Copies of protein S6 in Escherichia coli ribosomes

A reinvestigation of the copy number of protein S6 in Escherichia coli ribosomes shows that there is only one copy of S6 in 30 S subunits and in 70 S ribosomes. The previously reported higher value (Subramanian, A. R. (1980) J. Biol. Chem. 255, 6941-6946) is shown to arise from the presence in the usual ribosome preparations of a protein which co-electrophoreses with S6 but does not react with S6 antiserum. This protein is removed when ribosomes are purified by passage through a sucrose gradient.     

Studies on the 3′-terminal sequences of the large ribosomal ribonucleic acid of different eukaryotes and those associated with `hidden'' breaks in heat-dissociable insect 26S ribonucleic acid

The 3'-terminal sequences associated with the large rRNA complex from a range of eukaryotes were determined after pancreatic or T(1)-ribonuclease digestion of RNA terminally labelled with [(3)H]isoniazid. In all higher eukaryotes examined except Drosophila melanogaster, the 3'-terminal sequences Y-G-U(OH) and G-C-U(OH) were demonstrated for the large RNA component(s) and for 6S RNA respectively. The 3'-terminal sequence of Saccharomyces cerevisiae 26S RNA was Y-G-U(OH) and that of 6S RNA Y-A-U-U-U(OH). Three 3'-terminal sequences were found in equimolar amounts in the heat-dissociable 26S rRNA characteristic of insect ribosomes. These were Y-G-U-G-U(OH), Y-C-G-U(OH) and G-C-U(OH) for cultured Antheraea eucalypti cells, Y-G-U(OH), Y-G-U(OH) and G-C-U(OH) for Galleria mellonella larvae and Y-C-G-A(OH), Y-G-U-A(OH) and G-Y-U-G(OH) for Drosophila melanogaster flies. Thus the introduction of the central scission in insect 26S rRNA results in the generation of a unique 3'-terminus and does not arise from random cleavage of the polynucleotide chain.     

Ordered multisite phosphorylation of Xenopus ribosomal protein S6 by S6 kinase II.

Phosphorylated ribosomal proteins were isolated from Xenopus 40 S ribosomal subunits by reversed-phase high performance liquid chromatography (HPLC) to enable direct analysis of the phosphorylation sites in ribosomal protein S6. Xenopus S6 closely resembled mammalian S6 with respect to the following properties: (i) reversed-phase HPLC elution behavior, (ii) amino-terminal sequence (96% identity in the first 37 residues), and (iii) an identical sequence within the region of its phosphorylation sites. Whereas S6 was the only ribosomal protein phosphorylated in vitro by Xenopus S6 kinase II, ribosomes phosphorylated in vivo were found to be associated with an additional phosphoprotein having an amino-terminal sequence identical to that of the ubiquitin carboxyl-terminal extension protein CEP 80. S6 kinase II phosphorylated at least four sites (serines 1-3 and 5) in the sequence Arg-Arg-Leu-Ser(1)-Ser(2)-Leu-Arg-Ala-Ser(3)-Thr-Ser(4)-Lys-Ser(5)-, which correspond to the residues known to be phosphorylated in the carboxyl-terminal region of mammalian S6. The in vivo S6 phosphorylation sites in maturing Xenopus oocytes were shown to be located within the same cluster of serine residues, although individual sites were not identified. Kinetic analysis of S6 kinase II-catalyzed phosphorylation events indicated a simple sequential mechanism of multisite phosphorylation initiating at either serine 2 (preferred) or serine 1, with the rates of phosphorylation of individual sites occurring in the order serine 2 greater than serine 1 greater than serine 3 greater than serine 5.     

