Binding of erythromycin to the 50S ribosomal subunit is affected by alterations in the 30S ribosomal subunit

Ribosomal Proteins in the Spotlight

The assignment of specific ribosomal functions to individual ribosomal proteins is difficult due to the enormous cooperativity of the ribosome; however, important roles for distinct ribosomal proteins are becoming evident. Although rRNA has a major role in certain aspects of ribosomal function, such as decoding and peptidyl-transferase activity, ribosomal proteins are nevertheless essential for the assembly and optimal functioning of the ribosome. This is particularly true in the context of interactions at the entrance pore for mRNA, for the translation-factor binding site and at the tunnel exit, where both chaperones and complexes associated with protein transport through membranes bind.

Polypeptide chain termination and stop codon readthrough on eukaryotic ribosomes

During protein translation, a variety of quality control checks ensure that the resulting polypeptides deviate minimally from their genetic encoding template. Translational fidelity is central in order to preserve the function and integrity of each cell. Correct termination is an important aspect of translational fidelity, and a multitude of mechanisms and players participate in this exquisitely regulated process. This review explores our current understanding of eukaryotic termination by highlighting the roles of the different ribosomal components as well as termination factors and ribosome-associated proteins, such as chaperones.

Multiple defects in translation associated with altered ribosomal protein L4

The ribosomal proteins L4 and L22 form part of the peptide exit tunnel in the large ribosomal subunit. In Escherichia coli, alterations in either of these proteins can confer resistance to the macrolide antibiotic, erythromycin. The structures of the 30S as well as the 50S subunits from each antibiotic resistant mutant differ from wild type in distinct ways and L4 mutant ribosomes have decreased peptide bond-forming activity. Our analyses of the decoding properties of both mutants show that ribosomes carrying the altered L4 protein support increased levels of frameshifting, missense decoding and readthrough of stop codons during the elongation phase of protein synthesis and stimulate utilization of non-AUG codons and mutant initiator tRNAs at initiation. L4 mutant ribosomes are also altered in their interactions with a range of 30S-targeted antibiotics. In contrast, the L22 mutant is relatively unaffected in both decoding activities and antibiotic interactions. These results suggest that mutations in the large subunit protein L4 not only alter the structure of the 50S subunit, but upon subunit association, also affect the structure and function of the 30S subunit.

Genetic and culture-based approaches for detecting macrolide resistance in Chlamydia pneumoniae

Three clinical Chlamydia pneumoniae isolates for which the MIC of azithromycin increased after treatment were investigated for genetic evidence of macrolide resistance. Attempts to induce antibiotic resistance in vitro were made. No genetic mechanism was identified for the phenotypic change in these C. pneumoniae isolates. No macrolide resistance was obtained in vitro.

The polypeptide tunnel system in the ribosome and its gating in erythromycin resistance mutants of L4 and L22

Variations in the inner ribosomal landscape determining the topology of nascent protein transport have been studied by three-dimensional cryo-electron microscopy of erythromycin-resistant Escherichia coli 70S ribosomes. Significant differences in the mouth of the 50S subunit tunnel system visualized in the present study support a simple steric-hindrance explanation for the action of the drug. Examination of ribosomes in different functional states suggests that opening and closing of the main tunnel are dynamic features of the large subunit, possibly accompanied by changes in the L7/L12 stalk region. The existence and dynamic behavior of side tunnels suggest that ribosomal proteins L4 and L22 might be involved in the regulation of a multiple exit system facilitating cotranslational processing (or folding or directing) of nascent proteins.

Peptide environment of the peptidyl transferase center from Escherichia coli 70 S ribosomes as determined by thermoaffinity labeling with dihydrospiramycin

In an attempt to gain information about the peptidyl transferase center at the peptide level we cross-linked the spiramycin derivative dihydrospiramycin to its functional binding site in the 70 S ribosome of Escherichia coli. In this manner ribosomal proteins S12, S14, L17, L18, L27 and L35 were found specifically affinity-labeled. Proteolytic fragmentation of these proteins, separation by C18 reversed-phase high performance liquid chromatography of the peptide mixtures, and subsequent sequence analysis of labeled peptides revealed peptide regions at positions Ala1-Lys9 and Tyr116-Lys119 of S12, Leu47-Asp53 of protein S14, Ser6-Lys35 of protein L17, Ala57-Lys63 of protein L18, Ala5-Lys18 and Val66-Lys71 of protein L27, and Thr5-Lys11 of protein L35. This approach is a valuable tool to characterize the binding site of spiramycin as well as the peptidyl transferase center at the molecular level.

