Photoaffinity labeling of Escherichia coli ribosomes

Changes in ribosome function induced by protein kinase associated with ribosomes of Streptomyces collinus producing kirromycin

Protein kinase associated with ribosomes of streptomycetes phosphorylates 11 ribosomal proteins. Phosphorylation activity of protein kinase reaches its maximum at the end of exponential phase of growth. When (32)P-labeled cells from the end of exponential phase of growth were transferred to a fresh medium, after 2 h of cultivation ribosomal proteins lost more than 90% of (32)P and rate of polypeptide synthesis increases twice. Protein kinase cross-reacting with antibody raised against protein kinase C was partially purified from 1 M NH(4)Cl wash of ribosomes and used to phosphorylation of ribosomes. Phosphorylation of 50S subunits (L2, L3, L7, L16, L21, L23, and L27) had no effect on the integrity of subunits but affects association with 30 to 70S monosomes. In vitro system derived from ribosomal subunits was used to examine the activity of phosphorylated 50S at poly(U) translation. Replacement unphosphorylated 50S with 50S possessed of phosphorylated r-proteins leads to the reduction of polypeptide synthesis of about 52%. The binding of N-Ac[(14)C]Phe-tRNA to A-site of phosphorylated ribosomes is not affected but the rate of peptidyl transferase is more than twice lower than that in unphosphorylated ribosomes. These results provide evidence that phosphorylation of ribosomal proteins is involved in mechanisms regulating the translational system of Streptomyces collinus.

Characterization of the rplB gene from Streptomyces collinus and its protein product by mass spectrometry

Ribosomal protein L2 is the largest protein components of 50S subunits. The protein is implicated in peptidyl transferase activity and binds to functionally important domains of 23S rRNA. The rplB gene, which codes for ribosomal protein L2 was cloned from Streptomyces collinus. The gene rplB was isolated from BamHI fragment (3.0 kb) of chromosomal DNA possessing two partial and four complete ORF's in the order from 5' to 3': rplC, rplD, rplW, rplB, rpsS, and rplV. The gene organization corresponds to the S10 operon. Gene rplB (834 bp) encodes a polypeptide chain of 278 amino acids. The molecular mass calculated from genomic structure is 30.5 kDa and pI 11.87. Protein L2 is rich in positively charged amino acids (Arg 36, Lys 20, and His 11). N-terminal domain possesses topology similar to the oligonucleotide/oligosaccharide binding OB folds. The availability of genome sequence makes it possible to identify L2 protein by mass spectrometry, moreover it facilitates the characterization of its potential posttranslational modifications. To confirm the protein sequence derived from the rplB gene the tryptic peptides of L2 were analyzed by mass spectrometric techniques. The obtained data matched exactly with the results of DNA sequencing.

Histidine 229 in protein L2 is apparently essential for 50S peptidyl transferase activity

It has recently been suggested that peptidyl transferase activity is primarily a property of ribosomal RNA and that ribosomal proteins may act only as scaffolding. On the other hand, evidence from both photoaffinity labeling studies and reconstitution studies suggest that protein L2 may be functionally important for peptidyl transferase. In the work reported here, we reconstitute 50S subunits in which the H229Q variant of L2 replaces L2, with all other ribosomal components remaining unchanged, and determine the catalytic and structural properties of the reconstituted subunits. We observe that mutation of the highly conserved His 229 to Gin results in a complete loss of peptidyl transferase activity in the reconstituted 50S subunit. This is strong evidence for the direct involvement of L2 in ribosomal peptidyl transferase activity. Control experiments show that, though lacking peptidyl transferase activity, 50S subunits reconstituted with H229Q-L2 appear to be identical with 50S subunits reconstituted with wild-type L2 with respect to protein composition and 70S formation in the presence of added 30S subunits. Furthermore, as shown by chemical footprinting analysis, H229Q-L2 appears to bind 23S RNA in the same manner as wild-type L2. Thus, the effect of H229 mutation appears to be confined to an effect on peptidyl transferase activity, providing the most direct evidence for protein involvement in this function to date.

