The structural gene for the ribosomal protein S18 in Escherichia coli. II. Chemical studies on the protein S18 having an altered electrophoretic mobility

A mutant of Escherichia coli strain CR341 has an altered 30 S ribosomal protein S18. The alteration involves a change in the electrophoretic mobility of S18. S18 proteins were purified from the mutant and the parent strain, respectively, and their amino acid composition and tryptic peptides were compared. The results have shown that the mutational alteration involves substitution of cysteine for arginine. In addition, we determined the electrophoretic mobility of S18 proteins modified by ethyleneimine. The modification, which involves conversion of cysteine residues to S-(2-aminoethyl)cysteine, causes a greater electrophoretic mobility increase in the mutant protein than in the wild type protein, resulting in identical mobilities for the aminoethylated proteins. This experiment gives further support to the conclusion that the original mobility difference between mutant and wild type proteins is due to the mutational substitution of cysteine for arginine. The S18 obtained from a recombinant was also studied. The recombinant protein was found to have the mobility of the wild type protein and the wild type primary structure, as judged by amino acid composition and tryptic peptide analysis. This recombinant was obtained from the mutant by introducing Hfr strain G10 chromosome segments in the region between 70 and 10 minutes, and not in the str-spc region at 64 minutes, as described in the preceding paper. These results, together with those in the preceding paper, show that the mutation studied here is in the structural gene for S18, and that it maps outside the str-spc region.     

Ribosomal protein modification in Escherichia coli. I. A mutant lacking the N-terminal acetylation of protein S5 exhibits thermosensitivity.

A thermosensitive mutant (JE386) of Escherichia coli which harbours an alteration in protein S5 of the smaller ribosomal subunit has been isolated. Genetic studies have shown that the lesion causing thermosensitivity also causes the alteration in protein S5, and that this mutation is not in the structural gene for S5 (rpsE). Hence the mutation has been termed rimJ (ribosomal modification). Protein-chemical studies of protein S5 purified from JE386 and its wild-type parent indicated an alteration in the N-terminal tryptic peptide. Amino acid sequence analysis of the N-terminal peptides showed complete homology between wild-type and mutant, suggesting that the N-terminal modification (acetylation) of the parent was absent in the mutant. Gradient transmission mapping has located the rimJ mutation at 31 minutes on the current E. coli genetic map. By constructing a derivative of the mutant heterozygous for rimJ, it has been found that the wild-type allele is dominant over the mutant one. Ts⁺ revertants of JE386 have been isolated which show either a wild-type ribosomal protein electrophoresis pattern, or an additional alteration in either protein S4 or S5. The mutations in S4 and S5 may compensate the lesion caused by the rimJ mutation of JE386, that is even though the N-terminus of S5 remains unacetylated, bacteria can grow at 42 °C. Furthermore, a mutation near or at strA carried by JE386 has been found to be involved in the phenotypic expression of the rimJ mutation. This mutation was also found to be present in four other strA mutants. Possible implications of the modification of ribosomal proteins in vivo are discussed.     

Alteration of ribosomal protein S17 by mutation linked to neamine resistance in Escherichia coli: II. Localization of the amino acid replacement in protein S17 from a neaA mutant

A mutant of Escherichia coli strain K12S, nea^R301, resistant to the antibiotic neamine was found to have an altered 30 S ribosomal protein S17. The modification involves a change in the electrophoretic mobility of this protein. S17 proteins wore purified from the mutant and the parental strain, respectively, and the amino acid compositions of all tryptic peptides were compared. The results show that the mutational alteration involves a replacement of histidine by proline in peptide T8 from mutant nea^R301. The amino acid replacement is located at position 30 of the S17 protein chain. We conclude, therefore, that the mutation nea^R301 affects the structural gene for protein S17 (rps Q).     

Ribosomal protein modification in Escherichia coli

Summary A mutant of Escherichia coli K12 has been isolated which shows an alteration in the ribosomal protein S18. Genetic analyses have revealed that the mutation causing this alteration maps at 99.3 min of the E. coli genetic map, between dnaC and deo. This indicated that the mutation has occurred in a gene different from the structural gene for this protein which has been located at 94 min. From the N-terminal amino acid sequence analysis it is concluded that the mutation has resulted in loss of the N-terminal acetyl group of this protein. The gene which is affected in this mutant is termed rimI that most likely specifies an enzyme acetylating the N-terminal alanine of protein S18. The mutation does not affect the acetylation of two other ribosomal proteins, S5 and L12, both of which are known to be acetylated in wild-type E. coli K12.     

