Spontaneous missense mutations in the rplX gene for ribosomal protein L24 from Escherichia coli.

Temperature-resistant pseudorevertants of the temperature-sensitive Escherichia coli mutant KNS19, harboring a mutation in rplX, the gene for ribosomal protein L24, were isolated, cloned, and sequenced. The codon GAC for the amino acid Asp in the temperature-sensitive mutant corresponding to position 84 in the protein chain mutated either back to the wild type (Gly) or to codons for the amino acids Tyr and Glu. Furthermore, rplX genes from two other mutants with an altered protein L24 were cloned and sequenced. The mutations were localized at position 56 (Gly to Asp) and at position 62 (Glu to Lys) in the rplX gene. The latter two mutants lacked a conditional lethal phenotype. The results suggest that the amino acid Gly at positions 56 and 84 in the protein might be involved in loop formations.     

DNA sequence and complementation analysis of a mutation in the rplX gene from Escherichia coli leading to loss of ribosomal protein L24.

A mutation in Escherichia coli leads to the loss of ribosomal protein L24, severely impaired growth, and a temperature-sensitive phenotype. The mutation was shown to be in rplX, the gene for protein L24, and was due to the alteration of an AAA codon to a TAA stop codon at position 61 in rplX that resulted in a 20-amino acid peptide instead of the 104 amino acids of wild-type L24 protein. rplX genes from three temperature-resistant and fast growing pseudorevertants of the mutant were cloned and sequenced. They were found to have different base substitutions in the TAA codon, resulting in the reappearance of a full-sized protein L24 moiety. Complementation of the slow growth in trans could be achieved with several plasmids containing at least the spc promoter and intact L14 and L24 genes. Plasmids containing genes distal to rplX could further stimulate growth, and the wild type arose when the entire spc operon and the alpha operon were present. In all cases, protein L24 was expressed by the plasmids. Therefore, slow growth could be explained by polarity extending to the alpha operon. However, temperature sensitivity could not be complemented by any of the plasmids in trans, although we found that this phenotype was caused by the mutation in the rplX gene.     

A temperature-sensitive mutant in the gene rplX for ribosomal protein L24 and its suppression by spontaneous mutations in a 23S rRNA gene of Escherichia coli.

A temperature-sensitive mutant with an altered ribosomal protein L24 was analysed. Revertant analysis showed that the temperature-sensitive growth was correlated with the altered protein. A DNA segment containing the mutant rplX gene was cloned and sequenced. The GGC codon for glycine at the amino acid position 84 of the protein was found to be altered to a GAC codon for aspartic acid. By transforming the rplX mutant with a plasmid carrying the rrnB operon and by selecting for temperature-resistant transformants we obtained two spontaneous suppressor mutants in the gene for 23S rRNA. DNA sequence analysis of the region corresponding to the 5' end of the 23S rRNA showed a C to T alteration at position 33 in both mutants and an additional A to G alteration at position 466 in one of them. The results suggest intimate interaction of protein L24 and the 5' end of 23S rRNA in vivo and support a secondary structure model of the 23S rRNA which brings these mutational points into a close contact.     

Involvement of DnaK3, One of the Three DnaK Proteins of Cyanobacterium Synechococcus sp. PCC7942, in Translational Process on the Surface of the Thylakoid Membrane

The Synechococcus sp. PCC7942 strain carrying a missense mutation in the peptide-binding domain of DnaK3, one of the essential dnaK gene products, revealed temperature-sensitive growth. We also isolated suppressor mutants of this strain. One of the suppressors was mapped in the ribosomal protein gene rpl24 (syc1876), which encodes the 50S ribosomal protein L24. Subcellular localization of three DnaK proteins was determined, and the results indicated that a quantity of DnaK3 was dislocated from membrane-bound polysomes when dnaK3 temperature-sensitive mutant was incubated at non-permissive temperatures. Furthermore, we examined the photosystem II reaction center protein D1 and detected a translational intermediate polypeptide in membrane-bound polysome fractions prepared from dnaK3 temperature-sensitive cells grown at high temperature. These characteristic features of DnaK3 localizations and detection of D1 protein intermediate were not observed in the suppressor mutant even at high temperatures.     

A spontaneous mutant of Escherichia coli with protein L24 lacking from the ribosome

Summary A spontaneous mutant that lacked ribosomal protein L24 was isolated and its derivatives investigated. The lesion responsible was close to, or in, rplX, the gene for protein L24. It led to a severe reduction in the amount of the large ribosomal subunit, even under permissive growth conditions. The mutation also led to a very slow growth rate and a temperature sensitive phenotype of carrier strains. Temperature indifferent secondary mutants frequently showed recovery of protein L24, but the protein was usually in a form larger than wildtype. Other secondary mutants had acquired an external suppressor that resulted in the simultaneous alteration of several other ribosomal proteins as well as the fractional presence of protein L24. Secondary mutants had normal amounts of the large ribosomal subunit, but it sedimented more slowly than normal.     

