Immunological studies of Escherichia coli mutants lacking one or two ribosomal proteins

Summary A battery of immunological tests were used to investigate mutants which had been determined as lacking one or two ribosomal proteins on the basis of two-dimensional polyacrylamide gels. Proteins which were confirmed as missing from the ribosome in one or more mutants were large subunit proteins L1, L15, L19, L24, L27, L28, L30 and L33 and small subunit proteins S1, S9, S17 and S20. Cross-reacting material (CRM) was also absent from the post-ribosomal supernatant except in the case of protein S1. Since mutants lacking protein L11 have been previously described, any one of 13 of the 52 ribosomal proteins can be missing. None of these 13 proteins, except S1, can therefore have an indispensable role in ribosome function or assembly. In several mutants in which a protein was not missing but altered, it was present as several moieties of differing charge and size.     

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.     

Mitochondrial ribosome assembly in Neurospora crassa: mutants with defects in mitochondrial ribosome assembly.

Summary We have examined mitochondrial (mt) ribosome assembly and-function in five nuclear and six extranuclear mutants of Neurospora crassa which had previously been characterized as deficient in cytochromes b and aa ₃. All six extranuclear mutants showed phenotypes similar to that previously described for the extranuclear [poky] mutant: small subunit-deficient with 19 S rRNA rapidly degraded. The nuclear mutants have the following phenotypes: 297-24 is mt small subunit deficient with 19 S RNA rapidly degraded. 289-56 is mt small subunit deficient but contains normal ratios of 19 S to 25 S RNA in whole mitochondria. 289-67 and 299-9 show defects in the processing of 25 S RNA leading to accumulation of a large precursor RNA. 289-4 is deficient in large subunits although a substantial, but less than normal, amount of 25 S RNA is present in the mitochondria.The present work provides new insight into the phenotypes of mt small subunit-deficient mutants. Previous studies using chloramphenicol suggest that some defects in the assembly of mt small subunits may arise secondarily as a result of inhibition of mt protein synthesis (LaPolla and Lambowitz, 1977; Lambowitz et al., 1979). Three mutants (289-56, 289-67 and 299-9) appear to show such defects. These strains contain incomplete mt small subunits which sediment more slowly than normal and are deficient in at least two proteins, S-5 and S-9. Correlation of mutant phenotypes with rates of mt protein synthesis in the different strains suggests that mt protein synthesis must be decreased to less than one half of the wild-type rate before secondary defects in mt small subunit assembly are observed. This threshold value is much lower than that which leads to gross deficiencies of cytochromes b and aa ₃. Although several mutants have phenotypes suggestive of alterations in mt ribosomal proteins, no such alterations could be identified by two dimensional gel electrophoresis.     

Further temperature-sensitive mutants of Escherichia coli with altered ribosomal proteins.

Summary Various alterations in ribosomal proteins were detected in forty-one mutants ofE. coli isolated as temperature-sensitive mutants. Out of these, six are new classes of mutants harboring mutations in proteins S3, L5, L7 (L12), L29, L30 and L33. One of them apparently lacks protein L7 of the large subunit. These mutants together with those reported previously (Isono et al., 1976) total one hundred and one ribosomal mutants in thirty different proteins.     

Yeast ribosomal protein L24 affects the kinetics of protein synthesis and ribosomal protein L39 improves translational accuracy, while mutants lacking both remain viable

Four mutant strains from Saccharomyces cerevisiae were used to study ribosome structure and function. They included a strain carrying deletions of the two genes encoding ribosomal protein L24, a strain carrying a mutation spb2 in the gene for ribosomal protein L39, a strain carrying a deletion of the gene for L39, and a mutant lacking both L24 and L39. The mutant lacking only L24 showed just 25% of the normal polyphenylalanine-synthesizing activity followed by a decrease in P-site binding, suggesting the possibility that protein L24 is involved in the kinetics of translation. Each of the two L39 mutants displayed a 4-fold increase of their error frequencies over the wild type. This was accompanied by a substantial increase in A-site binding, typical of error-prone mutants. The absence of L39 also increased sensitivity to paromomycin, decreased the ribosomal subunit ratio, and caused a cold-sensitive phenotype. Mutant cells lacking both ribosomal proteins remained viable. Their ribosomes showed reduced initial rates caused by the absence of L24 but a normal extent of polyphenylalanine synthesis and a substantial in vivo reduction in the amount of 80S ribosomes compared to wild type. Moreover, this mutant displayed decreased translational accuracy, hypersensitivity to the antibiotic paromomycin, and a cold-sensitive phenotype, all caused mainly by the deletion of L39. Protein L39 is the first protein of the 60S ribosomal subunit implicated in translational accuracy.     

A pair of Bacillus subtilis ribosomal protein genes mapping outside the principal ribosomal protein cluster.

