activities are not confined to the proteins L2 and L16 of Escherichia coli ribosomes

The capacity of some Escherichia coli (E. coli) ribosomal proteins to bind to tRNA and to hydrolyse their aminoacylated derivatives has been analysed. The following results were obtained: (1) The basic proteins L2, L16 and L33 and S20 bound f[3H]Met-tRNA to a similar extent as the total proteins from 30 S (TP30) or 50 S (TP50) when tested by nitrocellulose filtration, in contrast to the more acidic proteins L7/L12 and S8. (2) The proteins of the peptidyltransferase centre, L2 and L16, showed no distinct specificity, binding various charged tRNAs from E. coli and Saccharomyces cerevisiae (S. cerevisiae). (3) A number of isolated ribosomal proteins hydrolysed aminoacyl-tRNA as assessed by trichloroacetic acid precipitation, in contrast to the TP30 and TP50. (4) The loss of radiolabel from Ac[14C]Phe-tRNA and from [14C]tRNA in the presence of these proteins could not be prevented by RNasin, a ribonuclease inhibitor, whereas that mediated by a sample of non-RNase-free bovine serum albumin was inhibited. (5) When double-labelled, Ac[3H]Phe-[14C]tRNA was incubated with L2 both radiolabels were lost, indicating that this potential candidate for a peptidyltransferase enzyme does not specifically cleave the ester bond between the aminoacyl residue and the tRNA.     

Influence of the state of ribosome association on the phosphorylation of ribosomal proteins in isolated ribosome--protein kinase systems from rat cerebral cortex.

Ribosomal protein phosphorylation was investigated in isolated ribosomal subunits and polyribosomes from rat cerebral cortex in the presence of [gamma-32P]ATP and purified catalytic subunit of cyclic AMP-dependent protein kinase from the same tissue. Ribosomal proteins that were most readily phosphorylated in isolated cerebral ribosomal subunits included proteins S2, S3a, S6 and S10 of the 40 S subunit and proteins L6, L13, L14, L19 and L29 of the 60 S subunit. These proteins were also phosphorylated in cellular preparations of rat cerebral cortex in situ or in vitro [Roberts & Ashby (1978) J. Biol. Chem. 253, 288-296; Roberts & Morelos (1979) Biochem. J. 184, 233-244]. However, several additional ribosomal proteins were phosphorylated when isolated 40 S or 60 S subunits were separately incubated in the reconstituted system. Analogous results were obtained with an equimolar mixture of cerebral 40 S and 60 S subunits under comparable conditions. In contrast, extensive exposure of purified cerebral polyribosomes to the catalytic subunit resulted in phosphorylation of only those ribosomal proteins of the 40 S subunit that were most highly labelled after the administration of [32P]Pi in vivo: proteins S2, S6 and S10. Ribosomal proteins of 60 S subunits that were readily phosphorylated in isolated cerebral polyribosomes included proteins L6, L13 and L29. These results indicate that polyribosome formation markedly decreases the number of ribosomal protein sites available for phosphorylation by the catalytic subunit of cyclic AMP-dependent protein kinase. Moreover, the findings suggest that, of the ribosomal protein phosphorylations observed in rat cerebral cortex in vivo, proteins S2, S6, S10, L6, L13 and L29 can be phosphorylated in polyribosomes, whereas proteins S3a, S5, L14 and L19 may become phosphorylated only in free ribosomal subunits.     

Positioning of the mRNA stop signal with respect to polypeptide chain release factors and ribosomal proteins in 80S ribosomes

To study positioning of the mRNA stop signal with respect to polypeptide chain release factors (RFs) and ribosomal components within human 80S ribosomes, photoreactive mRNA analogs were applied. Derivatives of the UUCUAAA heptaribonucleotide containing the UUC codon for Phe and the stop signal UAAA, which bore a perfluoroaryl azido group at either the fourth nucleotide or the 3'-terminal phosphate, were synthesized. The UUC codon was directed to the ribosomal P site by the cognate tRNA(Phe), targeting the UAA stop codon to the A site. Mild UV irradiation of the ternary complexes consisting of the 80S ribosome, the mRNA analog and tRNA resulted in tRNA-dependent crosslinking of the mRNA analogs to the 40S ribosomal proteins and the 18S rRNA. mRNA analogs with the photoreactive group at the fourth uridine (the first base of the stop codon) crosslinked mainly to protein S15 (and much less to S2). For the 3'-modified mRNA analog, the major crosslinking target was protein S2, while protein S15 was much less crosslinked. Crosslinking of eukaryotic (e) RF1 was entirely dependent on the presence of a stop signal in the mRNA analog. eRF3 in the presence of eRF1 did not crosslink, but decreased the yield of eRF1 crosslinking. We conclude that (i) proteins S15 and S2 of the 40S ribosomal subunit are located near the A site-bound codon; (ii) eRF1 can induce spatial rearrangement of the 80S ribosome leading to movement of protein L4 of the 60S ribosomal subunit closer to the codon located at the A site; (iii) within the 80S ribosome, eRF3 in the presence of eRF1 does not contact the stop codon at the A site and is probably located mostly (if not entirely) on the 60S subunit.     