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).     

Characterization of an amber mutation in the structural gene for ribosomal protein L15, which impairs the expression of the protein export gene, secY, in Escherichia coli

We have previously described a temperature-sensitive mutant, ts215, which is defective in protein secretion. Complementation studies indicated that the mutation was located at the distal part of the spc ribosomal protein operon and the gene secY is required for efficient protein secretion. We now report a more complete genetic and biochemical analysis of the ts215 mutant. These studies revealed that the ts215 mutant has an amber mutation in the gene rp10 for ribosomal protein L15, which is located upstream and adjacent to secY. The amber mutation exerts a polar effect on secY causing a defect in protein secretion. These conclusions were supported by the following observations. The mutant strain carries a phi 80 prophage containing a temperature-sensitive suppressor, supFts6. The strain contains decreased amounts of L15 and is suppressible by a temperature-independent nonsense suppressor. In addition, L15 contains an extra tyrosine residue when suppressed by supF. DNA sequence analysis revealed the presence of a single base change in rp10 resulting in an amber codon at the 38th codon of L15. The mutant phenotype is complemented by a plasmid carrying only the secY gene under lac promoter control. The mutant cells complemented by secY can grow and synthesize proteins at normal rates and abundances at 42 degrees C, despite the fact that their ribosomes contain barely detectable levels of L15. These results indicate that ribosomal protein L15 is dispensable for protein synthesis and cell growth. In contrast, the decreased level of expression of the secY gene leads to defective protein secretion and defective cell growth.     

DNA sequencing of the Escherichia coli ribonuclease III gene and its mutations

Summary A 0.7 kb DNA fragment of the Escherichia coli K12 chromosome was shown to contain the structural gene for RNAse III (rnc). The DNA sequence of the gene was determined and its alteration in an RNAse III defective mutant, AB301-105, was identified. DNA sequence analysis also showed that a secondary-site suppressor of a temperature-sensitive mutation in the E. coli ribosomal protein gene, rpsL, occurred within the rnc gene, providing genetic evidence for the interaction of ribosomal proteins with RNAse III, which in turn acts on the nascent ribosomal RNA during assembly of ribosomes in E. coli.     

Identification of the structural gene for the S9 ribosomal protein in the fungus Podospora anserina: a new protein involved in the control of translational accuracy

Summary AS9-1 was isolated as a mutation restoring growth in a strain carrying the ribosomal mutation su12-1. The AS9-1 mutation confers a weak antisuppressor effect and a low level of resistance to paromomycin. Two-dimensional polyacrylamide gel electrophoresis patterns of the ribosomal proteins from AS9-1 strains show an altered S9 protein which is more basic than the wild-type form. The presence of the two forms of the protein (wild-type and mutant) in heterocaryotic strains strongly suggests that AS9 is the structural gene for the ribosomal protein S9.     

Involvement of DnaK3, one of the three DnaK proteins of cyanobacterium Synechococcus sp. PCC7942, in translational process on the surface of the thylakoid membrane

The Synechococcus sp. PCC7942 strain carrying a missense mutation in the peptide-binding domain of DnaK3, one of the essential dnaK gene products, revealed temperature-sensitive growth. We also isolated suppressor mutants of this strain. One of the suppressors was mapped in the ribosomal protein gene rpl24 (syc1876), which encodes the 50S ribosomal protein L24. Subcellular localization of three DnaK proteins was determined, and the results indicated that a quantity of DnaK3 was dislocated from membrane-bound polysomes when dnaK3 temperature-sensitive mutant was incubated at non-permissive temperatures. Furthermore, we examined the photosystem II reaction center protein D1 and detected a translational intermediate polypeptide in membrane-bound polysome fractions prepared from dnaK3 temperature-sensitive cells grown at high temperature. These characteristic features of DnaK3 localizations and detection of D1 protein intermediate were not observed in the suppressor mutant even at high temperatures.     

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.     

