The structural gene for the ribosomal protein S18 in Escherichia coli. I. Genetic studies on a mutant having an alteration in the protein S18

A mutant of Escherichia coli strain CR341, originally isolated as a temperature-sensitive mutant, was found to have an altered 30 S ribosomal protein (S18) in addition to and independently of temperature sensitivity. Protein S18 from the mutant strain differs in electrophoretic mobility in polyacrylamide gel electrophoresis at pH 4.5 from protein S18 of the parental origin. The mutation responsible for the alteration in S18 is different from two other mutations in the mutant strain which give the temperature-sensitive phenotype. The gene involved in the S18 alteration is located in a region between 76 and 88 minutes on the E. coli genetic map; the location is outside the str-spc region at 64 minutes, where several known ribosomal protein genes are located. An episome covering the loci rha (76 min) through pyr B (84 min) was introduced into the mutant. The resultant merodiploid strains were shown to produce both the normal and the mutant forms of S18. The results support the conclusion described in the accompanying paper (Kahan et al., 1973) that the mutation studied is in the structural gene for S18.     

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).     

Genetic studies of the ribosomal proteins in Escherichia coli. I. Mutants and strains having 30s ribosomal subunit with altered protein components

Summary Two 30s ribosomal protein components, 30-4_K and 30-7_K, from E. coli K12 strain were clearly distinguished on the CMC column chromatogram from the corresponding protein components, 30-4_B and 30-7_B, from B strain. The 30-7_K component was shown to correspond to the K-character.A mutant strain of K12, W3637, had an altered 30s ribosomal protein component, 30-9_W3637.The characters of 30-4_K, 30-7_K, 30-9_W3637 and str ^r were found to be cotransduced from W3637 to B strain by Plke phage in 16 out of 20 str ^r transductants. The 30-9_W3637 and 30-4_K components were separated from str ^r in 4 str ^r transductants. These results indicate that (1) neither 30-4 nor 30-9 is the protein whose mutational change leads to str ^r, and (2) the genes specifying the 30s ribosomal proteins, 30-4, 30-7, 30-9 and str are linked on the chromosome.Abbreviations used CMC carboxymethyl cellulose - str streptomycin     

Deletion and insertion mutants in the structural gene for ribosomal protein S1 from Escherichia coli

Mutants have been constructed by deleting regions of the gene rpsA for ribosomal protein S1, which had been cloned in plasmid pACYC184. The mutant genes were analyzed for their ability to complement an S1 amber mutant containing a temperature-sensitive suppressor. Another series of mutants was constructed using the tac promoter plasmid pKK223-3, and the effect of the mutant proteins was analyzed in a strain wild type for rpsA. The gene products of all mutants were identified by the immunoblotting technique. Plasmids with a mutant rpsA gene which do not or only poorly complement the S1 amber mutation cause drastic growth reduction, whereas the overall protein synthesis is affected to different extents depending on the site of the deletion. Mutants which express S1 fragments comprising at least the NH2-terminal 100 amino acids stimulate or inhibit the synthesis of certain cellular proteins. The amount of chromosomal coded S1 was reduced by each mutant plasmid. Our data suggest that S1 has a general regulatory role during protein biosynthesis.     

The Escherichia coli ribosomal protein S16 is an endonuclease

The histone-like protein HU isolated from Escherichia coli exhibited, after several purification steps, a Mg²⁺-dependent nuclease activity. We show here that this activity can be dissociated from HU by a denaturation-renaturation step, and is due to a small fraction of ribosomal protein S16 co-purifying with HU. S16 is an essential component of the 30S ribosomal particles. We have cloned, overproduced, and purified a histidine-tagged S16 and shown that this protein is a DNA-binding protein carrying a Mg²⁺-Mn²⁺-dependent endonuclease activity. This is an unexpected property for a ribosomal protein.     

Physical studies on the conformation of ribosomal protein S4 from Escherichia coli.

Proton magnetic resonance, circular dichroism and infrared spectroscopy were used to investigate the secondary and tertiary structure of the 16-S RNA binding protein S4 from Escherichia coli ribosomes. The proton magnetic resonance spectra of protein S4 in ribosomal reconstitution and low-salt buffers were identical and showed little dipolar broadening of the peaks, suggesting that the protein had an open extended structure. A ring-current-shifted apolar methyl resonance in the high-field region of the spectrum, together with a perturbation of the tyrosine ring proton resonance in the low-field region, indicated the existence of a specific tertiary fold in the polypeptide chain. This structure disappeared on lowering the pH below 5 or on heating above 30 degrees C, both processes being reversible. Circular dichroism measurements on protein S4 showed an alpha-helix content of 32% in reconstitution buffer compared with 26% in low-salt buffer. Heating the protein solution in reconstitution buffer above 35 degrees C reversibly disrupted this extra helix. Infrared studies on both solid films and solutions of protein S4 indicated the presence of little or no beta-structure. These results correlate well with the known RNA binding properties of protein S4.     

