Location of protein S1 of Escherichia coli ribosomes at the ''A''-site of the codon binding site. Affinity labeling studies with a 3''-modified A-U-G analog.

An affinity analog with a 5-bromoacetamido uridine 5'-phosphate moiety bonded to the 3' end of A-U-G has been prepared with the aid of polynucleotide phosphorylase. This 3'-modified, chemically reactive A-U-G analog was used to probe the ribosomal codon binding site. The yield of the reaction depended strongly on the ribosomal source and was sensitive to salt-washing ribosomes. The major crosslinking product was identified to be protein S1. Since the reaction of this 3'-modified A-U-G programmed ribosomes for Met-tRNA-Met-M binding, it is concluded that protein S1 is located at or near the 3'-side of the ribosomal codon binding site.     

Comparison of the reactions of chemically reactive analogs of U-G-A and of A-U-G with ribosomes of Escherichia coli.

The chemically reactive analog of U-G-A, 5'-(4-(Bromo-[2-14C] acetamido) phenylphospho) - uridylyl-(3'-5') - guanylyl-(3'-5') adenosine has a 20 fold lower affinity to 70S ribosomes than the corresponding analog of A-U-G though the U-G-A analog also preferentially reacts with protein S18 of 70S ribosomes. This reaction programs ribosomes for EF-T dependent Trp-tRNATrp-suIII binding. Therefore, it is concluded that this protein is part of the A'-site of the ribosomal codon binding site. Reaction of the U-G-A analog with 30S subunits lead to a predominant crosslinking of U-G-A to proteins S4 and S18. In contrast, a comparable reaction of the A-U-G analog with 30S subunits lead to a predominant crosslinking of A-U-G to proteins S4 and S12 (Pongs, O., Stoffler, G.A., Lanka, E., (1975) J. Mol. Biol. 99, 301). Since protein S12 is located at the 'P' site of the ribosomal codon binding site, it is proposed that the U-G-A analog does not bind at this site.     

Suppression of the Escherichia coli rpoH opal mutation by ribosomes lacking S15 protein.

Several suppressors (suhD) that can specifically suppress the temperature-sensitive opal rpoH11 mutation of Escherichia coli K-12 have been isolated and characterized. Unlike the parental rpoH11 mutant deficient in the heat shock response, the temperature-resistant pseudorevertants carrying suhD were capable of synthesizing sigma 32 and exhibiting partial induction of heat shock proteins. These strains were also cold sensitive and unable to grow at 25 degrees C. Genetic mapping and complementation studies permitted us to localize suhD near rpsO (69 min), the structural gene for ribosomal protein S15. Ribosomes and polyribosomes prepared from suhD cells contained a reduced level (ca. 10%) of S15 relative to that of the wild type. Cloning and sequencing of suhD revealed that an IS10-like element had been inserted at the attenuator-terminator region immediately downstream of the rpsO coding region. The rpsO mRNA level in the suhD strain was also reduced to about 10% that of wild type. Apparently, ribosomes lacking S15 can actively participate in protein synthesis and suppress the rpoH11 opal (UGA) mutation at high temperature but cannot sustain cell growth at low temperature.     

G1401: a keystone nucleotide at the decoding site of Escherichia coli 30S ribosomes.

16S ribosomal RNA contains three highly conserved single-stranded regions. Centrally located in one of these regions is the C1400 residue. Zero-length cross-linking of this residue to the anticodon of ribosome-bound tRNA showed that it was at or near the ribosomal decoding site [Ehresmann, C., Ehresmann, B., Millon, R., Ebel, J-P., Nurse, K., & Ofengand, J. (1984) Biochemistry 23, 429-437]. To assess the functional significance of sequence conservation of rRNA in the vicinity of this functionally important site, a series of site-directed mutations in this region were constructed and the effects of these mutations on the partial reactions of protein synthesis determined. Mutation of C1400 or C1402 to any other base only moderately affected a set of in vitro protein synthesis partial reactions. However, any base change from the normal G1401 residue blocked all of the tested ribosomal functions. This was also true for the deletion of G1401. Deletion of C1400 or C1402 had more complex effects. Whereas subunit association was hardly affected, 30S initiation complex formation was blocked by deletion of C1400 but much less so by deletion of C1402. Alternatively, tRNA binding to the ribosomal A site was more strongly affected by deletion of C1402 than by deletion of C1400. P site binding was inhibited by either deletion. HPLC analysis of the in vitro reconstituted mutant ribosomes showed that none of the functional effects were due to the absence or gross reduction in amount of any ribosomal protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of the 30 S protein adjacent to peptidyl transferase catalytic center of Escherichia coli ribosomes

Iodoacetylphenylalanyl-tRNA^Phe was used as an affinity label to localize the ribosomal components involved in the peptidyl transferase catalytic center of Escherichia coli ribosomes. When labeling was carried out at pH 5.0, the affinity label could specifically label the ribosomal components which comprise the catalytic center. Analysis of ribosomal proteins which had reacted with the affinity label revealed that a 30 S subunit protein, S 20, was located at or near to the ribosomal binding site of the 3-terminus of aminoacyl- or peptidyl-tRNA.     