Erythromycin inhibits the assembly of the large ribosomal subunit in growing Escherichia coli cells

Erythromycin and other macrolide antibiotics have been examined for their effects on ribosome assembly in growing Escherichia coli cells. Formation of the 50S ribosomal subunit was specifically inhibited by erythromycin and azithromycin. Other related compounds tested, including oleandomycin, clarithromycin, spiramycin, and virginiamycin M1, did not influence assembly. Erythromycin did not promote the breakdown of ribosomes formed in the absence of the drug. Two erythromycin-resistant mutants with alterations in ribosomal proteins L4 and L22 were also examined for an effect on assembly. Subunit assembly was affected in the mutant containing the L22 alteration only at erythromycin concentrations fourfold greater than those needed to stop assembly in wild-type cells. Ribosomal subunit assembly was only marginally affected at the highest drug concentration tested in the cells that contained the altered L4 protein. These novel results indicate that erythromycin has two effects on translation, preventing elongation of the polypeptide chain and also inhibiting the formation of the large ribosomal subunit.

Increased kasugamycin sensitivity in Escherichia coli caused by the presence of an inducible erythromycin resistance (erm) gene of Streptococcus pyogenes

An inducible erythromycin resistance gene (erm) of Streptococcus pyogenes was introduced into Escherichia coli by transformation with a plasmid. The recipient E. coli cells were either kasugamycin sensitive (wildtype) or kasugamycin resistant (ksgA). The MIC values of erythromycin increased from 150 micrograms/ml to greater than 3000 micrograms/ml for E. coli. An extract of transformed cells, particularly a high-salt ribosomal wash, contained an enzyme that was able to methylate 23S rRNA from untransformed cells in vitro; however, 23S rRNA from transformed cells was not a substrate for methylation by such an extract. 165 rRNA and 30S ribosomal subunits of either the wild type or a kasugamycin resistant (ksgA) mutant were not methylated in vitro. Transformation of E. coli by the erm-containing plasmid led to a reduction of the MIC values for kasugamycin. This happened in wild-type as well as in ksgA cells. However, in vitro experiments with purified ksgA encoded methylase demonstrated that also in erm transformed E. coli, the ksgA encoded enzyme was active in wild-type, but not in ksgA cells. It was also shown by in vitro experiments that ribosomes from erm ksgA cells have become sensitive to kasugamycin. Our experiments show that in vivo methylation of 23S rRNA, presumably of the adenosine at position 2058, leads to enhanced resistance to erythromycin and to reduced resistance to kasugamycin. This, together with previous data, argues for a close proximity of the two sites on the ribosome that are substrates for adenosine dimethylation.

About the specificity of photoinduced affinity labeling of Escherichia coli ribosomes by dihydrorosaramicin, a macrolide related to erythromycin

Photoactivation of the [3H]dihydrorosaramicin chromophore at a wavelength above 300 nm allows the covalent attachment of the macrolide antibiotic to the bacterial ribosome. Bidimensional electrophoresis shows that the radioactivity is mainly associated with proteins L1, L5, L6, L15, L18, L19, S1, S3, S4, S5 and S9. When photoincorporation of the drug is conducted in the presence of puromycin as effector of [3H]dihydrorosaramicin-binding sites, a decrease in the labeling of most proteins is observed, except for L18 and L19, which are radiolabeled to a larger extent. These results allow us to speculate that L18 and L19 belong to the high-affinity binding site of rosaramicin antibiotic.

Ribosome structure: binding site of macrolides studied by photoaffinity labeling

The macrolide antibiotics carbomycin A, niddamycin, and tylosin have been radioactively labeled by reducing their aldehyde group at the C-18 position. Dihydro derivatives with specific activities around 2.5 Ci/mmol can be obtained that, although partially affected in their activity, still bind to the ribosomes with high affinity. The presence in the chemical structure of these antibiotics of alpha-beta-unsaturated ketone groups makes them photochemically reactive, and by irradiation above 300 nm, covalent incorporation of the radioactive dihydro derivatives into ribosomes has been achieved. The covalent binding seems to take place at the specific binding sites for macrolides as deduced from binding saturation studies and competition experiments with unmodified drugs. Analysis of the ribosomal components labeled by the drugs indicated that most radioactivity is associated with the proteins L27, L2, and L28 when 50S subunits are labeled, and with L27, L2, L32/33, S9, and S12 in the case of 70S ribosomes. These results agree well with a model of macrolides' mode of action that assumes an interaction of the drug at the peptidyl transferase P site that would block the exit channel for the growing peptide chain.

Revertants of a streptomycin-resistant, oligosporogenous mutant of Bacillus subtilis

Revertants of a streptomycin-resistant (Strr), oligosporogenous (Spo-) mutant of Bacillus subtilis were selected form the ability to sporulate. The revertants obtained fell into two phenotypic classes: Strs Spo+ (streptomycin-sensitive, sporeforming), which arose by reversion of the streptomycin resistance mutations of the parent strain; and Strr Spo+, which arose by the acquisition of additional mutations, some of which were shown to affect ribosomal proteins. Alterations of ribosomal proteins S4 and S16 in the 30S subunit and L18 inthe 50S subunit were detected in Strr Spo+ revertants by polyacrylamide gel electrophoresis. Streptomycin resistance of the parental strain and the Strr revertants was demonstrated to reside in the 30S ribosomal subunit. The second site mutations of the revertants depressed the level of streptomycin resistance in vivo and in the in vitro translation of phage SP01 messenger ribonucleic acid (mRNA) relative to the resistance exhibited by the Strr parental strain. The Strr parent grew slowly and sporulated at approximately 1% of the wild type level. The Strr revertants closely resembled the wild type strain with regard to growth and sporulation. The Strr revertants grew at rates intermediate between those of the Strr patent and wild type, and sporulated at wild type levels.

