Protein synthesis defects in temperature-sensitive mutants of Escherichia coli with altered ribosomal proteins

The ribosomes from four temperature-sensitive mutants of Escherichia coli have been examined for defects in cell-free protein synthesis. The mutants examined had alterations in ribosomal proteins S10, S15, or L22 (two strains). Ribosomes from each mutant showed a reduced activity in the translation of phage MS2 RNA at 44 degrees C and were more rapidly inactivated by heating at this temperature compared to control ribosomes. Ribosomal subunits from three of the mutants demonstrated a partial or complete inability to reassociate at 44 degrees C. 70-S ribosomes from two strains showed a reducton in messenger RNA binding. tRNA binding to the 30 S subunit was reduced in the strains with altered 30-S proteins and binding to the 50 S subunit was affected in the mutants with a change in 50 S protein L22. The relation between ribosomal protein structure and function in protein synthesis in these mutants is discussed.     

Tiamulin resistance mutations in Escherichia coli.

Forty "two-step" and 13 "three-step" tiamulin-resistant mutants of Escherichia coli PR11 were isolated and tested for alteration of ribosomal proteins. Mutants with altered ribosomal proteins S10, S19, L3, and L4 were detected. The S19, L3, and L4 mutants were studied in detail. The L3 and L4 mutations did not segregate from the resistance character in transductional crosses and therefore seem to be responsible for the resistance. Extracts of these mutants also exhibited an increased in vitro resistance to tiamulin in the polyuridylic acid and phage R17 RNA-dependent polypeptide synthesis systems, and it was demonstrated that this was a property of the 50S subunit. In the case of the S19 mutant, genetic analysis showed segregation between resistance and the S19 alteration and therefore indicated that mutation of a protein other than S19 was responsible for the resistance phenotype. The isolated ribosomes of the S19, L3, and L4 mutants bound radioactive tiamulin with a considerably reduced strength when compared with those of wild-type cells. The association constants were lower by factors ranging from approximately 20 to 200. When heated in the presence of ammonium chloride, these ribosomes partially regained their avidity for tiamulin.     

Binding of erythromycin to the 50S ribosomal subunit is affected by alterations in the 30S ribosomal subunit

Summary Expression of resistance to erythromycin in Escherichia coli, caused by an altered L4 protein in the 50S ribosomal subunit, can be masked when two additional ribosomal mutations affecting the 30S proteins S5 and S12 are introduced into the strain (Saltzman, Brown, and Apirion, 1974). Ribosomes from such strains bind erythromycin to the same extent as ribosomes from erythromycin sensitive parental strains (Apirion and Saltzman, 1974).Among mutants isolated for the reappearance of erythromycin resistance, kasugamycin resistant mutants were found. One such mutant was analysed and found to be due to undermethylation of the rRNA. The ribosomes of this strain do not bind erythromycin, thus there is a complete correlation between phenotype of cells with respect to erythromycin resistance and binding of erythromycin to ribosomes.Furthermore, by separating the ribosomal subunits we showed that 50S ribosomes bind or do not bind erythromycin according to their L4 protein; 50S with normal L4 bind and 50S with altered L4 do not bind erythromycin. However, the 30s ribosomes with altered S5 and S12 can restore binding in resistant 50S ribosomes while the 30S ribosomes in which the rRNA also became undermethylated did not allow erythromycin binding to occur.Thus, evidence for an intimate functional relationship between 30S and 50S ribosomal elements in the function of the ribosome could be demonstrated. These functional interrelationships concerns four ribosomal components, two proteins from the 30S ribosomal subunit, S5, and S12, one protein from the 50S subunit L4, and 16S rRNA.     