Conformational studies of Escherichia coli ribosomes with the use of acridine orange as a probe

The interaction of E. coli vacant ribosomes with acridine orange (AO) was studied, to obtain conformational information about rRNAs in ribosomes. Acridine orange binds to an RNA in two different modes: cooperative outside binding with stacking of bound AO's and intercalation between nucleotide bases. Free 16S and 23S rRNAs have almost identical affinities to AO. At 1 mM Mg2+, AO can achieve stacking binding on about 40% of rRNA phosphate groups. The number of stacking binding sites falls to about 1/3 in the 30S subunit in comparison with free 16S rRNA. In the 50S subunit, the number of stacking binding sites is only 1/5 in comparison with free 23S rRNA. Mg2+ ions are more inhibitory for the binding of AO to ribosomes than to free rRNAs. The strength of stacking binding appears to be more markedly reduced by Mg2+ in active ribosomes than in rRNAs. "Tight couple" 70S particles are less accessible for stacking binding than free subunits. The 30S subunits that have irreversibly lost the capability for 70S formation under low Mg2+ conditions have an affinity to AO that is very different from that of active 30S but similar to that of free rRNA, though the number of stacking binding sites is little changed by the inactivation. 70S and 30S ribosomes with stacking bound AO's have normal sedimentation constants, but the 50S subunits reversibly form aggregates.     

Interaction of N-acetyl-phenylalanyl-tRNAPhe with 70S ribosomes of Escherichia coli.

The interaction of N--Acetyl--Phe--tRNA Phe with 70 S ribosomes is a reversible process in the absence as well as in the presence of messenger. The equilibrium binding constants of these interactions were measured at different magnesium concentrations and temperatures and thermodynamical quantities computed. The enthalpy of the formation of complexes with the P site of ribosomes is larger by 6,000 cal/mol in the presence of poly (U) than in the presence of poly (C) or in total absence of messenger. Free energy differences are rather small, the association constants differ less than one order of magnitude. The association constant of N--Acetyl--Phe--tRNA Phe with the A site of ribosomes is 30--50 times lower than with the P site even in the presence of poly (U).     

Identification of neighbouring proteins by cross-linking of intact 70 S ribosomes from Escherichia coli

70 S ribosomes from Escherichia coli have been reacted with the bifunctional reagent 1,4-phenyldiglyoxal under near physiological conditions. As a result of the cross-linking reaction a number of high-molecular-weight protein fractions with altered electrophoretic mobility could be isolated. A new chemical procedure has been introduced to reverse the cross-links between proteins at least partially. The cleavage reaction did not affect the gel electrophoretic mobility of the proteins. Thus a direct identification of cross-linked proteins using one- or two-dimensional gels was made possible. Two protein trimers, S3-S4-S5 and L1-S4-S5, as well as five protein dimers, S3-S4, L6-L7/12, L10-L7/12, S9-L19 and L18-L19 could be identified as close neighbours in the E. coli 70 S ribosome. The protein pairs S9-L19 and L18-L19 had previously not been identified as near neighbours using cross-linking studies.     

Single protein omission reconstitution studies of tetracycline binding to the 30S subunit of Escherichia coli ribosomes

In previous work we showed that on photolysis of Escherichia coli ribosomes in the presence of [3H]tetracycline (TC) the major protein labeled is S7, and we presented strong evidence that such labeling takes place from a high-affinity site related to the inhibitory action of TC [Goldman, R. A., Hasan, T., Hall, C. C., Strycharz, W. A., & Cooperman, B. S. (1983) Biochemistry 22, 359-368]. In this work we use single protein omission reconstitution (SPORE) experiments to identify those proteins that are important for high-affinity TC binding to the 30S subunit, as measured by both cosedimentation and filter binding assays. With respect to both sedimentation coefficients and relative Phe-tRNAPhe binding, the properties of the SPORE particles we obtain parallel very closely those measured earlier [Nomura, M., Mizushima, S., Ozaki, M., Traub, P., & Lowry, C. V. (1969) Cold Spring Harbor Symp. Quant. Biol. 34, 49-61], with the exception of the SPORE particle lacking S13. A total of five proteins, S3, S7, S8, S14, and S19, are shown to be important for TC binding, with the largest effects seen on omission of proteins S7 and S14. Determination of the protein compositions of the corresponding SPORE particles demonstrates that the observed effects are, for the most part, directly attributable to the omission of the given protein rather than reflecting an indirect effect of omitting one protein on the uptake of another. A large body of evidence supports the notion that four of these proteins, S3, S7, S14, and S19, are included, along with 16S rRNA bases 920-1396, in one of the major domains of the 30S subunit.     