RatA (YfjG), an Escherichia coli toxin, inhibits 70S ribosome association to block translation initiation

RatA (YfjG) is a toxin encoded by the ratA-ratB (yfjG-yfjF) operon on the Escherichia coli genome. Induction of RatA led to the inhibition of protein synthesis, while DNA and RNA synthesis was not affected. The stability of mRNAs was also unchanged as judged by in vivo primer extension experiments and by Northern blotting analysis. The ribosome profile of the cells overexpressing RatA showed that 70S ribosomes as well as polysomes significantly decreased with concomitant increase of 50S and 30S subunits. The addition of purified RatA to a cell-free system inhibited the formation of 70S ribosomes even in the presence of 6 mM Mg(2+) . RatA was specifically associated with 50S subunits, indicating that it binds to 50S subunits to block its association with 30S subunits leading to the inhibition of formation of 70S ribosomes. However, RatA did not cause dissociation of 70S ribosomes and its anti-association activity was blocked by paromomycin, an inhibitor for IF3, an essential initiation factor, having 21% sequence homology with RatA. Here we demonstrate that RatA is a new E. coli toxin, which effectively blocks the translation initiation step. We propose that this toxin of previously unknown function be renamed as RatA (Ribosome association toxin A).     

Identification of insulin-induced sites of ribosomal protein S6 phosphorylation in Drosophila melanogaster

Insulin treatment of Drosophila melanogaster Kc 167 cells induces the multiple phosphorylation of a Drosophila ribosomal protein, as judged by its decreased electrophoretic mobility on two-dimensional polyacrylamide gels. The extent to which insulin induces this response is potentiated by cycloheximide and blocked by pretreatment with rapamycin. Isolation and mass spectrometric analysis revealed that the multiply phosphorylated protein was the larger of two Drosophila melanogaster orthologues of mammalian 40S ribosomal protein S6, termed here DS6A. Proteolytic cleavage of DS6A derived from stimulated Kc 167 cells with the endoproteinase Lys-C released a number of peptides, one of which contained all the putative phosphorylation sites. Conversion of phosphoserines to dehydroalanines with Ba(OH)(2) showed that the sites of phosphorylation reside at the carboxy terminus of DS6A. The sites of phosphorylation were identified by Edman degradation after conversion of the phosphoserine residues to S-ethylcysteine as Ser(233), Ser(235), Ser(239), Ser(242), and Ser(245). Finally, phosphopeptide mapping of individual phosphoderivatives, isolated from two-dimensional polyacrylamide gels, indicated that DS6A phosphorylation, in analogy to mammalian S6 phosphorylation, appears to proceed in an ordered fashion. The importance of these observations in cell growth and development is discussed.     

Differences in 23 S rRNA-protein neighbourhood in Escherichia coli 70 S ribosomes and 70 S initiation complex. Probing by bifunctional Pt(II)-containing reagent

rRNA-protein cross-links in free E. coli 35S-labeled 70 S ribosomes and in the initiation complex 35S-labeled 70 S ribosome.AUGU6.fMet-tRNA(fMet) were studied with the aid of a new type of binuclear Pt(II) compound - dichlorotetra-ammine(1,6-hexamethylenediaminediplatinum++ +) dichloride. The use of this reagent allowed us to reveal differences in the rRNA-protein neighbourhood in free 70 S ribosomes and in the initiation complex. Proteins L3, L6, L23 and L25 were shown to cross-link to 23 S rRNA only in the initiation complex, whereas proteins L1, L13, L14, L16, L17, L18, L22, L28 and S1 did so in both free ribosomes and the complex. 16 S rRNA was found to be cross-linked preferentially to a single protein, S1, in both states of the ribosomes.     