Ribosomal protein methylation in Escherichia coli: the gene prmA, encoding the ribosomal protein L11 methyltransferase, is dispensable

The prmA gene, located at 72 min on the Escherichia coli chromosome, is the genetic determinant of ribosomal protein L11-methyltransferase activity. Mutations at this locus, prmA1 and prmA3, result in a severely undermethylated form of L11. No effect, other than the lack of methyl groups on L11, has been ascribed to these mutations. DNA sequence analysis of the mutant alleles prmA1 and prmA3 detected point mutations near the C-terminus of the protein and plasmids overproducing the wild-type and the two mutant proteins have been constructed. The wild-type PrmA protein could be crosslinked to its radiolabelled substrate, S-adenosyl-L -methionine (SAM), by u.v. irradiation indicating that it is the gene for the methyltransferase rather than a regulatory protein. One of the mutant proteins, PrmA3, was also weakly crosslinked to SAM. Both mutant enzymes when expressed from the overproducing plasmids were capable of catalysing the incorporation of ³H-labelled methyl groups from SAM to L11 in vitro. This confirmed the observation that the mutant proteins possess significant residual activity which could account for their lack of growth phenotype. However, a strain carrying an in vitro-constructed null mutation of the prmA gene, transferred to the E. coli chromosome by homologous recombination, was perfectly viable.     

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.     

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.     

The ribosomal components responsible for kasugamycin dependence, and its suppression, in a mutant of Escherichia coli

Summary The phenotype of a kasugamycin dependent mutant, MV17, was found to be the product of a kasugamycin resistance mutation in ksgA, together with a dependentizing mutation in rplW, the gene for large ribosomal subunit protein L23. Revertants from dependence on this small subunit targeted antibiotic were found to have mutational alterations in ribosomal proteins L23, L1, L11, and S9. The mutations causing alterations in L1 and L23 were shown to be responsible for the reversion and that altering L11 to be involved in the reversion.     

An amber mutation in the gene rpsA for ribosomal protein S1 in Escherichia coli

Summary An amber mutation has been induced in the gene rpsA (which codes fo ribosomal protein S1) of Escherichia coli K-12 strain in the presence of an amber suppressor (supD) and mutations sueA, sueB and sueC that additively enhance the efficiency of suppression. That the amber mutation has occurred in the gene rpsA was confirmed by complementation with a plasmid which carried the wild-type allele of rpsA. The mutation is lethal in the absence of an amber suppressor, indicating that ribosomal protein S1 is indispensable to E. coli.     

Recessive nonsense-suppression in yeast: Involvement of 60S ribosomal subunit

Summary The ribosomal protein patterns of recessive suppressor strain and parent strain of Saccharomyces cerevisiae were analyzed by two-dimensional polyacrylamide gel electrophoresis. About 30 protein spots were found for ribosomal proteins of small subunit for both mutant and parent strain. These patterns do not differ from each other neither in intensity of staining, nor in mobility of spots. 41 protein spots were found in electrophoregrams of 60S ribosomal proteins both from parent strain and recessive suppressor strain. The electrophoretic picture of the 60S proteins from the parent and mutant strains is similar except the intensity of staining of the L30 spot. This protein is present in 60S subunit of suppressor strain and completely absent or only weakly stained on electrophoregrams of ribosomal proteins of parent strain. The possible relationships between the content of L30 protein and the mechanism of recessive suppression in yeast are discussed.     

Suppressors of temperature-sensitive mutations in a ribosomal protein gene, rpsL (S12), of Escherichia coli K12

Summary Temperature-sensitive (ts) mutations were isolated within a ribosomal protein gene (rpsL) of Escherichia coli K12. Mutations were mapped by complementation using various transducing phages and plasmids carrying the rpsL gene, having either a normal or a defective promoter for the rpsL operon. One of these mutations, ts118, resulted in a mutant S12 protein which behaved differently from the wild-type S12 on CM-cellulose column chromatography. Suppressors of these ts mutations were isolated and characterized; one was found to be a mutation of a nonribosomal protein gene which was closely linked to the RNAase III gene on the E. coli chromosome. This suppressor, which was recessive to its wild-type allele, was cloned into a transducing phage and mapped finely. A series of cold-sensitive mutations, affecting the assembly of ribosomes at 20°C, was isolated within the purL to nadB region of the E. coli chromosome and one group, named rbaA, mapped at the same locus as the suppressor mutation, showing close linkage to the RNAase III gene.     

Ribosomal protein modification in Escherichia coli

Summary Among mutants of E. coli selected for temperaturesensitive growth, four were found to possess alterations in ribosomal proteins L7/L12. Of these, three apparently lack protein L7, the acetylated form of protein L12. Genetic analyses have revealed that the mutation responsible for this alteration maps at a locus around 34 min of the current E. coli genetic map, which is clearly different from the location for the structural gene for protein L7/L12 which is situated at 89 min. Hence, the gene affected in these mutants was termed rimL. Tryptic and thermolysin fingerprints of the protein L12 purified from the rimL mutants showed a profile indistinguishable from that of wild-type protein. It was found that the acetylase activity specific for protein L12 was negligible, when assayed in vitro, in the high-speed supernatant prepared from mutant cells. These results indicated that the three mutants contain mutations in the gene rimL that codes for an acetylating enzyme specific for ribosomal protein L12.Previous paper in this series is Isono and Isono (1980)