Genetic studies of the ribosomal proteins in Escherichia coli. XI. Mapping of the genes for L21, L27, S15 and S21 by using hybrid bacteria and over-production of these proteins in the merodiploid strains.

Summary Host capacity for growth of single-stranded DNA phages was investigated with several replication mutants of E. coli. In dnaL708, dnaM709 and dnaS707 mutants, multiplication of K was not restricted even at 42°C. In dnaM710 cells, however, growth of K was severely affected at 42°C but not at 33°C. Upon infection of K, parental replicative form was synthesized at the restrictive temperature, whereas subsequent step (replication of progeny replicative form) was blocked in the dnaZ strain. Growth of X174 and 3, as tested by transfection, was also thermosensitive in the dnaM710 mutant but not in the dnaL708, dnaM709 and dnaS707 strains. In contrast with , microvirid phages could grow in E. coli cells bearing the groPC259, groPC756 or seg-2 mutation.This paper is number 15 in the series entitled Sensivity of Escherichia coli to Viral Nucleic Acid     

Binding sites for ribosomal proteins S8 and S15 in the 16 S RNA of Escherichia coli.

A fragment of the 16 S ribosomal RNA of Escherichia coli that contains the binding sites for proteins S8 and S15 of the 30 S ribosomal subunit has been isolated and characterized. The RNA fragment, which sediments as 5 S, was partially protected from pancreatic RNAase digestion when S15 alone, or S8 and S15 together, were bound to the 16 S RNA. Purified 5 S RNA was shown to reassociate specifically with protein S15 by analysis of binding stoichiometry. Although interaction between the fragment and protein S8 alone could not be detected, the 5 S RNA selectively bound both S8 and S15 when incubated with an unfractionated mixture of 30-S subunit proteins. Nucleotide sequence analysis demonstrated that the 5 S RNA arises from the middle of the 16 S RNA molecule and encompasses approximately 150 residues from Sections C, C'1 and C'2. Section C consists of a long hairpin loop with an extensively hydrogen-bonded stem and is contiguous with Section C'1. Sections C'1 and C'2, although not contiguous, are highly complementary and it is likely that together they comprise the base-paired stem of an adjacent loop.     

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.     

Positions of proteins S6, S11 and S15 in the 30 S ribosomal subunit of Escherichia coli

A map of the positions of 12 of the 21 proteins of the 30 S ribosomal subunit of Escherichia coli (S1, S3, S4, S5, S6, S7, S8, S9, S10, S11, S12 and S15), based on neutron scattering, is presented and discussed. Estimates for the radii of gyration of these proteins in situ are also obtained. It appears that many ribosomal proteins have compact configurations in the particle.     

Interaction of ribosomal proteins S6, S8, S15 and S18 with the central domain of 16 S ribosomal RNA from Escherichia coli

The co-operative interaction of 30 S ribosomal subunit proteins S6, S8, S15 and S18 with 16 S ribosomal RNA from Escherichia coli was studied by (1) determining how the binding of each protein is influenced by the others and (2) characterizing a series of protein-rRNA fragment complexes. Whereas S8 and S15 are known to associate independently with the 16 S rRNA, binding of S18 depended upon S8 and S15, and binding of S6 was found to require S8, S15 and S18. Ribonucleoprotein (RNP) fragments were derived from the S8-, S8/S15- and S6/S8/S15/S18-16 S rRNA complexes by partial RNase hydrolysis and isolated by electrophoresis through Mg2+-containing polyacrylamide gels or by centrifugation through sucrose gradients. Identification of the proteins associated with each RNP by gel electrophoresis in the presence of sodium dodecyl sulfate demonstrated the presence of S8, S8 + S15 and S6 + S8 + S15 + S18 in the corresponding fragment complexes. Analysis of the rRNA components of the RNP particles confirmed that S8 was bound to nucleotides 583 to 605 and 624 to 653, and that S8 and S15 were associated with nucleotides 583 to 605, 624 to 672 and 733 to 757. Proteins S6, S8, S15 and S18 were shown to protect nucleotides 563 to 605, 624 to 680, 702 to 770, 818 to 839 and 844 to 891, which span the entire central domain of the 16 S rRNA molecule (nucleotides 560 to 890). The binding site for each protein contains helical elements as well as single-stranded internal loops ranging in size from a single bulged nucleotide to 20 bases. Three terminal loops and one stem-loop structure within the central domain of the 16 S rRNA were not protected in the four-protein complex. Interestingly, bases within or very close to these unprotected regions have been shown to be accessible to chemical and enzymatic probes in 30 S subunits but not in 70 S ribosomes. Furthermore, nucleotides adjacent to one of the unprotected loops have been cross-linked to a region near the 3' end of 16 S rRNA. Our observations and those of others suggest that the bases in this domain that are not sequestered by interactions with S6, S8, S15 or S18 play a role involved in subunit association or in tertiary interactions between portions of the rRNA chain that are distant from one-another in the primary structure.(ABSTRACT TRUNCATED AT 400 WORDS)     

Ribosomal proteins L15 and L16 are mere late assembly proteins of the large ribosomal subunit. Analysis of an Escherichia coli mutant lacking L15