Ribosomal proteins L7 and L8 function in concert with six A3 assembly factors to propagate assembly of domains I and II of 25S rRNA in yeast 60S ribosomal subunits

Ribosome biogenesis is a complex multistep process that involves alternating steps of folding and processing of pre-rRNAs in concert with assembly of ribosomal proteins. Recently, there has been increased interest in the roles of ribosomal proteins in eukaryotic ribosome biogenesis in vivo, focusing primarily on their function in pre-rRNA processing. However, much less is known about participation of ribosomal proteins in the formation and rearrangement of preribosomal particles as they mature to functional subunits. We have studied ribosomal proteins L7 and L8, which are required for the same early steps in pre-rRNA processing during assembly of 60S subunits but are located in different domains within ribosomes. Depletion of either leads to defects in processing of 27SA(3) to 27SB pre-rRNA and turnover of pre-rRNAs destined for large ribosomal subunits. A specific subset of proteins is diminished from these residual assembly intermediates: six assembly factors required for processing of 27SA(3) pre-rRNA and four ribosomal proteins bound to domain I of 25S and 5.8S rRNAs surrounding the polypeptide exit tunnel. In addition, specific sets of ribosomal proteins are affected in each mutant: In the absence of L7, proteins bound to domain II, L6, L14, L20, and L33 are greatly diminished, while proteins L13, L15, and L36 that bind to domain I are affected in the absence of L8. Thus, L7 and L8 might establish RNP structures within assembling ribosomes necessary for the stable association and function of the A(3) assembly factors and for proper assembly of the neighborhoods containing domains I and II.     

Biosynthesis of ribosomal proteins by poly(A)-containing mRNAs from rat liver in a wheat germ cell-free system and sizes of mRNAs coding ribosomal proteins

(1) Poly(A)-containing mRNAs from total polysomal RNA of regenerating rat liver were incubated with [3H]leucine in a wheat germ cell-free system. Ribosomal proteins were purified as described previously [1], and with two-dimensional gel electrophoresis. The proteins on the gel except for less basic protein had appreciable radioactivity, whereas the surrounding areas had very low radioactivity. Acetic acid-soluble proteins labeled in this system were subjected to three-dimensional gel electrophoresis [2]. Except for L1 and L2 proteins, each of the ribosomal proteins, including less basic ones, showed a major radioactive peak coinciding with the protein band on SDS gel. Thus, the wheat germ cell-free system completely translates almost all mRNAs for individual ribosomal proteins. Equimolar amounts of almost all ribosomal proteins were synthesized in the presence of the saturating concentration of mRNAs. (2) Free polysomes from regenerating rat liver were fractionated into three sizes. Each class of polysomes was incubated with [3H]leucine. Ribosomal proteins with molecular weights of 40 000 to 21 000 were mainly synthesized by Fraction B (5-14 monomeric ribosomes), L1 and L2 [2] with 60 000 and 54 000, by Fraction C (greater than 15 monomeric ribosomes) and B, and ribosomal proteins smaller than 20 000 by Fractions A (less than pentamer) and B. (3) mRNAs from rat liver total polysomes were fractionated into seven classes by size and each was translated in the wheat germ extract. Ribosomal proteins with molecular weights of 54 000 to 30 000 were mainly synthesized by mRNAs of 12 to 14.5 S, ribosomal proteins of 35 000 to 22 000 by those of 9.5 to 12 S, ribosomal proteins of 22 000 to 13 000 by those of 7 to 9.5 S, and smaller ribosomal proteins by those smaller than 7 S. These results indicate that individual ribosomal proteins are synthesized by monocistronic mRNAs, the lengths of which are proportional to the molecular weights of the corresponding ribosomal proteins.     