Peptidyl transferase and beyond

The peptidyl transferase center of the Escherichia coli ribosome encompasses a number of 50S-subunit proteins as well as several specific segments of the 23S rRNA. Although our knowledge of the role that both ribosomal proteins and 23S rRNA play in peptide bond formation has steadily increased, the location, organization, and molecular structure of the peptidyl transferase center remain poorly defined. Over the past 10 years, we have developed a variety of photoaffinity reagents and strategies for investigating the topography of tRNA binding sites on the ribosome. In particular, we have used the photoreactive tRNA probes to delineate ribosomal components in proximity to the 3' end of tRNA at the A, P, and E sites. In this article, we describe recent experiments from our laboratory which focus on the identification of segments of the 23S rRNA at or near the peptidyl transferase center and on the functional role of L27, the 50S-subunit protein most frequently labeled from the acceptor end of A- and P-site tRNAs. In addition, we discuss how these results contribute to a better understanding of the structure, organization, and function of the peptidyl transferase center.

Determination of peptide regions exposed at the surface of the bacterial ribosome with antibodies against synthetic peptides

We synthesized six peptides corresponding to regions that are predicted to be surface-exposed of the following ribosomal proteins: protein L2, positions (D263-K272); protein L5, positions (I136-G150); protein L25, positions (Q75-D90); protein S3, positions (Q222-K232) derived from Escherichia coli; and protein L2, positions (K257-K275), and protein S3, positions (R130-T150) from Bacillus stearothermophilus. These peptides were employed to raise ribosomal protein-cross-reactive antibodies. The anti-peptide antisera reacted specifically with their parent proteins, as demonstrated by immunoblotting experiments. In a competition assay proteins L2 from E. coli and B. stearothermophilus as well as proteins L5 and L25 from E. coli were found to be accessible to the respective anti-peptide antibodies in the 50S subunits, but not in 70S ribosomes, proving their location at the 50S interface which is covered by the 30S subunit in the 70S complex. Two of the anti-peptide antisera directed against sequences deduced from protein S3 of E. coli and B. stearothermophilus reacted with 30S subunits as well as with 70S ribosomes, demonstrating their location at the backside, which is exposed to solvent. Thus, by the strategy applied specific short peptide stretches were located at the surface of the ribosome.

Recombinant photoreactive tRNA molecules as probes for cross-linking studies

Photoreactive tRNA derivatives have been used extensively for investigating the interaction of tRNA molecules with their ligands and substrates. Recombinant RNA technology facilitates the construction of such tRNA probes through site-specific incorporation of photoreactive nucleosides. The general strategy involves preparation of suitable tRNA fragments and their ligation either to a photoreactive nucleotide or to each other. tRNA fragments can be prepared by site-specific cleavage of native tRNAs, or synthesized by enzymatic and chemical means. A number of photoreactive nucleosides suitable for incorporation into tRNA are presently available. Joining of tRNA fragments is accomplished either by RNA ligase or by DNA ligase in the presence of a DNA splint. The application of this methodology to the study of tRNA binding sites on the ribosome is discussed, and a model of the tRNA-ribosome complex is presented.

Saturable binding of halothane to rat brain synaptosomes

The hypothesis that volatile anesthetics act directly on or bind specifically to membrane proteins remains controversial. In earlier in situ electron probe microanalysis studies in cardiac muscle we showed preferential partitioning of halothane into mitochondria. To determine whether partitioning represents saturable binding or simple solubility, a photoaffinity labeling method was developed for halothane to examine binding in rat brain synaptosomes. Radioligand binding assays were then used to determine binding parameters for this important inhalational anesthetic. UV-light exposure of synaptosomes incubated with clinical concentrations of [14C]halothane resulted in sufficient labeling to allow characterization of binding sites. Analysis of saturation and competition curves showed that greater than 60% of [14C]halothane photolysis product binding to synaptosomes was specific, with low affinity (Kd = 0.49 +/- 0.16 mM) and high binding site concentration (Bmax = 1.87 +/- 0.75 nmol/mg of protein). Halothane photoaffinity labeling was partially inhibited by isoflurane (20%), chloroform (44%), 2-bromotrifluoroethane (20%), and dichlorotrifluoroethane (20%) but not by ethanol. The Kd measured with this photoaffinity approach is similar to the concentration of halothane required to produce anesthesia in rats.