The role of multiply phosphorylated S6 in ribosome degradation

Rat liver ribosomes, prepared 1–24 h after intraperitoneal cortisol injection, contain multiple phosphorylated S6 consisting of four distinct derivatives in addition to the original non-phosphorylated S6. 25 h following the hormone injection the extent of S6 phosphorylation, as judged by its electrophoretic pattern in two-dimensional gels, resembles that of untreated rats. Ribosomal subunits with gradually increased degree of S6 phosphorylation, isolated at different time intervals after cortisol injection, exhibit polyphenylalanine polymerization levels inversely proportional to the extent of S6 phosphorylation. In addition, they show an elevated misincorporation of leucine in a poly(U)-programmed in vitro system. The lower amount of polyphenylalanine synthesized by multiple phosphorylated ribosomes in vitro is likely due to an enhanced susceptibility of nascent polypeptide chains synthesized in the in vitro system to proteinases present in the pH 5 and S-100 fractions. Liver polysomes derived from cortisol-treated animals lose their highly phosphorylated derivatives when exposed to S-100 enzymes. The loss can be prevented by concomitant action of proteinase and RNAase inhibitors (phenylmethylsulfonyl fluoride and heparin) but not by an inhibitor of phosphatase (sodium fluoride). In the absence of RNAase and proteinase inhibitors only degradation of old 40 S subunits can be demonstrated. 25 h after the cortisol treatment degradation of liver ribosomes occurs simultaneously with S6 dephosphorylation and is preceded by polysomal breakdown.     

Primary structure of mammalian ribosomal protein S6

Ribosomal protein S6 was isolated from rat liver ribosomes by reversed-phase high-performance liquid chromatography (HPLC) and subjected to cyanogen bromide and proteolytic cleavages. The cleavage fragments were resolved by HPLC and sequenced by automated Edman degradation. The overall amino acid sequence of S6 (249 residues) was determined by alignment of the overlapping sequences of selected cyanogen bromide, chymotryptic, tryptic, and clostripain cleavage fragments. The only protein found to exhibit close homology with the S6 sequence is yeast ribosomal protein S10 (61% sequence identity). Previously, characterized phosphopeptide derivatives of S6 containing phosphorylation sites for adenosine 3',5'-cyclic phosphate dependent and protease-activated protein kinases originate from the carboxy-terminal region of S6 encompassing residues 233-249.     

The role of GTP in transient splitting of 70S ribosomes by RRF (ribosome recycling factor) and EF-G (elongation factor G)

Ribosome recycling factor (RRF), elongation factor G (EF-G) and GTP split 70S ribosomes into subunits. Here, we demonstrated that the splitting was transient and the exhaustion of GTP resulted in re-association of the split subunits into 70S ribosomes unless IF3 (initiation factor 3) was present. However, the splitting was observed with sucrose density gradient centrifugation (SDGC) without IF3 if RRF, EF-G and GTP were present in the SDGC buffer. The splitting of 70S ribosomes causes the decrease of light scattering by ribosomes. Kinetic constants obtained from the light scattering studies are sufficient to account for the splitting of 70S ribosomes by RRF and EF-G/GTP during the lag phase for activation of ribosomes for the log phase. As the amount of 70S ribosomes increased, more RRF, EF-G and GTP were necessary to split 70S ribosomes. In the presence of a physiological amount of polyamines, GTP and factors, even 0.6 μM 70S ribosomes (12 times higher than the 70S ribosomes for routine assay) were split. Spermidine (2 mM) completely inhibited anti-association activity of IF3, and the RRF/EF-G/GTP-dependent splitting of 70S ribosomes.     

S6 phosphorylation is regulated at multiple levels in Xenopus laevis oocytes

It is known that the 40s ribosomal protein S6 undergoes a dramatic increase in its level of phosphorylation during Xenopus oocyte meiotic maturation in response to progesterone stimulation. During prophase arrest, the majority of S6 has 0 moles phosphate per mole protein; this increases to 4-5 moles phosphate per mole protein by the time of germinal vesicle breakdown (GVBD). Our in vitro and in vivo studies indicate that the accumulation of phosphate on S6 is the net result of a 4-5-fold increase in S6 kinase activity and a 30-50% decrease in the rate of dephosphorylation and/or turnover of phosphate groups on S6 in maturing oocytes. In addition, the level of phosphorylation of S6 on 80s monosomes injected into non-hormone-stimulated oocytes was unexpectedly high. This indicates that the S6 kinase/phosphatase ratio in prophase arrested oocytes is higher than anticipated from previous studies. This observation implies that the majority of the oocyte ribosomes may be sequestered from any S6 kinase during meiotic prophase. Furthermore, these observations suggest that a portion of the increased accumulation of phosphate on S6 may be the result of increased accessibility of the ribosomes to S6 kinase during oocyte meiotic maturation.     