Comparative study between prokaryotes and eukaryotes by chemical iodination of ribosomal proteins.

Escherichia coli and Saccharomyces cerevisiae ribosomal proteins were chemically iodinated with 125I by chloramine T under conditions in which the proteins were denatured. The labelled proteins were subsequently separated by two-dimensional gel electrophoresis with an excess of untreated ribosomal proteins from the same species. The iodination did not change the electrophoretic mobility of the proteins as shown by the pattern of spots in the stained gel slabs and their autoradiography. The 125I radioactivity incorporated in the proteins was estimated by cutting out the gel spots from the two-dimensional electrophoresis gel slabs. The highest content of 125I was found in the ribosomal proteins L2, L11, L13, L20/S12, S4 and S9 from E. coli, and L2/L3, L4/L6/S7, L5, L19/L20, L22/S17, L29/S27, L35/L37 and S14/S15 from S. cerevisiae. Comparisons between the electrophoretic patterns of E. coli and S. cerevisiae ribosomal proteins were carried out by coelectrophoresis of labelled and unlabelled proteins from both species. E. coli ribosomal proteins L5, L11, L20, S2, S3 and S15/S16 were found to overlap with L15, L11/L16, L36/L37, S3, S10 and S33 from S. cerevisiae, respectively. Similar coelectrophoresis of E. coli 125I-labelled proteins with unlabelled rat liver and wheat germ ribosomal proteins showed the former to overlap with proteins L1, L11, L14, L16, L19, L20 and the latter with L2, L5, L6, L15, L17 from E. coli.     

Synthesis and application of two reagents for the introduction of sulfhydryl groups into proteins

Two reagents are described which can be used for the introduction of sulfhydryl groups into proteins. Mercaptopropionylhydrazide modifies specifically periodate-oxidized N termini of proteins, provided that the N-terminal residue is serine or threonine. 3-(Phenyldithio)propionimidate introduces a disulfide bond at lysine residues of proteins. Reduction converts the disulfide into a sulfhydryl group. The imidate compound was found to react with a high specificity with only one lysine residue of ribosomal protein L7/L12.     

An improved method for two-dimensional gel-electrophoresis: Analysis of mutationally altered ribosomal proteins of Escherichia coli

Summary An improved method for the two-dimensional electrophoretic analysis of ribosomal proteins on acrylamide gel slabs has been developed by combining the procedures for the first dimension of Mets and Bogorad (1974) and for the second dimension of Kaltschmidt and Wittmann (1970) and by introducing several modification. Ribosomal proteins of various Escherichia coli mutants have been analyzed by the new method. Advantages are that (1) it requires only small amounts of protein (100–200 g 70S ribosomal proteins), (2) reproducibility is very high, and (3) it makes it easier to identify mutational alterations in proteins S10, L4, L10, and L21 which hardly migrate out of the sample gel with our previous electrophoresis procedure. Furthermore, the new method can be nicely adapted to analysis of the ribosomal proteins from other organisms, such as Bacilli or yeast.     

Study of the surface of Escherichia coli ribosomes and ribosomal particles by the tritium bombardment method

A new technique of atomic tritium bombardment has been used to study the surface topography of Escherichia coli ribosomes and ribosomal subunits. The technique provides for the labeling of proteins exposed on the surface of ribosomal particles, the extent of protein labeling being proportional to the degree of exposure. The following proteins were considerably tritiated in the 70S ribosomes: S1, S4, S7, S9 and/or S11, S12 and/or L20, S13, S18, S20, S21, L1, L5, L6, L7/L12, L10, L11, L16, L17, L24, L26 and L27. A conclusion is drawn that these proteins are exposed on the ribosome surface to an essentially greater extent than the others. Dissociation of 70S ribosomes into the ribosomal subunits by decreasing Mg2+ concentration does not lead to the exposure of additional ribosomal proteins. This implies that there are no proteins on the contacting surfaces of the subunits. However, if a mixture of subunits has been subjected to centrifugation in a low Mg2+ concentration at high concentrations of a monovalent cation, proteins S3, S5, S7, S14, S18 and L16 are more exposed on the surface of the isolated 30S and 50S subunits than in the subunit mixture or in the 70S ribosomes. The exposure of additional proteins is explained by distortion of the native quaternary structure of ribosomal subunits as a result of the separation procedure. Reassociation of isolated subunits at high Mg2+ concentration results in shielding of proteins S3, S5, S7 and S18 and can be explained by reconstitution of the intact 30S subunit structure.     