The flexible N-terminal domain of ribosomal protein L11 from Escherichia coli is necessary for the activation of stringent factor

The stringent response is activated by the binding of stringent factor to stalled ribosomes that have an unacylated tRNA in the ribosomal aminoacyl-site. Ribosomes lacking ribosomal protein L11 are deficient in stimulating stringent factor. L11 consists of a dynamic N-terminal domain (amino acid residues 1-72) connected to an RNA-binding C-terminal domain (amino acid residues 76-142) by a flexible linker (amino acid residues 73-75). In vivo data show that mutation of proline 22 in the N-terminal domain is important for initiation of the stringent response. Here, six different L11 point and deletion-mutants have been constructed to determine which regions of L11 are necessary for the activation of stringent factor. The different mutants were reconstituted with programmed 70 S(DeltaL11) ribosomes and tested for their ability to stimulate stringent factor in a sensitive in vitro pppGpp synthesis assay. It was found that a single-site mutation at proline 74 in the linker region between the two domains did not affect the stimulatory activity of the reconstituted ribosomes, whereas the single-site mutation at proline 22 reduced the activity of SF to 33% compared to ribosomes reconstituted with wild-type L11. Removal of the entire linker between the N and C-terminal domains or removal of the entire proline-rich helix beginning at proline 22 in L11 resulted in an L11 protein, which was unable to stimulate stringent factor in the ribosome-dependent assay. Surprisingly, the N-terminal domain of L11 on its own activated stringent factor in a ribosome-dependent manner without restoring the L11 footprint in 23 S rRNA in the 50 S subunit. This suggests that the N-terminal domain can activate stringent factor in trans. It is also shown that this activation is dependent on unacylated tRNA.     

Isolation and characterization of temperature-sensitive mutants of Escherichia coli with altered ribosomal proteins

Summary The ribosomal proteins of temperature-sensitive mutants of Escherichia coli isolated independently after mutagenesis with nitrosoguanidine were analyzed by two-dimensional gel electrophoresis. Out of 400 mutants analyzed, 60 mutants (15%) showed alterations in a total of 22 different ribosomal proteins. The proteins altered in these mutants are S2, S4, S6, S7, S8, S10, S15, S16, S18, L1, L3, L6, L10, L11, L14, L15, L17, L18, L19, L22, L23 and L24. A large number of them (25 mutants) have mutations in protein S4 of the small subunit, while four mutants showed alterations in protein L6 of the large subunit. The importance of these mutants for structural and functional analyses of ribosomes is discussed.     

Identification of a region of Escherichia coli ribosomal protein L2 required for the assembly of L16 into the 50 S ribosomal subunit

In vitro mutagenesis of rplB was used to generate changes in a conserved region of Escherichia coli ribosomal protein L2 between Gly221 and His231. Mutants were selected by temperature sensitivity using an inducible expression system. A mutant L2 protein with the deletion of Thr222 to Asp228 was readily distinguishable from wild-type L2 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and ribosomes from the strain overexpressing this mutant protein were characterized by sucrose density gradient centrifugation and protein composition. In addition to 30 S and 50 S ribosomal subunits, cell lysates contained a new component that sedimented at 40 S in 1 mM Mg2+ and at 48 S in 10 mM Mg2+. These particles contained mutant L2 protein exclusively, completely lacked L16, and had reduced amounts of L28, L33, and L34. They did not reassociate with 30 S ribosomal subunits and were inactive in polyphenylalanine synthesis. Other mutants in the same conserved region, including the substitution of His229 by Gln229, produced similar aberrant 50 S particles that sedimented at 40 S and failed to associate with 30 S subunits.     

Use of a hapten specific anti-dansyl antibody for the localization of ribosomal proteins by immuno electron microscopy

The fluorescent reagent dansyl chloride has been used as an immunological marker for the electron microscopic localization of ribosomal proteins on the surface of 50S ribosomal subunits. The proteins BstL1 from Bacillus stearothermophilus and EcoL1 from Escherichia coli were dansylated to various degrees and reconstituted into the L1-deficient E. coli 50S subunits from mutant MV17-10. Using antibodies specific to dansyl chloride, both proteins were mapped at the lateral protuberance near the peptidyl transferase center.     

Efficient reconstitution of functional Escherichia coli 30S ribosomal subunits from a complete set of recombinant small subunit ribosomal proteins.