Before now, the only ribosomal protein gene loci to be identified in Bacillus subtilis map within the principal ribosomal protein gene cluster at about 10 degrees on the linkage map. Using mutants with alterations in large subunit ribosomal proteins L20 or L24, I mapped the corresponding genes near leuA at approximately 240 degrees. The data were fully consistent with the fact that the genes for the two proteins were close together but not near any other ribosomal protein genes, as is also the case with the genes for the corresponding proteins of Escherichia coli.     

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.     

Selection in Bacillus subtilis giving rise to strains with mutational alterations in a variety of ribosomal proteins

Summary To facilitate mapping of ribosomal protein genes in Bacillus subtilis, a selection was devised which gave rise to strains with alterations in any one of a variety or ribosomal proteins. Alterations in eighteen ribosomal proteins were identified when eighty mutants were analysed. In addition, one strain showed a major assembly defect in the large ribosomal subunit resulting in the presence of a particle sedimenting at about 40S. Eighteen large subunit proteins were present on this particle in normal amounts, while twelve proteins were much reduced in amount or undetectible.     

A nuclear mutation conferring thiostrepton resistance in Chlamydomonas reinhardtii affects a chloroplast ribosomal protein related to Escherichia coli ribosomal protein L11

We have isolated a nuclear mutant (tsp-1) of Chlamydomonas reinhardtii which is resistant to thiostrepton, an antibiotic that blocks bacterial protein synthesis. The tsp-1 mutant grows slowly in the presence or absence of thiostrepton, and its chloroplast ribosomes, although resistant to the drug, are less active than chloroplast ribosomes from the wild type. Chloroplast ribosomal protein L-23 was not detected on stained gels or immunoblots of total large subunit proteins from tsp-1 probed with antibody to the wild-type L-23 protein from C. reinhardtii. Immunoprecipitation of proteins from pulse-labeled cells showed that tsp-1 synthesizes small amounts of L-23 and that the mutant protein is stable during a 90 min chase. Therefore the tsp-1 phenotype is best explained by assuming that the mutant protein synthesized is unable to assemble into the large subunit of the chloroplast ribosome and hence is degraded over time. L-23 antibodies cross-react with Escherichia coli r-protein L11, which is known to be a component of the GTPase center of the 50S ribosomal subunit. Thiostrepton-resistant mutants of Bacillus megaterium and B. subtilis lack L11, show reduced ribosome activity, and have slow growth rates. Similarities between the thiostreptonresistant mutants of bacteria and C. reinhardtii and the immunological relatedness of Chlamydomonas L-23 to E. coli L11 suggest that L-23 is functionally homologous to the bacterial r-protein L11.     

Cold-sensitive growth of a mutant of Escherichia coli with an altered ribosomal protein S8: analysis of revertants.

Summary 26 cold-resistant revertants of a cold-sensitiveEscherichia coli mutant with an altered ribosomal protein S8 were analyzed for their ribosomal protein pattern by two-dimensional polyacrylamide gel electrophoresis. It was found that 16 of them had acquired the apparent wild-type form of protein S8, one exhibits a more strongly altered S8 than the original mutant and two revertants regained the wild-type form of S8 and, in addition, possess alterations in protein L30. The ribosomes of the residual revertants showed no detectable difference from those of the parental S8 mutant.The mutation leading to the more strongly altered S8 was genetically not separable from the primary S8 mutation; this indicates that both mutations are very close to each other or at the same site. The structural gene for ribosomal protein L30 was mapped relative to two other ribosomal protein genes (for proteins S5 and S8) by the aid of one of the L30 mutants: The relative order obtained is:aroE....rpmD(L30)....rpsE(S5)....rpsH(S8)....THe L30 mutation impairs growth and ribosomal assembly at 20°C and is therefore the first example of a mutant with a defined 50S alteration that has (partial) cold-sensitive ribosome assembly. A double mutant was constructed which possesses both the S8 and the L30 mutations. It was found that the L30 mutation had a slight antagonistic effect on the growth inhibition caused by the S8 mutation. Thus the L30 mutants might have possibly arisen from the original S8 mutants first as S8/L30 double mutants which was followed by the loss of the original S8 lesion.     

Yeast ribosomal protein deletion mutants possess altered peptidyltransferase activity and different sensitivity to cycloheximide.