Identification of the Escherichia coli 30S ribosomal subunit protein neighboring mRNA during initiation of translation

To identify the proteins of the 30S ribosomal subunit of E coli that neighbor mRNA in the ternary initiation complex (mRNA*30S subunit*tRNA(fMet), we used an affinity cross-linking approach in which photoactivated groups were attached to different positions along the mRNA chain. A series of mini-genes originating from the 5'-end region of the cro gene of lambda bacteriophage were constructed as templates for mini-mRNA synthesis. Two strategies were used to introduce photo-reactive agents into the message. According to the first, two transcripts were isolated from E coli and chemically derivatized at their 5'-ends with a photoinducible diaziril group. One of these messages allowed for localization of the 5'-end of the Shine-Dalgarno sequence while the other one allowed for labeling of the ribosome at the 5'-end side of the initiation AUG codon in the P site. According to the second approach, 5-azidouridine (5N3U) was randomly incorporated into mRNA transcripts during a T7 RNA polymerase catalyzed reaction by using a mixture of 5N3UTP and UTP. A message that had U residues at either -4, -3, -1, +2 and +14, +19, +20 positions was used (A from cro AUG is +1). Whereas cross-links with the 5N3U transcripts were essentially 'zero-length', the 5'-derivatized transcripts were covalently attached to ribosomal components about 14 A from the 5'-end. We found that proteins S1, S7, S5, S3 and S4 compose, or were close to, the ribosomal mRNA-binding site.(ABSTRACT TRUNCATED AT 250 WORDS)

A consonant model of the tRNA-ribosome complex during the elongation cycle of translation

Chemical and photochemical affinity techniques have been used extensively to determine the positions of the tRNA binding sites on the Escherichia coli ribosome. Recent advances in our understanding of ribosome structure and function prompted us to critically review the data that have accumulated on tRNA-ribosome cross-links. As a result, we propose a new model of the tRNA-ribosome complex that accounts for nearly all of the pertinent evidence.

A deletion mutation at the 5' end of Escherichia coli 16S ribosomal RNA

A deletion of five nucleotides was introduced at the 5' end of the Escherichia coli 16S rRNA gene cloned in an appropriate vector under control of a T7 promoter. The 16S rRNA generated by in vitro transcription could be assembled into 30S subunits. The deletion did not affect the efficiency of translation of natural messengers and the correct selection of the reading frame. However, it reduced the binding of the messengers, which suggests that the 5' end of 16S rRNA is located on the pathway followed by the messengers on the 30S subunits. The deletion also restricted the stimulation of misreading by streptomycin in a poly(U)-directed system. This is in accord with the proximity of the 5' end of 16S rRNA to proteins S4, S5 and S12, which are known to be involved in the control of translational accuracy.

Reconstitution of Escherichia coli 50S ribosomal subunits containing puromycin-modified L23: functional consequences

In previous work we have shown that both puromycin [Weitzmann, C. J., & Cooperman, B. S. (1985) Biochemistry 24, 2268-2274] and p-azidopuromycin [Nicholson, A. W., Hall, C. C., Strycharz, W. A., & Coooperman, B. S. (1982) Biochemistry 21, 3809-3817] site specifically photoaffinity label protein L23 to the highest extent of any Escherichia coli ribosomal protein. In this work we demonstrate that L23 that has been photoaffinity labeled within a 70S ribosome by puromycin (puromycin-L23) can be separated from unmodified L23 by reverse-phase high-performance liquid chromatography (RP-HPLC) and further that puromycin-L23 can reconstitute into 50S subunits when added in place of unmodified L23 to a reconstitution mixture containing the other 50S components in unmodified form. We have achieved a maximum incorporation of 0.5 puromycin-L23 per reconstituted 50S subunit. As compared with reconstituted 50S subunits either containing unmodified L23 or lacking L23, reconstituted 50S subunits containing 0.4-0.5 puromycin-L23 retain virtually all (albeit low) peptidyl transferase activity but only 50-60% of mRNA-dependent tRNA binding stimulation activity. We conclude that although L23 is not directly at the peptidyl transferase center, it is sufficiently close that puromycin-L23 can interfere with tRNA binding. This conclusion is consistent with a number of other experiments placing L23 close to the peptidyl transferase center but is difficult to reconcile with immunoelectron microscopy results placing L23 near the base of the 50S subunit on the side facing away from the 30S subunit [Hackl, W., & Stöffler-Meilicke, M. (1988) Eur. J. Biochem. 174, 431-435].