Previous studies have shown that the 30S ribosomal subunit of Escherichia coli can be reconstituted in vitro from individually purified ribosomal proteins and 16S ribosomal RNA, which were isolated from natural 30S subunits. We have developed a 30S subunit reconstitution system that uses only recombinant ribosomal protein components. The genes encoding E. coli ribosomal proteins S2-S21 were cloned, and all twenty of the individual proteins were overexpressed and purified. Reconstitution, following standard procedures, using the complete set of recombinant proteins and purified 16S ribosomal RNA is highly inefficient. Efficient reconstitution of 30S subunits using these components requires sequential addition of proteins, following either the 30S subunit assembly map (Mizushima & Nomura, 1970, Nature 226:1214-1218; Held et al., 1974, J Biol Chem 249:3103-3111) or following the order of protein assembly predicted from in vitro assembly kinetics (Powers et al., 1993, J MoI Biol 232:362-374). In the first procedure, the proteins were divided into three groups, Group I (S4, S7, S8, S15, S17, and S20), Group II (S5, S6, S9, Sll, S12, S13, S16, S18, and S19), and Group III (S2, S3, S10, S14, and S21), which were sequentially added to 16S rRNA with a 20 min incubation at 42 degrees C following the addition of each group. In the second procedure, the proteins were divided into Group I (S4, S6, S11, S15, S16, S17, S18, and S20), Group II (S7, S8, S9, S13, and S19), Group II' (S5 and S12) and Group III (S2, S3, S10, S14, and S21). Similarly efficient reconstitution is observed whether the proteins are grouped according to the assembly map or according to the results of in vitro 30S subunit assembly kinetics. Although reconstitution of 30S subunits using the recombinant proteins is slightly less efficient than reconstitution using a mixture of total proteins isolated from 30S subunits, it is much more efficient than reconstitution using proteins that were individually isolated from ribosomes. Particles reconstituted from the recombinant proteins sediment at 30S in sucrose gradients, bind tRNA in a template-dependent manner, and associate with 50S subunits to form 70S ribosomes that are active in poly(U)-directed polyphenylalanine synthesis. Both the protein composition and the dimethyl sulfate modification pattern of 16S ribosomal RNA are similar for 30S subunits reconstituted with either recombinant proteins or proteins isolated as a mixture from ribosomal subunits as well as for natural 30S subunits.     

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.     

Multiple defects in translation associated with altered ribosomal protein L4

The ribosomal proteins L4 and L22 form part of the peptide exit tunnel in the large ribosomal subunit. In Escherichia coli, alterations in either of these proteins can confer resistance to the macrolide antibiotic, erythromycin. The structures of the 30S as well as the 50S subunits from each antibiotic resistant mutant differ from wild type in distinct ways and L4 mutant ribosomes have decreased peptide bond-forming activity. Our analyses of the decoding properties of both mutants show that ribosomes carrying the altered L4 protein support increased levels of frameshifting, missense decoding and readthrough of stop codons during the elongation phase of protein synthesis and stimulate utilization of non-AUG codons and mutant initiator tRNAs at initiation. L4 mutant ribosomes are also altered in their interactions with a range of 30S-targeted antibiotics. In contrast, the L22 mutant is relatively unaffected in both decoding activities and antibiotic interactions. These results suggest that mutations in the large subunit protein L4 not only alter the structure of the 50S subunit, but upon subunit association, also affect the structure and function of the 30S subunit.     

The contribution of the zinc-finger motif to the function of Thermus thermophilus ribosomal protein S14

In the crystal structure of the 30S ribosomal subunit from Thermus thermophilus, cysteine 24 of ribosomal protein S14 (TthS14) occupies the first position in a CXXC-X12-CXXC motif that coordinates a zinc ion. The structural and functional importance of cysteine 24, which is widely conserved from bacteria to humans, was studied by its replacement with serine and by incorporating the resulting mutant into Escherichia coli ribosomes. The capability of such modified ribosomes in binding tRNA at the P and A-sites was equal to that obtained with ribosomes incorporating wild-type TthS14. In fact, both chimeric ribosomal species exhibited 20% lower tRNA affinity compared with native E. coli ribosomes. In addition, replacement of the native E. coli S14 by wild-type, and particularly by mutant TthS14, resulted in reduced capability of the 30S subunit for association with 50S subunits. Nevertheless, ribosomes from transformed cells sedimented normally and had a full complement of proteins. Unexpectedly, the peptidyl transferase activity in the chimeric ribosomes bearing mutant TthS14 was much lower than that measured in ribosomes incorporating wild-type TthS14. The catalytic center of the ribosome is located within the 50S subunit and, therefore, it is unlikely to be directly affected by changes in the structure of S14. More probably, the perturbing effects of S14 mutation on the catalytic center seem to be propagated by adjacent intersubunit bridges or the P-site tRNA molecule, resulting in weak donor-substrate reactivity. This hypothesis was verified by molecular dynamics simulation analysis.     