Gene rpmF for ribosomal protein L32 and gene rimJ for a ribosomal protein acetylating enzyme are located near pyrC (23.4 min) in Escherichia coli

Summary An Escherichia coli mutant harbouring altered ribosomal protein L32 has been isolated and genetically characterized. The mutation leading to this alteration (rpmF) and the temperature-sensitive mutation (ts-1517) present in the same strain were found to map near pyrC (23.4 min), being cotransducible not only with pyrC but also with fabD, flaT and purB in P1 phage mediated transductions. Furthermore, we found that the gene rimJ, which encodes an enzyme that acetylates the N-terminal alanine of protein S5 and the temperature-sensitive mutation, ts-386, present in the rimJ mutant strain (Cumberlidge and Isono 1979) also mapped in this region. Thus, the order of genes is deduced to be: ts-386-pyrC-ts-1517-rimJ-flaT-fabD-rpmF-purB.     

Ribosomal assembly deficiency in an Escherichia coli thermosensitive mutant having an altered L24 ribosomal protein.

Localized P1 mutagenesis was used to screen for conditionally lethal mutations in ribosomal protein genes. One such mutation, 2859mis, has been mapped inside the ribosomal protein gene cluster at 72 minutes on the Escherichia coli chromosome and cotransduces at 98% with rpsE (S5). The 2869mis mutation leads to thermosensitivity and impaired assembly in vivo of 50 S ribosomal particles at 42 °C. The strain carrying the mutation has an altered L24 ribosomal protein which at 42 °C shows weaker affinity for 23 S RNA than the wild-type protein. The mutational alteration involves a replacement of glycine by aspartic acid in protein L24 from the mutant. We conclude therefore that the 2859mis mutation affects the structural gene for protein L24 (rplX).     

The gene for ribosomal protein L25 (rplY) maps at 47.3 min near nalA in Escherichia coli K-12.

Summary A temperature sensitive mutant, termed JE1306, derived from Escherichia coli strain PA3092 was found to have an alteration in the ribosomal protein L25. Crosses with various Hfr strains and transductions with P1kc phage have revealed that the mutation maps at 47.3 min between nalA and fpk, in a region where no ribosomal protein gene has so far been located. The gene affected by this mutation is most probably the structural gene for protein L25 (rplY), because a strain heteromerozygous for the region shows both wild type and mutant forms of protein L25.     

Localization of the structural gene for ribosomal protein L19 (rplS) in Escherichia coli

Summary A temperature-sensitive mutant derived from an E. coli K12 strain, PA3092, was found to have an alteration in the ribosomal protein L19 (Isono et al., 1977). This mutant is a double mutant with a temperature-sensitivity mutation and a mutation leading to the structural alteration of L19 protein. Crosses with various Hfr strains and transductions with P1kc have revealed that the latter mutation maps at 56.4 min, between pheA and alaS. From the fact that two other mutations causing different types of alterations in L19 protein also map at this locus, the gene affected by these mutations was concluded to be the structural gene for the ribosomal protein L19 (rplS).     

Late steps in the assembly of 30 S ribosomal proteins in vivo in a spectinomycin-resistant mutant of Escherichia coli.

The late steps in ribosome assembly in vivo were studied by characterizing mutations which suppress the cold-sensitivity of a spectinomycin-resistant mutant of Escherichia coli. The results obtained indicated that the cold-sensitivity could be relieved by secondary alterations in either the S2, S3 or S5 protein of the 30 S ribosomal subunit. The gene controlling the alteration of S2 protein was closely linked to the polC gene located at about 3.5 minutes on the genetic map of E. coli, whereas S3 and S5 suppressor genes were linked to the str-spc region at 64 minutes. A possible model in which the S2, S3 and S5 proteins constitute a sub-assembly pathway in the assembly of 30 S subunits in vivo is discussed.     

Genes encoding ribosomal proteins S16 and L19 form a gene cluster at 56.4 min in Escherichia coli.

