In vitro synthesis of Escherichia coli ribosomal RNA

Synthesis of ribosomal RNA in a cell-free system was achieved using purified Escherichia coli RNA polymerase and bacterial DNA templates from E. coli, Proteus mirabilis and E. coli/P. mirabilis hybrid strains carrying an E. coli DNA enriched for ribosomal RNA genes.Both direct and indirect competition hybridization revealed that from 5 to 15% of the in vitro product, depending on the template used, had sequences homologous to rRNA. The level of synthesis of sequences homologous to rRNA was related directly to the proportion of rRNA genes in the template. The use of heterologous DNA during competition hybridization ensured at least a 100-fold greater sensitivity for the detection of rRNA sequences than from any messenger RNA sequence.     

Organization of ribosomal protein genes in Escherichia coli: II. Mapping of ribosomal protein genes by in vitro synthesis of ribosomal proteins using DNA fragments of a transducing phage as templates

The structural genes for six ribosomal proteins (r-proteins) located in the str-spc region around 64 minutes on the Escherichia coli chromosome have been mapped physically with respect to each other and the neighboring genes aroE and trkA. The genes code for the 30 S r-proteins S4 (ram), S5 (spc), S8, S11, S13 and S14. Furthermore, regions coding for unidentified 50 S r-proteins have been indicated.The mapping was performed by biochemical methods employing DNA from the specialized transducing phage λspc1, which carries the aroE-trkA-spc region of the E. coli chromosome. The phage DNA was cleaved by restriction endonucleases, and the generated DNA fragments used as templates for synthesis of r-proteins in a DNA-dependent cell-free system. Since the relative order of the DNA fragments created by the restriction endonucleases is known, a genetic map could be constructed.     

The effect of parabens on DNA, RNA and protein synthesis in Escherichia coli and Bacillus subtilis

The effect of methyl, propyl and butyl esters of p-hydroxybenzoic acid on DNA and RNA synthesis has been tested in toluenized cells of Escherichia coli and Bacillus subtilis. Both RNA and DNA synthesis of these bacteria were inhibited. The inhibitory concentrations were higher than those previously reported for growth inhibition. Protein synthesis in cell-free extracts (S-30 fraction) of B. subtilis was even more sensitive to parabens than DNA and RNA synthesis, while protein synthesis in Esch. coli was largely unaffected.     

Single-chain ribosome inactivating proteins from plants depurinate Escherichia coli 23S ribosomal RNA.

The rRNA N-glycosidase activities of the catalytically active A chains of the heterodimeric ribosome inactivating proteins (RIPs) ricin and abrin, the single-chain RIPs dianthin 30, dianthin 32, and the leaf and seed forms of pokeweed antiviral protein (PAP) were assayed on E. coli ribosomes. All of the single-chain RIPs were active on E. coli ribosomes as judged by the release of a 243 nucleotide fragment from the 3′ end of 23S rRNA following aniline treatment of the RNA. In contrast, E. coli ribosomes were refractory to the A chains of ricin and abrin. The position of the modification of 23S rRNA by dianthin 32 was determined by primer extension and found to be A₂₆₆₀, which lies in a sequence that is highly conserved in all species.     

Escherichia coli ribosomal protein S1 recognizes two sites in bacteriophage Qbeta RNA.

As a component of bacteriophage Qbeta replicase, S1 is required both for initiation of Qbeta minus strand RNA synthesis and for translational repression, which has been traced to the ability of the enzyme to bind to an internal site in the Qbeta RNA molecule. Previously, Senear and Steitz (Senear, A. W., and Steitz, J. A. (1976) J. Biol. Chem. 251, 1902-1912) found that isolated S1 protein binds specifically to an oligonucleotide spanning residues -38 to -63 from the 3' terminus of Qbeta RNA. Here we report that S1 also interacts strongly with a second oligonucleotide in Qbeta RNA, which is derived from the region recognized by replicase just 5' to the Qbeta coat protein cistron. Both sequences exhibit pyrimidine-rich regions.     