The major function of the ribosome is its ability to catalyze formation of peptide bonds, and it is carried out by the ribosomal peptidyltransferase. Recent evidence suggests that the catalyst of peptide bond formation is the 23S rRNA of the large ribosomal subunit. We have developed an in vitro system for the determination of peptidyltransferase activity in yeast ribosomes. Using this system, a kinetic analysis of a model reaction for peptidyltransferase is described with Ac-Phe-tRNA as the peptidyl donor and puromycin as the acceptor. The Ac-Phe-tRNA-poly(U)-80S ribosome complex (complex C) was isolated and then reacted with excess puromycin to give Ac-Phe-puromycin. This reaction (puromycin reaction) followed first-order kinetics. At saturating concentrations of puromycin, the first-order rate constant (k(3)) is identical to the catalytic rate constant (k(cat)) of peptidyltransferase. This k(cat) from wild-type yeast strains was equal to 2.18 min(-1) at 30 degrees C. We now present for the first time kinetic evidence that yeast ribosomes lacking a particular protein of the 60S subunit may possess significantly altered peptide bond-forming ability. The k(cat) of peptidyltransferase from mutants lacking ribosomal protein L24 was decreased 3-fold to 0.69 min(-1), whereas the k(cat) from mutants lacking L39 was slightly increased to 3.05 min(-1) and that from mutants lacking both proteins was 1.07 min(-1). These results suggest that the presence of ribosomal proteins L24 and, to a lesser extent, L39 is required for exhibition of the normal catalytic activity of the ribosome. Finally, the L24 or L39 mutants did not affect the rate or the extent of the translocation phase of protein synthesis. However, the absence of L24 caused increased resistance to cycloheximide, a translocation inhibitor. Translocation of Ac-Phe-tRNA from the A- to P-site was inhibited by 50% at 1.4 microM cycloheximide for the L24 mutant compared to 0.7 microM for the wild type.     

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.     

Erythromycin inhibits the assembly of the large ribosomal subunit in growing Escherichia coli cells

Erythromycin and other macrolide antibiotics have been examined for their effects on ribosome assembly in growing Escherichia coli cells. Formation of the 50S ribosomal subunit was specifically inhibited by erythromycin and azithromycin. Other related compounds tested, including oleandomycin, clarithromycin, spiramycin, and virginiamycin M₁, did not influence assembly. Erythromycin did not promote the breakdown of ribosomes formed in the absence of the drug. Two erythromycin-resistant mutants with alterations in ribosomal proteins L4 and L22 were also examined for an effect on assembly. Subunit assembly was affected in the mutant containing the L22 alteration only at erythromycin concentrations fourfold greater than those needed to stop assembly in wild-type cells. Ribosomal subunit assembly was only marginally affected at the highest drug concentration tested in the cells that contained the altered L4 protein. These novel results indicate that erythromycin has two effects on translation, preventing elongation of the polypeptide chain and also inhibiting the formation of the large ribosomal subunit.     

Mutations affecting the structural genes and the genes coding for modifying enzymes for ribosomal proteins in Escherichia coli.

Summary Temperature-sensitive mutants of an Escherichia coli K-12 strain PA3092 have been isolated following mutagenesis with nitrosoguanidine, and their ribosomal proteins analyzed by two-dimensional gel electrophoresis This method was found to be very efficient in obtaining mutants with various structural alterations in ribosomal proteins. Thus a total of some 160 mutants with alterations in 41 different ribosomal proteins have so far been isolated. By characterizing these mutants, we could isolate, not only those mutants with alterations in the structural genes for various ribosomal proteins, but also those with impairments in the modification of proteins S5, S18 and L12. Furthermore, a mutant has been obtained which apparently lacks the protein S20 (L26) with a concomitant reduction to a great extent of the polypeptide synthetic activity of the small subunit. The usefulness of these mutants in establishing the genetic architecture of the genes coding for the ribosomal proteins and their modifiers is discussed.     

The cytoplasmic ribosomes of Chlamydomonas reinhardtii: characterization of antibiotic sensitivity and cycloheximide-resistant mutants

Summary In vitro protein synthesis was used to characterize the antibiotic sensitivity of cytoplasmic ribosomes from wild-type and antibiotic-resistant strains of Chlamydomonas reinhardtii. Cytoplasmic ribosomes from two cycloheximide-resistant mutants, act-1 and act-2, were resistant to the antibiotic in vitro. The alteration effected by the act-1 mutation, which was dominant in diploids, was localized to the large subunit of the cytoplasmic ribosomes, but no ribosomal protein alterations were detected using two-dimensional gel electrophoresis. The act-2 mutation, which was semidominant in diploids, was frequently associated with a charge alteration in the large subunit ribosomal protein (r-protein) cyL38 that segregated independently from the antibiotic-resistant phenotype in crosses.     