A carbon-13 nuclear magnetic resonance study of the 3'-terminus of 16S ribosomal RNA of Escherichia coli specifically labeled with carbon-13 in the methylgroups of the m6(2)Am6(2)A sequence.

30S ribosomes were isolated from a kasugamycin resistant mutant of E. coli that lacks methylgroups on two adjacent adenines in 16S ribosomal RNA. These ribosomes were methylated in vitro with a purified methylating enzyme and 5-S-adenosyl-(13C-methyl)-L-methionine chloride ((13C-methyl)-SAM) as methyldonor. After in situ cleavage of the 16S ribosomal RNA by the bacteriocin cloacin DF13, the 49 nucleotide fragment from the 3'-end of the RNA was isolated. The carbon-13 nuclear magnetic resonance spectra of the fragment at various temperatures were compared with those of 6-N-dimethyladenosine (m6(2)A) and 6-N-dimethyladenylyl-(3' leads to 5')-6-N-dimethyladenosine (m6(2)Am6(2)A). The data show that the two methylated adenines, which are part of a four membered hairpin loop, show a strong tendency to be stacked in analogy to the dinucleotide m6(2)Am6(2).     

The phosphorylation of eukaryotic ribosomal protein S6 by protein kinase C

Purified Ca2+-dependent and phospholipid-dependent protein kinase (protein kinase C) from bovine brain catalysed the phosphorylation of ribosomal protein S6 when incubated with 40S ribosomal subunits from rat liver or from hamster fibroblasts. The phosphorylation was dependent on Ca2+ and phospholipid, and occurred under ionic conditions similar to those which support protein biosynthesis in vitro. Protein kinase C phosphorylated at least three sites on ribosomal protein S6 when incubated with unphosphorylated ribosomes, and increased the extent of phosphorylation of ribosomes previously phosphorylated predominantly on two sites by cyclic-AMP-dependent protein kinase, converting some molecules to the tetraphosphorylated or pentaphosphorylated form. This indicates that protein kinase C can phosphorylate sites on ribosomal protein S6 other than those phosphorylated by the cyclic-AMP-dependent protein kinase, and this conclusion was confirmed by analysis of tryptic phosphopeptides. These results strengthen the possibility that protein kinase C might be involved in catalysing the multisite phosphorylation of ribosomal protein S6 in certain circumstances in vivo.     

Zn(II) binding to Escherichia coli 70S ribosomes

Escherichia coli 70S ribosomes tightly bind 8 equiv of Zn(II), and EXAFS spectra indicate that Zn(II) may be protein-bound. Ribosomes were incubated with EDTA and Zn(II), and after dialysis, the resulting ribosomes bound 5 and 11 equiv of Zn(II), respectively. EXAFS studies show that the additional Zn(II) in the zinc-supplemented ribosomes binds in part to the phosphate backbone of the ribosome. Lastly, in vitro translation studies demonstrate that EDTA-treated ribosomes do not synthesize an active Zn(II)-bound metalloenzyme, while the as-isolated ribosomes do. These studies demonstrate that the majority of intracellular Zn(II) resides in the ribosome.     

Multisite phosphorylation of a synthetic peptide derived from the carboxyl terminus of the ribosomal protein S6

The synthetic peptide AKRRRLSSLRASTSKSESSQK (S6-21) which corresponds to the carboxyl-terminal 21 amino acids of human ribosomal protein S6 was synthesized and tested as a substrate for S6/H4 kinase purified from human placenta. The specific activity of the enzyme with the synthetic peptide and 40 S ribosomes was 45 and 23 nmol/min/mg, respectively. The S6/H4 kinase activity with S6-21 was greater than the enzyme activity with any other substrate tested, including histones, protamine, and casein and several other synthetic peptides. The phosphorylation of the peptide was not inhibited by inhibitors of several other proteins kinases. S6/H4 kinase catalyzed the phosphorylation of three major sites in the synthetic peptide and the 40 S ribosomes. A fourth site in S6-21 was phosphorylated more slowly. The principal phosphorylation sites were serines in the acidic carboxyl-terminal domain of the peptide. A serine (Ser-7 or -8) in the amino-terminal domain was phosphorylated at approximately 25% the rate of the carboxyl-terminal domain serines. The data suggest that multiple S6 kinases may be required to phosphorylate S6 at all five sites which are modified in vivo.     