The localization of protein L19 on the surface of 50 S subunits of Escherichia coli aided by the use of mutants lacking protein L19

Three independently isolated mutants of Escherichia coli which apparently lacked protein L19 on their ribosomes, as judged by two-dimensional gels, were analyzed by a range of immunological tests to determine if the protein was indeed lacking. In two of the three, all the tests indicated that protein L19 was absent from both ribosome and supernatant. In the third, a drastically altered form of protein L19 was present on the ribosome. Electron micrographs of ribosomes obtained from the mutants were indistinguishable from those of wild type strains. The location of ribosomal protein L19 on the surface of the large subunit was determined. It was situated at the base of the 50 S particle facing the small subunit, on the side where the rod like appendage originates.     

Mapping proteins of the 50S subunit from Escherichia coli ribosomes

Mapping of protein positions in the ribosomal subunits was first achieved for the 30S subunit by means of neutron scattering about 15 years ago. Since the 50S subunit is almost twice as large as the 30S subunit and consists of more proteins, it was difficult to apply classical contrast variation techniques for the localisation of the proteins. Polarisation dependent neutron scattering (spin-contrast variation) helped to overcome this restriction. Here a map of 14 proteins within the 50S subunit from Escherichia coli ribosomes is presented including the proteins L17 and L20 that are not present in archeal ribosomes. The results are compared with the recent crystallographic map of the 50S subunit from the archea Haloarcula marismortui.     

Interaction of the cytoplasmic membrane and ribosomes in Escherichia coli; altered ribosomal proteins in sucrose-dependent spectinomycin-resistant mutants.

Alterations in the ribosomes of sucrose-dependent spectinomycin-resistant (Sucd-Spcr) mutants of Escherichia coli were studied. Subunit exchange experiments showed that 30S subunits were responsible for the resistance of ribosomes to spectinomycin in all Sucd-Spcr mutants tested. Proteins of 30S ribosomes were analyzed by carboxymethyl cellulose column chromatography based on their elution positions. Mutants YM22 and YM93 had an altered 30S ribosomal protein component, S5, and mutant YM50 had an altered protein, S4. Although a shift of elution position was not detected for all the 30S ribosomal proteins from mutant YM101, the amount of protein S3 was appreciably lowered in the isolated 30S subunits. A partial reconstitution experiment with protein S3 prepared from both the wild-type strain and YM101 revealed that the mutant had altered protein S3 which is responsible for the spectinomycin resistance. These alterations in 30S subunits are discussed in relation to the interaction between ribosomes and the cytoplasmic membrane.     

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.     

Ribosomal protein L7/L12 cross-links to proteins in separate regions of the 50 S ribosomal subunit of Escherichia coli

The 50 S ribosomal subunits from Escherichia coli were modified by reaction with 2-iminothiolane under conditions in which 65 sulfhydryl groups, about 2/protein, were added per subunit. Earlier work showed that protein L7/L12 was modified more extensively than the average but that nearly all 50 S proteins contained sulfhydryl groups. Mild oxidation led to the formation of disulfide protein-protein cross-links. These were fractionated by urea gel electrophoresis and then analyzed by diagonal gel electrophoresis. Cross-linked complexes containing two, three, and possibly four copies of L7/L12 were evident. Cross-links between L7/L12 and other ribosomal proteins were also formed. These proteins were identified as L5, L6, L10, L11, and, in lower yield, L9, L14, and L17. The yields of cross-links to L5, L6, L10, and L11 were comparable to the most abundant cross-links formed. Similar experiments were performed with 70 S ribosomes. Protein L7/L12 in 70 S ribosomes was cross-linked to proteins L6, L10, and L11. The strong L7/L12-L5 cross-link found in 50 S subunits was absent in 70 S ribosomes. No cross-links between 30 S proteins and L7/L12 were observed.     