The (minus L15) character from the Escherichia coli strain AM16.98 was transduced to an RNase-deficient strain in order to enable a reconstitution analysis. The following results were obtained. 1) The strain lacking L15 showed a 2-3-fold prolonged generation time and the 70 S ribosomes a reduced tendency toward dissociation. 2) Active particles could not be reconstituted unless L15 was added. Addition of L15 regained activity, even if L15 was added after the two-step procedure during a third incubation. However, a modification of the standard two-step reconstitution procedure (lowering NH4+ from 400 to 240 mM and the incubation temperature of the second step from 50 to 47 degrees C) yielded 100% active particles in the absence of L15. Active particles could be formed which even lacked L15, L16, and L30. Addition of either L15 or L16 accelerated the formation of active particles in the second step by a factor of five, and both proteins together by a factor of more than 20. 3) The activation energy of the rate-limiting step of the second incubation was surprisingly reduced for about 20 kcal/mol in the absence of L15, although the corresponding rates were two to five times slower. We conclude 1) that L15 and L16 are late assembly proteins which accelerate the formation of active particles during the late assembly but are neither needed for the early assembly nor essential for ribosomal functions; 2) that some routes of the late assembly (e.g. incorporation of L16) are changing their significance depending on the NH4+ concentration and the absence and presence of L15; and 3) that different reactions are rate limiting during the second step incubation in the presence and absence of L15, respectively, and that the corresponding reaction rates exhibit a different temperature dependence.     

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.     

Translational autocontrol of the Escherichia coli ribosomal protein S15

When rpsO, the gene encoding the ribosomal protein S15 in Escherichia coli, is carried by a multicopy plasmid, the mRNA synthesis rate of S15 increases with the gene dosage but the rate of synthesis of S15 does not rise. A translational fusion between S15 and beta-galactosidase was introduced on the chromosome in a delta lac strain and the expression of beta-galactosidase studied under different conditions. The presence of S15 in trans represses the beta-galactosidase level five- to sixfold, while the synthesis rate of the S15-beta-galactosidase mRNA decreases by only 30 to 50%. These data indicate that S15 is subject to autogenous translational control. Derepressed mutants were isolated and sequenced. All the point mutations map in the second codon of S15, suggesting a location for the operator site that is very near to the translation initiation codon. However, the creation of deletion mutations shows that the operator extends into the 5' non-coding part of the message, thus overlapping the ribosome loading site.     

The production of anti-hexapeptide antibodies which recognize the S7, L6 and L13 ribosomal proteins of Escherichia coli.

Here we report the synthesis of the N-terminal hexapeptide H-Pro-Arg-Arg-Arg-Val-Ile-OH of the E. coli ribosomal protein S7. the C-terminal hexapeptide H-Lys-Glu-Ala-Lys-Lys-Lys-OH of L6 and the C-terminal hexapeptide H-Pro-Gln-Val-Leu-Asp-Ile-OH of L13. All peptides were prepared by SPPS following the Fmoc-strategy, using DIC/HOBt and/or HBTU as coupling reagents and 2-chlorotrityl chloride resin as the solid support. The carrier linked synthetic peptides were injected into rabbits and elicited an anti-peptide response. These anti-hexapeptide antibodies were found to recognize the corresponding peptides and proteins.     

The gene for ribosomal protein S21, rpsU, maps close to dnaG at 66.5 min on the Escherichia coli chromosomal linkage map.

Anaerobic suspensions of Alteromonas haloplanktis accumulated alpha-aminoisobutyric acid, by a sodium-dependent process, in response to an artificially imposed membrane potential in the presence or absence of a transmembrane chemical gradient of sodium. These results suggest that the transport of alpha-aminoisobutyrate by this organism occurs via Na+-substrate symport.     

Dynamics inherent in helix 27 from Escherichia coli 16S ribosomal RNA

The original interpretation of a series of genetic studies suggested that the highly conserved Escherichia coli 16S ribosomal RNA helix 27 (H27) adopts two alternative secondary structure motifs, the 885 and 888 conformations, during each cycle of amino acid incorporation. Recent crystallographic and genetic evidence has called this hypothesis into question. To ask whether a slippery sequence such as that of H27 may harbor inherent conformational dynamics, we have designed a series of model RNAs based on E. coli H27 for in vitro physicochemical studies. One-dimensional (1)H NMR spectroscopy demonstrates that both the 885 and 888 conformations are occupied to approximately the same extent (f(888) = 0.427 +/- 0.04) in the native H27 sequence at low pH (6.4) and low ionic strength (50 mM NaCl). UV irradiation assays conducted under conditions analogous to those used for assays of ribosomal function (pH 7.5 and 20 mM MgCl(2)) suggest that nucleotides 892 and 905, which are too far apart in the known 885 crystal structures, can approach each other closely enough to form an efficient cross-link. The use of a fluorescence resonance energy transfer (FRET)-labeled RNA together with a partially complementary DNA oligonucleotide that induces a shift to the 888 conformation shows that H27 interchanges between the 885 and 888 conformations on the millisecond time scale, with an equilibrium constant of 0.33 +/-0.12. FRET assays also show that tetracycline interferes with the induced shift to the 888 conformation, a finding that is consistent with crystallographic localization of tetracycline bound to the 885 conformation of H27 in the 30S ribosomal subunit. Taken together, our data demonstrate the innate tendency of an isolated H27 to exist in a dynamic equilibrium between the 885 and 888 conformations. This begs the question of how these inherent structural dynamics are suppressed within the context of the ribosome.     

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 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.