Reversible modification of Escherichia coli ribosomes with 2,3-dimethylmaleic anhydride. A new method to obtain protein-deficient ribosomal particles.

Treatment of Escherichia coli ribosomes with the protein reagent 2,3-dimethylmaleic anhydride is accompanied by inactivation of polypeptide polymerization and by dissociation of ribosomal proteins. Regeneration of the modified amino groups at pH 6.0 is followed by reactivation and reconstitution of the ribosomes. Prior to regeneration of the amino groups, ribosomal particles and split proteins can be separated by centrifugation, which allows the preparation of new protein-deficient particles. The ribosomal particles obtained by three successive treatments with 2,3-dimethyl-maleic anhydride at a molar ratio of reagent to ribosome equal to 16,000 lack proteins S1, S2, S3, S5, S10, S13, S14, L7, L8, L10, L11, L12, and L20 and have lost part of proteins S4, L1, L6, L16, and L25. This new procedure to obtain protein-deficient ribosomal particles is mild and might be useful to dissociate other protein-containing structures in addition to ribosomes.     

Topography of Escherichia coli ribosomal proteins. The order of reactivity of thiol groups

1. 30S and 50S ribosomal subunits of Escherichia coli were treated with N-[2,3-(14)C]-ethylmaleimide and iodo[(14)C]acetamide. 2. The proteins in the native subunits which reacted with the reagents were S1,double dagger S2, S12, S13, S18, S21, L2, L5, L6, L10, L11, L15, L17, L20, L26+28 and L27. 3. Several proteins, such as S1, S12, S14, S18, L2, L6, L10, L11 and either L26 or 28, had thiol groups in an oxidized form and reacted to a greater extent after reduction with beta-mercaptoethanol or dithiothreitol. 4. The total number of thiol groups in 30S and 50S subunits was determined as 16-17 and 26-27 respectively. The total number of thiol groups in each ribosomal protein was also determined. 5. The reaction of 30S and 50S subunits with iodoacetamide under several different conditions established the order of reactivity of thiol groups.     

Phosphorylation of ribosomal proteins influences subunit association and translation of poly (U) in Streptomyces coelicolor

The occurrence of phosphorylated proteins in ribosomes of Streptomyces coelicolor was investigated. Little is known about which biological functions these posttranslational modifications might fulfil. A protein kinase associated with ribosomes phosphorylated six ribosomal proteins of the small subunit (S3, S4, S12, S13, S14 and S18) and seven ribosomal proteins of the large subunit (L2, L3, L7/L12, L16, L17, L23 and L27). The ribosomal proteins were phosphorylated mainly on the Ser/Thr residues. Phosphorylation of the ribosomal proteins influences ribosomal subunits association. Ribosomes with phosphorylated proteins were used to examine poly (U) translation activity. Phosphorylation induced about 50% decrease in polyphenylalanine synthesis. After preincubation of ribosomes with alkaline phosphatase the activity of ribosomes was greatly restored. Small differences were observed between phosphorylated and unphosphorylated ribosomes in the kinetic parameters of the binding of Phe-tRNA to the A-site of poly (U) programmed ribosomes, suggesting that the initial binding of Phe-tRNA is not significantly affected by phosphorylation. On contrary, the rate of peptidyl transferase was about two-fold lower than that in unphosphorylated ribosomes. The data presented demonstrate that phosphorylation of ribosomal proteins affects critical steps of protein synthesis.     

The phenotypic suppression of a mutation in the gene rplX for ribosomal protein L24 by mutations affecting the lon gene product for protease LA in Escherichia coli K12

Summary A suppressor mutation of a temperature-sensitive mutant of ribosomal protein L24 (rplX19) was mapped close to the lon gene by genetic analysis and was shown to affect protease LA. The degradation and the synthesis rates of individual ribosomal proteins were determined. Proteins L24, L14, L15 and L27 were found to be degraded faster in the original rplX19 mutant than in the rplX19 mutant containing the suppressor mutation. Other ribosomal proteins were either weakly or not at all degraded in both mutants. Temperature-sensitive growth was also suppressed by the overproduction of mutant protein L24 from a plasmid. Our results suggest that (1) either free ribosomal proteins or proteins bound to abortive assembly precursors are highly susceptible to the lon gene product and (2) the mutationally altered protein L24 can still function at the nonpermissive growth temperature of the mutant, if it is present in sufficient amounts.