The effect of parabens on DNA, RNA and protein synthesis in Escherichia coli and Bacillus subtilis

The effect of methyl, propyl and butyl esters of p -hydroxybenzoic acid on DNA and RNA synthesis has been tested in toluenized cells of Escherichia coli and Bacillus subtilis. Both RNA and DNA synthesis of these bacteria were inhibited. The inhibitory concentrations were higher than those previously reported for growth inhibition. Protein synthesis in cell-free extracts (S-30 fraction) of B. subtilis was even more sensitive to parabens than DNA and RNA synthesis, while protein synthesis in Esch. coli was largely unaffected.     

Effects of Escherichia coli ribosomal protein S12 mutations on cell-free protein synthesis.

We examined the effects of Escherichia coli ribosomal protein S12 mutations on the efficiency of cell-free protein synthesis. By screening 150 spontaneous streptomycin-resistant isolates from E. coli BL21, we successfully obtained seven mutants of the S12 protein, including two streptomycin-dependent mutants. The mutations occurred at Lys42, Lys87, Pro90 and Gly91 of the 30S ribosomal protein S12. We prepared S30 extracts from mutant cells harvested in the mid-log phase. Their protein synthesis activities were compared by measuring the yields of the active chloramphenicol acetyltransferase. Higher protein production (1.3-fold) than the wild-type was observed with the mutant that replaced Lys42 with Thr (K42T). The K42R, K42N, and K42I strains showed lower activities, while the other mutant strains with Lys87, Pro90 and Pro91 did not show any significant difference from the wild-type. We also assessed the frequency of Leu misincorporation in poly(U)-dependent poly(Phe) synthesis. In this assay system, almost all mutants showed higher accuracy and lower activity than the wild-type. However, K42T offered higher activity, in addition to high accuracy. Furthermore, when 14 mouse cDNA sequences were used as test templates, the protein yields of nine templates in the K42T system were 1.2-2 times higher than that of the wild-type.     

The conformation of 16S RNA in the 30S ribosomal subunit from Escherichia coli.

The digestion of E. coli 16S RNA with a single-strand-specific nuclease produced two fractions separable by gel filtration. One fraction was small oligonucleotides, the other, comprising 67.5% of the total RNA, was highly structured double helical fragments of mol. wt. 7,600. There are thus about 44 helical loops of average size corresponding to 12 base pairs in each 16S RNA. 10% of the RNA could be digested from native 30S subunits. Nuclease attack was primarily in the intraloop single-stranded region but two major sites of attack were located in the interloop single-stranded regions. Nuclease digestion of unfolded subunits produced three classes of fragments, two of which, comprising 80% of the total RNA, were identical to fragments from 16S RNA. The third, consisting of 20% RNA, together with an equal weight of peotein, was a resistant core (sedimentation coefficient 7S).     

Site-directed mutagenesis of the binding site for ribosomal protein S8 within 16S ribosomal RNA from Escherichia coli.

Twelve specific alterations have been introduced into the binding site for ribosomal protein S8 in Escherichia coli 16S rRNA. Appropriate rDNA segments were first cloned into bacteriophage M13 vectors and subjected to bisulfite and oligonucleotide-directed mutagenesis in vitro. Subsequently, the mutagenized sequences were placed within the rrnB operon of plasmid pNO1301 and the mutant plasmids were used to transform E. coli recipients. The growth rates of cells containing the mutant plasmids were determined and compared with that of cells containing the wild-type plasmid. Only those mutations which occurred at highly conserved positions, or were expected to disrupt the secondary structure of the binding site, increased the doubling time appreciably. The most striking changes in growth rate resulted from mutations that altered a small internal loop within the S8 binding site. This structure is phylogenetically conserved in prokaryotic 16S rRNAs and may play a direct role in S8-16S rRNA recognition and interaction.     

Identification of Escherichia coli and Bacillus stearothermophilus ribosomal protein binding sites on Escherichia coli 5S RNA.