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.     

Structure of the Escherichia coli S10 ribosomal protein operon.

The complete structure of the Escherichia coli S10 ribosomal protein operon is presented. Based on the DNA sequence, the deduced order of the 11 genes in the operon is rpsJ, rplC, rplD, rplW, rplB, rpsS, rplV, rpsC, rplP, rpmC, rpsQ. The estimated transcribed length of the operon is 5181 base pairs. Putative sequences involved in ribosome binding are discussed. The DNA sequence data corrects several errors in previously determined protein sequence data.     

Fragment of protein L18 from the Escherichia coli ribosome that contains the 5S RNA binding site.

A fragment of ribosomal protein L18 was prepared by limited trypsin digestion of a specific complex of L18 and 5S RNA. It was characterised for sequence and the very basic N-terminal region of the protein was found to be absent. No smaller resistant fragments were produced. 5S RNA binding experiments indicated that the basic N-terminal region, from amino acid residues 1 to 17, was not important for the L18-5S RNA association. Under milder trypsin digestion conditions three resistant fragments were produced from the free protein. The largest corresponded to that isolated from the complex. The smaller ones were trimmed slightly further at both N- and C-terminal ends. These smaller fragments did not reassociate with 5S RNA. It was concluded on the basis of the trypsin protection observations and the 5S RNA binding results that the region extending from residues 18 to 117 approximates to the minimum amount of protein required for a specific and stable protein-RNA interaction. The accessibility of the very basic N-terminal region of L18, in the L18-5S RNA complex, suggests that it may be involved, in some way, in the interaction of 5S RNA with 23S RNA.     

mRNA-binding site of ribosomes at different stages of translation. II. Affinity modification of Escherichia coli ribosomes bya benzylidene derivative of AUGU6 in pre- and post-translation complexes

Affinity labeling of E. coli ribosomes with the 2',3'-O-[4-(N-2-chloroethyl)-N-methyl-amino]benzylidene derivative of AUGU6 (AUGU6-[14C]CHRCl) was studied within the pretranslocational complex ribosome.AUGU6[14C]CHRCl.tRNA(fMet)(P-site).fMetPhe-tR NA(Phe)(A-site) and posttranslocational complex ribosome.AUGU6[14C]CHRCl.fMetPhe-tRNA(Phe)(P-site). Both 30S and 50S subunits were labeled within these complexes, but the extent of 30S subunit modification was 6-8-fold higher than those for 50S subunit. Ribosomal proteins of both subunits were found to be labeled preferentially. Proteins S1, S5, S11, L1 were identified to be crosslinked with AUGU6[14C]CHRCl within the pretranslocational complex and S7--within the posttranslocational complex from the data of two-dimensional electrophoresis in the polyacrylamide gel.     

Identification of protein S 1 at the messenger RNA binding site of the Escherichia coli ribosome

Poly-4-thiouridylic acid acts as messenger RNA for polyphenylalanine synthesis in an $\text{in vitro}$ protein synthesizing system. When a complex consisting of ribosomes, poly-4-thiouridylic acid and Phe-tRNA is irradiated at 300 to 400 nm, covalent bonds between this messenger RNA and protein S 1 are formed.     

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.     

Affinity labeling at the A-site of Escherichia coli ribosomes by a non-hydrolyzable gamma-amide analog of GTP

gamma-Amides of GTP and affinity and photoaffinity derivatives of gamma-amides of GTP: gamma-anilide of GTP, gamma-(4-azido)anilide of GTP, gamma-[N-(4-azidobenzyl)-N-methyl]amide of GTP, gamma[4-N-(2-chloroethyl)-N-methylaminobenzyl]amide of GTP and gamma-[4-N-(2-oxoethyl)-N-methylaminobenzyl]amide of GTP substituted efficiently for GTP in the EF-Tu-dependent transfer of aminoacyl-tRNA to the ribosome but, in contrast to GTP, they were not hydrolyzed in this process. They represent a new class of non-hydrolyzable GTP analogs with preserved gamma-phosphodiester bond. The radioactive analog of GTP: gamma-[4-N-(2-chloroethyl)-N-methylamino[14C]benzyl]amide of GTP was used as an affinity labeling probe for the identification of components of the GTPase center formed in the EF-Tu-dependent transfer reaction of aminoacyl-tRNA to the ribosomal A-site. Within a six-component complex of poly(U)-programmed E. coli ribosomes with elongation factor Tu, Phe-tRNA(Phe) (at the A-site), tRNA(Phe) (at the P-site) and the [14C]GTP analog, mainly the ribosomal 23S RNA and to a lesser extent the ribosomal proteins L17, L21, S16, S21 and the ribosomal 16S RNA were labeled by the reagent. No significant modification of EF-Tu was detected.