Summary A mutant of Escherichia coli which was isolated for temperature-sensitive growth was found to harbour a structural alteration in protein S16 (Isono et al., 1978). The mutation was localized by matings with various Hfr strains and by Plkc-mediated transduction. The results showed that it mapped very close to the gene coding for L19 protein which has been placed at 56.4 min (Kitakawa and Isono, 1977), indicating that it most likely forms a new ribosomal protein-gene cluster.     

A conditionally lethal mutation of Escherichia coli affecting the gene coding for ribosomal protein S2 (rpsB).

Localized P1 mutagenesis has been used to isolate conditionally lethal mutations in the four-minute region of the Escherichia coli genome. One such mutation, ts25, has been mapped at about 3.7 minutes between the popC and dapD genes. This mutation leads to thermosensitivity of growth and impaired in vivo assembly of 30 S ribosomal subunits at 42 °C. The strain carrying the mutation has an altered S2 ribosomal protein as judged by (1) its inability to maintain stable complex with the ribosome under mild washing conditions and (2) its altered electrophoretic mobility.Spontaneous reversion to temperature independence can restore both the normal assembly in vivo of 30 S ribosomal subunits at 42 °C and the normal electrophoretic behaviour of the S2 ribosomal protein in vitro.We conclude therefore that the ts25 mutation affects the structural gene for ribosomal protein S2 (rpsB).     

A missense mutation in the gene coding for ribosomal protein S17 (rpsQ) leading to ribosomal assembly defectivity in Escherichia coli.

Summary The conditionally lethal mutation, 286lmis, has been mapped inside the ribosomal protein gene cluster at 72 minutes on the Escherichia coli chromosome and was found to cotransduce at 97% with rpsE (S5). The 2861mis mutation leads to thermosensitivity and impaired assembly in vivo of 30S ribosomal particles at 42°C. The strain carrying the mutation has an altered S17 ribosomal protein; the mutational alteration involves a replacement of serine by phenylalanine in protein S17. Spontaneous reversion to temperature independence can restore the normal assembly in vivo of 30S ribosomal subunits at 42°C and the normal chromatographical sehaviour of the S17 ribosomal protein in vitro. We conclude therefore that the 2861mis mutation affects the structural gene for protein S17 (rpsQ).     

Restoration by ribosomal protein S1 of the defective translation in a temperature-sensitive mutant of Escherichia coli K-12: characterization and genetic studies.

A temperature-sensitive mutant of Escherichia coli was isolated that had a temperature-sensitive defect in ribosomal-wash protein(s) required for translation in vitro of E. coli endogenous messenger ribonucleic acid. It was found that 30S ribosomal protein S1 rescued the defect in the ribosomal-wash protein(s) of the mutant and that the complete restoration to the wild-type level was attained when 1 mol of protein S1 was added to 1 mol of 70S ribosome. The mutation, tss, causing such a defect was mapped at 21 min and was closely linked to the pyrD locus, the region of which was entirely different from that of the other genes coding for the many ribosomal proteins of E. coli. These results indicate that the gene specified by this mutation is involved in the function of the 30S ribosomal protein S1.     

RRP20, a component of the 90S preribosome,is required for pre-18S rRNA processing in Saccharomyces cerevisiae

A strain of Saccharomyces cerevisiae, defective in small subunit ribosomal RNA processing, has a mutation in YOR145c ORF that converts Gly235 to Asp. Yor145c is a nucleolar protein required for cell viability and has been reported recently to be present in 90S pre-ribosomal particles. The Gly235Asp mutation in YOR145c is found in a KH-type RNA-binding domain and causes a marked deficiency in 18S rRNA production. Detailed studies by northern blotting and primer extension analyses show that the mutant strain impairs the early pre-rRNA processing cleavage essentially at sites A₁ and A₂, leading to accumulation of a 22S dead-end processing product that is found in only a few rRNA processing mutants. Furthermore, U3, U14, snR10 and snR30 snoRNAs, involved in early pre-rRNA cleavages, are not destabilized by the YOR145c mutation. As the protein encoded by YOR145c is found in pre-ribosomal particles and the mutant strain is defective in ribosomal RNA processing, we have renamed it as RRP20.     