Physical localisation and direction of transcription of the structural gene for Escherichia coli ribosomal protein S15

The coding sequence for the Escherichia coli ribosomal protein S15 (rpsO) has been shown to lie immediately adjacent to the structural gene for polynucleotide phosphorylase (pnp). Based on DNA sequencing data, it is deduced that rpsO is transcribed counterclockwise with respect to the standard E. coli genetic map.     

The DNA sequence of the gene rpsA of Escherichia coli coding for ribosomal protein S1.

The DNA sequence of the gene rpsA as well as of its neighboring regions has been determined using the dideoxyribonucleotide method. It was found that there is an "open-reading-frame" of 350 bp which precedes the gene rpsA. Furthermore, an extensive internal repeats of nucleotide sequence have been found in this gene.     

Conformational prediction and circular dichroism studies on ribosomal protein S4 from Escherichia coli.

The conformation of ribosomal protein S4 from Escherichia coli has been studied by circular dichroism (CD) and shown to possess unique conformation free in solution. The near ultraviolet spectrum suggests the existence of unique tertiary structural environment for the aromatic amino acid residues. The far ultraviolet spectrum gives an estimation of its secondary structure which is 32% alpha-helix and 14% beta-structure in reconstitution buffer at 25 degrees C. The conformation of S4 has been predicted from its sequence, and two models are presented here. An attempt is made to correlate these two molecular models with the available physicochemical data concerning the shape, conformation, and possible RNA binding site of protein S4.     

Comparative studies on the structural gene for the ribosomal protein S1 in ten bacterial species

Summary Callus protoplasts of a plastome chlorophyll-deficient mutant of tobacco, Nicotiana tabacum, were fused with mesophyll protoplasts from one of the following five sources: cms-analogs of tobacco bearing the cytoplasms of N. suaveolens, N. undulata, N. repanda, and N. plumbaginifolia, respectively, and the wild species N. glauca. In the sixth experiment, callus cells of the tobacco chlorophyll-deficient genome mutant, homozygous for the Su gene, were hybridized with mesophyll protoplasts of the plastome chlorophyll-deficient mutant of tobacco. Individual dividing heteroplasmic fusion products were isolated mechanically and cloned in microdroplets of nutrient medium. Among the regenerants in all parental combinations, though not in all clones, besides pure green and pure chlorophyll-deficient plants, numerous variegated plant forms were obtained. The variegation of cybrid and hybrid plants was connected with their heterozygocity for chloroplast DNA composition, as demonstrated by restriction analysis. In analytical crosses, the variegation was inherited maternally by part of the sexual progeny, and variegated F₁ progeny were also heterozygous for chloroplast DNA composition. As demonstrated by electron microscopic studies, the variegation is connected with the presence of mixed, i.e., heteroplastidic cells in leaves. The results obtained demonstrate that (1) upon somatic cell fusion, plastome genes are inherited biparentally in most fusion products, and (2) despite an evident mitotic segregation process, heterozygosity for plastome genes is a relatively durable state and can be revealed in cell hybrids of different specific combinations of plasmons after a great number of cell generations. In this regard the plastome cytogetes obtained by somatic cell fusion do not differ qualitatively from the cytoplasmic heterozygotes that arise as a result of the mutation process.     

Cloning of rpsO, the gene for ribosomal protein S15 of Escherichia coli

Summary The gene for Escherichia coli ribosomal protein S15 (rpsO) was cloned on the vector pBR322 from F-prime JCH55 DNA. The recombinant plasmid was transformed to Serratia marcescens cells and it was proved that E. coli S15 was synthesized and incorporated into ribosome particles in S. marcescens cells. A DNA fragment containing rpsO was also inserted into the vector pRF3, which changes its copy number depending on the growth temperature in a temperature-sensitive polA host. By use of this recombinant plasmid it was shown that the relative synthesis rate of S15 increased about twice even when the copy number of the plasmid increased more than twenty-fold.     

Comparative studies on the structural gene for the ribosomal protein S1 in ten bacterial species

Molecular Genetics and Genomics - By applying the Southern blot technique we compared the structural gene rpsA for ribosomal protein S1 and its preceding sequence from Escherichia coli with nine...     

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.