Immunoprecipitation of 70S, 50S and 30S ribosomes ofEscherichia coli

Antibodies were raised in rabbits against 70S ribosomes, 50S and 30S ribosomal subunits individually. Purified immunoglobulins from the antiserum against each of the above ribosomal entities were tested for their capabilities of precipitating 70S, 50S and 30S ribosomes. The observations revealed the following: (i) The antiserum (IgG) raised against 70S ribosomes precipitates 70S ribosomes completely, while partial precipitation is seen with the subunits, the extent of precipitation being more with the 50S subunits than with 30S subunits; addition of 50S subunits to the 30S subunits facilitates the precipitation of 30S subunits by the antibody against 70S ribosomes. (ii) Antiserum against 50S subunits has the ability to immunoprecipitate both 50S and 70S ribosomes to an equal extent. (iii) Antiserum against 30S subunits also has the property of precipitating both 30S and 70S ribosomes. The differences in the structural organisation of the two subunits may account for the differences in their immunoprecipitability.     

Functional characterization of a maize ribosomal S6 protein kinase (ZmS6K), a plant ortholog of metazoan p70(S6K)

Ribosomal protein S6 (S6rp) is phosphorylated by the p70S6K enzyme in mammals, under mitogen/IGF regulation. This event has been correlated with an increase in 5'TOP mRNA translation. In this research, a maize S6 kinase (ZmS6K) was isolated from maize (Zea mays L.) embryonic axes by human p70S6K antibody immunoprecipitation. This enzyme, a 62 kDa peptide, proved to be specific for S6rp phosphorylation, as revealed by in vivo and in vitro kinase activity using either the 40S ribosomal subunit or the RSK synthetic peptide as the substrates. ZmS6K activation was achieved by phosphorylation on serine/threonine residues. Specific phospho-Threo recognition by the p70S6K antibody directed to target phospho-Threo residue 389 correlated with ZmS6K activation. The ZmS6K protein content remained almost steady during maize seed germination, whereas the ZmS6K activity increased during this process, consistent with Zm6SK phosphorylation. Addition of insulin to germinating maize axes proved to increase ZmS6K activity and the extent of S6rp phosphorylation. These events were blocked by rapamycin, an inhibitor of the insulin signal transduction pathway in mammals, at the TOR (target of rapamycin) enzyme level. We conclude that ZmS6K is a kinase, structurally and functionally ortholog of the mammalian p70S6K, responsible for in vivo S6rp phosphorylation in maize. Its activation is induced by insulin in a TOR-dependent manner by phosphorylation on conserved serine/threonine residues.     

The small subunit of the mammalian mitochondrial ribosome. Identification of the full complement of ribosomal proteins present