Alteration of ribosomal protein S2 in kasugamycin-resistant mutant derived from Escherichia coli AB312

A new type of kasugamycin-resistant mutant has been isolated from $\text{E. coli}$ K12, strain AB312 (Hfr, $\text{lac,thr,leu,thi,strA,fus}$). In a cell-free protein-synthetic system, the resistance is localized in the ribosome but not in the supernatant fraction. On initiation complex formation, the resistance is associated with the washed ribosome but not with initiation factors. In reconstitution of the 30S ribosomal subunit, the resistance is due to the protein(s) but not to 16S RNA. In two-dimensional electrophoresis, protein S2 is deficient in the 30S ribosomal subunit of kasugamycin-resistant mutant. The results indicate that the kasugamycin-resistance is attributed to alteration of ribosomal protein S2.     

A streptomycin-resistant Escherichia coli mutant with ribosomes temperature-sensitive in the suppression of a nonsense codon.

Summary Cell free extracts from a streptomycin-resistant E. coli mutant which is also temperature-sensitive for Q phage were studied for suppression of a nonsense mutation at various temperatures. The streptomycin-resistant ribosomes of the mutant were found to be temperature-sensitive in suppression of an amber mutation in f2 phage coat protein while retaining the ability to synthesize proteins at an elevated temperature (42° C). The restriction of amber suppression at 42° C is assumed to be related to an alteration in the ribosomal protein S12 of the streptomycin-resistant mutant which also causes a change in its electrophoretic mobility.     

A temperature-sensitive mutant ofEscherichia coli with an alteration in ribosomal protein L22

A temperature-sensitive, protein synthesis-defective mutant ofEscherichia coli exhibiting an altered ribosomal protein L22 has been investigated. The temperature-sensitive mutation was mapped to therplV gene for protein L22. The genes from the wild type and mutant strains were amplified by the polymerase chain reaction and the products were sequenced. A cytosine to thymine transition at position 22 of the coding sequence was found in the mutant DNA, predicting an arginine to cysteine alteration in the protein. A single cysteine residue was found in the isolated mutant protein. This amino acid change accounts for the altered mobility of the mutant protein in two-dimensional gels and during reversed-phase HPLC. The temperature-sensitive phenotype was fully complemented by a plasmid carrying the wild type L22 gene. Ribosomes from the complemented cells showed only wild type protein L22 by two dimensional gel analysis and were as heat-resistant as control ribosomes in a translation assay. The point mutation in the L22 gene is uniquely responsible for the temperature-sensitivity of this strain.     

Genetic analysis of an alteration of ribosomal protein S20 in revertants of an alanyl-tRNA-synthetase mutant of Escherichia coli

Summary The genetic location has been determined of two mutations which suppress the temperature-sensitive phenotype of an alanyl-tRNA-synthetase mutant of Escherichia coli and which are correlated with alterations of the ribosomal protein S20. Both mutations map at the same chromosomal site; the gene order relative to other markers of the Escherichia coli map is thr-sup-pyrA-araC-leu.Replacement of the suppressor allele by the wild-type allele via P1 transduction results in the appearance of the wild-type S20 protein; concomitantly suppression of temperature-sensitivity is released.Strains of Escherichia coli were contructed which are partially diploid for the region of the chromosome containing the suppressor allele. Investigation of these strains revealed that the wild-type suppressor is dominant as judged by the activity to suppress the alaS mutation since the partial diploids are no longer able to suppress the alaS-3 mutation. Investigation of the ribosomal protein pattern of these partial diploids by means of two-dimensional polyacrylamide gel electrophoresis did not reveal two distinct spots characteristic for the normal and the altered forms of S20; rather, an elongated spot was observed trailing from the wild-type S20 position towards the anode.     

An Escherichia coli K12 mutant carrying altered ribosomal protein (S10).

An $\text{Escherichia coli}$ mutant (JE14373) carrying decreased stability of stable RNA species was found to have altered electrophoretic mobility of a 30S ribosomal protein (S10). Recombinants covering $\text{str}$ gene (76 min on $\text{E. coli}$ linkage map by Bachmann, Low and Taylor, 1976 (ref. 1)) obtained from a cross of CSH64 × JE14373, restored normal S10 protein. The size analysis of RNAs labeled for 15 min with [³H]uridine showed 50 to 60 % decrease of 16S RNA in this mutant strain, but almost no decrease of 23S RNA at 10 or 40 min after addition of rifampicin. On the other hand, no change was observed in the stability of both rRNA pieces in its parental PA3092 strain even at 40 min after addition of rifampicin.     

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.