Reconstitution of active 50 S ribosomal subunits from Bacillus licheniformis and Bacillus subtilis.

Active 50 S ribosomal subunits from Bacillus licheniformis and Bacillus subtilis can be reconstituted in vitro from dissociated RNA and proteins. The reconstituted 50 S sub-units are indistinguishable from native 50 S subunits in sedimentation on sucrose gradients and in protein composition. The procedure used is similar to that developed for reconstitution of Bacillus stearothermophilus 50 S subunits, though the optimal conditions are somewhat different. Hybrid ribosomes can be reconstituted with 23 S RNA and proteins from different sources (B. stearothermophilus and B. licheniformis or B. subtilis). The thermal stability of these ribosomes depends on the source of the proteins, and not on the source of 23 S RNA.     

Surface topography of the Bacillus stearothermophilus ribosome.

Summary The surface topography of the intact 70S ribosome and free 30S and 50S subunits from Bacillus stearothermophilus strain 2184 was investigated by lactoperoxidase-catalyzed iodination. Two-dimensional polyacrylamide gel electrophoresis was employed to separate ribosomal proteins for analysis of their reactivity. Free 50S subunits incorporated about 18% more ¹²⁵I than did 50S subunits derived from 70S ribosomes, whereas free 30S subunits and 30S subunits derived from 70S ribosomes incorporated similar amounts of ¹²⁵I. Iodinated 70S ribosomes and subunits retained 62–78% of the protein synthesis activity of untreated particles and sedimentation profiles showed no gross conformational changes due to iodination. The proteins most reactive to enzymatic iodination were S4, S7, S10 and Sa of the small subunit and L2, L4, L5/9, L6 and L36 of the large subunit. Proteins S2, S3, S7, S13, Sa, L5/9, L10, L11 and L24/25 were labeled substantially more in the free subunits than in the 70S ribosome. Other proteins, including S5, S9, S12, S15/16, S18 and L36 were more extensively iodinated in the 70S ribosome than in the free subunits. The locations of tyrosine residues in some homologus ribosomal proteins from B. stearothermophilus and E. coli are compared.     

Unassembled polypeptides of the plastidic ribosomes in heat-treated 70S-ribosome-deficient rye leaves

The polypeptides of the subunits of 70S ribosomes isolated from rye (Secale cereale L.) leaf chloroplasts were analyzed by two-dimensional polyacrylamide gel electrophoresis. The 50S subunit contained approx. 33 polypeptides in the range of relative molecular mass (M_r) 13000–36000, the 30S subunit contained approx. 25 polypeptides in the range of M_r 13000–40500. Antisera raised against the individual isolated ribosomal subunits detected approx. 17 polypeptides of the 50S and 10 polypeptides of the 30S subunit in the immunoblotting assay. By immunoblotting with these antisera the major antigenic ribosomal polypeptides (r-proteins) of the chloroplasts were clearly and specifically visualized also in separations of leaf extracts or soluble chloroplast supernatants. In extracts from rye leaves grown at 32° C, a temperature which is non-permissive for 70S-ribosome formation, or in supernatants from ribosome-deficient isolated plastids, six plastidic r-proteins were visualized by immunoblotting with the anti-50S-serum and two to four plastidic r-proteins were detected by immunoblotting with the anti-30S-serum, while other r-proteins that reacted with our antisera were missing. Those plastidic r-proteins that were present in 70S-ribosome-deficient leaves must represent individual unassembled ribosomal polypeptides that were synthesized on cytoplasmic 80S ribosomes. For the biogenesis of chloroplast ribosomes the mechanism of coordinate regulation appear to be less strict than those known for the biogenesis of bacterial ribosomes, thus allowing a marked accumulation of several unassembled ribosomal polypeptides of cytoplasmic origin.Abbreviations L polypeptide of large ribosomal subunit - M_r relative molecular mass - r-protein ribosomal polypeptide - S polypeptide of small ribosomal subunit - SDS sodium dodecyl sulfate     

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.