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 central core region of yeast ribosomal protein L11 is important for subunit joining and translational fidelity

Yeast ribosomal protein L11 is positioned at the intersubunit cleft of the large subunit central protuberance, forming an intersubunit bridge with the small subunit protein S18. Mutants were engineered in the central core region of L11 which interacts with Helix 84 of the 25S rRNA. Numerous mutants in this region conferred 60S subunit biogenesis defects. Specifically, many mutations of F96 and the A66D mutant promoted formation of halfmers as assayed by sucrose density ultracentrifugation. Halfmer formation was not due to deficiency in 60S subunit production, suggesting that the mutants affected subunit-joining. Chemical modification analyses indicated that the A66D mutant, but not the F96 mutants, promoted changes in 25S rRNA structure, suggesting at least two modalities for subunit joining defects. 25S rRNA structural changes were located both adjacent to A66D (in H84), and more distant (in H96-7). While none of the mutants significantly affected ribosome/tRNA binding constants, they did have strong effects on cellular growth at both high and low temperatures, in the presence of translational inhibitors, and promoted changes in translational fidelity. Two distinct mechanisms are proposed by which L11 mutants may affect subunit joining, and identification of the amino acids associated with each of these processes are presented. These findings may have implications for our understanding of multifaceted diseases such as Diamond–Blackfan anemia which have been linked in part with mutations in L11.     

Mutants of Escherichia coli lacking ribosomal protein L1

Two independently isolated mutants of Escherichia coli, RD19 and MV17-10, that appeared to lack protein L1 on their ribosomes, as determined by two-dimensional gels, were subjected to a battery of immunological tests to find if L1 was indeed lacking. The tests involved Ouchterlony double diffusion, modified immunoelectrophoresis, dimer formation on sucrose gradients, and affinity chromatography. By all these criteria, protein L1 was missing from the ribosome in these mutants. Nor was any L1 cross-reacting material detectable in the supernatant. There was, however, a specific two- to fivefold increase in concentrations of protein L11 in the supernatants of the mutants, which was evidence that protein L1 acts as a feedback inhibitor of expression of the operon coding for the genes for proteins L11 and L1.Electron micrographs of ribosomes obtained from these mutants were indistinguishable from those of wild-type strains. 50 S ribosomal subunits from mutants RD19 and MV17-10 were reconstituted with purified L1 from wild-type and investigated by immunoelectron microscopy. The three-dimensional location of ribosomal protein L1 on the surface of the large subunit was determined. L1 is located on the wider lateral protuberance of the 50 S subunit. The position of protein L1 in 50 S subunits reconstituted from mutants RD19 and MV17-10 was indistinguishable from the position in subunits from wild-type.     

Subcellular distribution of ribosomal proteins in Dictyostelium discoideum

The distribution of ribosomal proteins in monosomes, polysomes, the postribosomal cytosol, and the nucleus was determined during steady-state growth in vegetative amoebae. A partitioning of previously reported cell-specific ribosomal proteins between monosomes and polysomes was observed. L18, one of the two unique proteins in amoeba ribosomes, was distributed equally among monosomes and polysomes. However S5, the other unique protein, was abundant in monosomes but barely visible in polysomes. Of the developmentally regulated proteins, D and S6 were detectable only in polysomes and S14 was more abundant in monosomes. The cytosol revealed no ribosomal proteins. On staining of the nuclear proteins with Coomassie blue, about 18, 7 from 40S subunit and 11 from 60S subunit, were identified as ribosomal proteins. By in vivo labeling of the proteins with [35S]methionine, 24 of the 34 small subunit proteins and 33 of the 42 large subunit proteins were localized in the nucleus. For the majority of the ribosomal proteins, the apparent relative stoichiometry was similar in nuclear preribosomal particles and in cytoplasmic ribosomes. However, in preribosomal particles the relative amount of four proteins (S11, S30, L7, and L10) was two- to four-fold higher and of eight proteins (S14, S15, S20, S34, L12, L27, L34, and L42) was two-to four-fold lower than that of cytoplasmic ribosomes.     

Studies on proteins of animal ribosomes XXIV. Localisation of proteins in ribosomal subunits of rat liver studied by chemical substitution with p-nitrophenyl acetate and methyl acetimidate

The reaction of [³H]p-nitrophenyl acetate (NPA) or [¹⁴C]methyl acetimidate (MAI) with amino groups of ribosomal proteins from the rate has been studied.A comparison has been made between the reactivity of the proteins in situ in the ribosomal subunit with that of isolated protein mixtures.In the small subunit reactivity compared with the protein mixture was only 10–65% in the case of NPA but 45 to more than 100% in the case of MAI.In the large subunit reactivity to MAI was 10–60% that of the isolated protein mixture. This suggests that the large subunit has a denser structure than the small one.In agreement with earlier experiments with iodoacetamide the proteins S2, 5, 7, 8, 10 and 13 of the small subunit and L15, 17, 20, 24, 25, 27, 29, 33, 34, 35 and 38 in the large subunit are quite accessible while proteins S9, 14, 19, 20, 24, 25, 27, 29 and 30 of the small subunit and L1, 7, 8, 10, 11, 19, 28, 31 and 32 of the large one are relatively inaccessible.