Identification of all the protein components of the small subunit (28 S) of the mammalian mitochondrial ribosome has been achieved by carrying out proteolytic digestions of whole 28 S subunits followed by analysis of the resultant peptides by liquid chromatography and tandem mass spectrometry (LC/MS/MS). Peptide sequence information was used to search the human EST data bases and complete coding sequences of the proteins were assembled. The human mitochondrial ribosome has 29 distinct proteins in the small subunit. Fourteen of this group of proteins are homologs of the Escherichia coli 30 S ribosomal proteins S2, S5, S6, S7, S9, S10, S11, S12, S14, S15, S16, S17, S18, and S21. All of these proteins have homologs in Drosophila melanogaster, Caenorhabditis elegans, and Saccharomyces cerevisiae mitochondrial ribosomes. Surprisingly, three variants of ribosomal protein S18 are found in the mammalian and D. melanogaster mitochondrial ribosomes while C. elegans has two S18 homologs. The S18 homologs tend to be more closely related to chloroplast S18s than to prokaryotic S18s. No mitochondrial homologs to prokaryotic ribosomal proteins S1, S3, S4, S8, S13, S19, and S20 could be found in the peptides obtained from the whole 28 S subunit digests or by analysis of the available data bases. The remaining 15 proteins present in mammalian mitochondrial 28 S subunits (MRP-S22 through MRP-S36) are specific to mitochondrial ribosomes. Proteins in this group have no apparent homologs in bacterial, chloroplast, archaebacterial, or cytosolic ribosomes. All but two of these proteins have a clear homolog in D. melanogaster while all but three can be found in the genome of C. elegans. Five of the mitochondrial specific ribosomal proteins have homologs in S. cerevisiae.     

Effect of amino acid at the beta 6 position on surface hydrophobicity, stability, solubility, and the kinetics of polymerization of hemoglobin. Comparisons among Hb A (Glu beta 6), Hb C (Lys beta 6), Hb Machida (Gln beta 6), and Hb S (Val beta 6)

Surface hydrophobicity, stability, solubility, and kinetics of polymerization were studied using hemoglobins with four different amino acids at the beta 6 position: Hb A (Glu beta 6), Hb C (Lys beta 6), Hb Machida (Gln beta 6), and Hb S (Val beta 6). The surface hydrophobicity increased in the order of Hb C, Hb A, Hb Machida, and Hb S, coinciding with the hydrophobicity of the amino acid at the beta 6 position. Solubility of the oxy-form of these hemoglobins decreased in relation to increases in their surface hydrophobicity, suggesting that the solubility is controlled by the strength of hydrophobicity of the amino acid at the beta 6 position. The solubility of the oxy-form of these hemoglobins is always higher than that of the deoxy-form. There is a similar linear relationship between the solubility and surface hydrophobicity among deoxyhemoglobins A, C, and Machida. However, the solubility of deoxy-Hb S deviated significantly from the expected value, indicating that the extremely low solubility of deoxy-Hb S is not directly related to the hydrophobicity of the beta 6 valine. Kinetic studies on the polymerization of deoxy-Hb Machida revealed a distinct delay time prior to polymerization. This confirms our previous hypothesis that beta 6 valine is not responsible for the delay time prior to gelation. The kinetics of the polymerization of 1:1 mixtures of sickle and non-sickle hemoglobins were similar to those of pure Hb S, suggesting that only one of the two beta 6 valines is involved in an intermolecular contact. In mixtures of equal amounts of Hb S and Hb A, Hb C, or Hb Machida, half of the asymmetrical AS, SC, and S-Machida hybrid hemoglobins behaved like Hb S during nucleation, while the other half behaved like the non-sickle hemoglobin.     

Eukaryotic initiation factor 6 mediates a continuum between 60S ribosome biogenesis and translation

Eukaryotic ribosome biogenesis and translation are linked processes that limit the rate of cell growth. Although ribosome biogenesis and translation are mainly controlled by distinct factors, eukaryotic initiation factor 6 (eIF6) has been found to regulate both processes. eIF6 is a necessary protein with a unique anti‐association activity, which prevents the interaction of 40S ribosomal subunits with 60S subunits through its binding to 60S ribosomes. In the nucleolus, eIF6 is a component of the pre‐ribosomal particles and is required for the biogenesis of 60S subunits, whereas in the cytoplasm it mediates translation downstream from growth factors. The translational activity of eIF6 could be due to its anti‐association properties, which are regulated by post‐translational modifications; whether this anti‐association activity is required for the biogenesis and nuclear export of ribosomes is unknown. eIF6 is necessary for tissue‐specific growth and oncogene‐driven transformation, and could be a new rate‐limiting step for the initiation of translation.