Summary E. coli [³²P]-labelled 5S RNA was complexed with E. coli and B. stearothermophilus 50S ribosomal proteins. Limited T₁ RNase digestion of each complex yielded three major fragments which were analysed for their sequences and rebinding of proteins. The primary binding sites for the E. coli binding proteins were determined to be sequences 18 to 57 for E-L5, 58 to 100 for E-L18 and 101 to 116 for E-L25. Rebinding experiments of purified E. coli proteins to the 5S RNA fragments led to the conclusion that E-L5 and E-L25 have secondary binding sites in the section 58 to 100, the primary binding site for E-L18. Since B. stearothermophilus proteins B-L5 and BL22 were found to interact with sequences 18 to 57 and 58 to 100 it was established that the thermophile proteins recognize and interact with RNA sequences similar to those of E. coli. Comparison of the E. coli 5S RNA sequence with those of other prokaryotic 5S RNAs reveals that the ribosomal proteins interact with the most conserved sections of the RNA.Paper number 12 on structure and function of 5S RNA.Preceding paper: Wrede, P. and Erdmann, V.A. Proc. Natl. Acad. Sci. USA 74, 2706–2709 (1977)     

The effect of Escherichia coli ribosomal protein S1 on the translational specificity of bacterial ribosomes

Ribosomes from Gram-negative bacteria such as Escherichia coli exhibit non-specific translation of bacterial mRNAs. That is, they are able to translate mRNAs from a variety of sources in a manner independent of the "strength" of the Shine-Dalgarno region, in contrast to ribosomes from many Gram-positive bacteria, such as Bacillus subtilis, which show specific translation in only being able to translate other Gram-positive mRNA, or mRNAs that have "strong" Shine-Dalgarno regions. There is an evolutionary correlation between the translational specificity and the absence of a protein analogous to E. coli ribosomal protein S1. The specificity observed with B. subtilis ribosomes is a function of their 30 S subunit which lacks S1; translation of Gram-negative mRNA can occur with heterologous ribosomes containing the 30 S subunit of E. coli ribosomes and the 50 S subunit of B. subtilis ribosomes. However, the addition of E. coli S1 alone to B. subtilis ribosome does not overcome their characteristic inability to translate mRNA from Gram-negative organisms. By contrast, the removal of S1 from E. coli ribosomes results in translational behavior similar to that shown by B. subtilis ribosomes in that the S1-depleted E. coli ribosomes can translate mRNA from Gram-positive sources in the absence of added S1, although addition of S1 stimulates further translation of such mRNAs by the E. coli ribosomes.     

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.     

The Escherichia coli 30S ribosomal subunit; an optimized three-dimensional fit between the ribosomal proteins and the 16S RNA.

We have generated a computerized fit between the 3-dimensional map of the E.coli 30S ribosomal proteins, as determined by neutron scattering, and the recently published 3-dimensional model for the 16S RNA. To achieve this, the framework of coordinates for RNA-protein cross-link sites on the phosphate backbone in the RNA model was related to the corresponding framework of coordinates for the mass centres of the proteins by a least squares fitting procedure. The resulting structure, displayed on a computer graphics system, gives the first complete picture of the E.coli 30S ribosomal subunit showing both the proteins and the double-helical regions of the RNA. The root mean square distance between cross-link sites and protein centres is 32 A. The position of the mass centre of the combined double-helical regions was calculated from the model and compared with the position of the mass centre of the complete set of proteins. The two centres are displaced relative to one another by 20 A in the model structure, in good agreement with the experimental value of 25 A found by neutron scattering.     

The binding site for ribosomal protein L2 within 23S ribosomal RNA of Escherichia coli.

Ribosomal protein L2 from Escherichia coli binds to and protects from nuclease digestion a substantial portion of 'domain IV' of 23S rRNA. In particular, oligonucleotides derived from the sequence 1757-1935 were isolated and shown to rebind specifically to protein L2 in vitro. Other L2-protected oligonucleotides, also derived from domain IV (i.e. from residues 1955-2010) did not rebind to protein L2 in vitro nor did others derived from domain I. Given that protein L2 is widely believed to be located in the peptidyl transferase centre of the 50S ribosomal subunit, these data suggest that domain IV of 23S rRNA is also present in that active site of the ribosomal enzyme.