Erythromycin resistance due to a mutation in a ribosomal RNA operon of Escherichia coli

There are seven ribosomal RNA operons (rrn operons) in Escherichia coli. A single rrn operon was amplified by use of a multicopy recombinant plasmid containing a complete rrnH operon. rrnH thereby has the potential to contribute a greater fraction of the rRNA found in ribosomes. Erythromycin-resistant mutants were isolated from cells containing the plasmid, and at least one mutation to resistance was shown to reside in rrnH on the plasmid. Erythromycin resistance was retained when a major deletion was introduced into the 16S rRNA gene and was abolished by deletions that affect the 16S and 23S rRNA genes but do not alter the 5S rRNA gene or non-rrnH DNA. Cell-free S30 protein-synthesizing extracts from cells containing the mutant plasmid have an increased resistance to erythromycin. The selection procedure used to isolate erythromycin-resistance mutations in rrnH may allow, with minor modifications, the isolation of mutations in rrn operons that change resistance of the ribosome to other antibiotics or that alter other properties of ribosomes.

Protein synthesis defects in temperature-sensitive mutants of Escherichia coli with altered ribosomal proteins

The ribosomes from four temperature-sensitive mutants of Escherichia coli have been examined for defects in cell-free protein synthesis. The mutants examined had alterations in ribosomal proteins S10, S15, or L22 (two strains). Ribosomes from each mutant showed a reduced activity in the translation of phage MS2 RNA at 44 degrees C and were more rapidly inactivated by heating at this temperature compared to control ribosomes. Ribosomal subunits from three of the mutants demonstrated a partial or complete inability to reassociate at 44 degrees C. 70-S ribosomes from two strains showed a reducton in messenger RNA binding. tRNA binding to the 30 S subunit was reduced in the strains with altered 30-S proteins and binding to the 50 S subunit was affected in the mutants with a change in 50 S protein L22. The relation between ribosomal protein structure and function in protein synthesis in these mutants is discussed.

Isolation and characterization of lambda transducing phages for the E. coli genes ksgA and pdxA

Lambda phages carrying the Escherichia coli genes ksgA and pdxA were isolated from secondary site lysogens in araB. 1) The phage genomes were characterized by genetic complementation tests, restriction endonuclease digestion and electron microscopy. 2) A 6.3 kilobasepair (kb) EcoRI restriction fragment carrying both ksgA and pdxA was cloned in a lambda vector; this fragment has proven useful in further characterization of the ksgA gene (Andrésson and Davies, 1980a, b). The ksgA and pdxA genes are about 14 and 12-13 kb, respectively, counterclockwise of the arabinose operon and 1.5 and 2.5-3.5 kb clockwise of folA.

Peptidyl transferase of bacterial ribosome: resistance to proteinase K

70-S ribosomes and 50-S ribosomal subunits from Escherichia coli D10 were treated with proteinase K for increasing periods of time. Peptidyl transferase activity and sparsomycin-induced binding of (U)C-A-C-C-A-[3H]Leu-Ac were tested in the treated particles, the binding of the substrate being more sensitive to the protease than peptide bond formation. Comparison of the amounts of proteins present in the treated particles with the residual activity indicates that only proteins L3 and L14 are released at a similar rate to that at which peptidyl transferase activity is lost. Proteins related to this ribosomal activity by other techniques are lost at a faster rate than the activity itself. In addition, the results indicate that sparsomycin stimulates the binding of the substrate by a different mechanism from that which inhibits peptide bond formation.

Properties of ribosomes from erythromycin resistant mutants of Escherichia coli

We have studied the in vitro properties of ribosomes from several mutants resistant to erythromycin. Mutations in three different genes may confer resistance to erythromycin. Two of them are structural genes for proteins L4 and L22 of the large subunit. The third mutation (in eryC gene) seems to affect mainly the small subunit. The mechanism of action of the antibiotic may involve both subunits.

A spectinomycin dependent mutant of Escherichia coli

A mutant of Escherichia coli B has been isolated which shows a novel phenotype of spectinomycin dependence. The mutant, termed RD, needs spectinomycin to grow at temperatures of 37 degrees or below; it is unable to grow at 42 degrees in either the presence or absence of spectinomycin. Secondary mutants which grow well in the absence of spectinomycin can be isolated spontaneously at a frequency of about 10(-6). Two-dimensional gel electrophoresis of ribosomal proteins from 25 of these revertants showed that two revertants had an alteration in S4; one other showed an alteration in L5, and one showed an apparent absence of L1. Mutant RD itself had an altered less basic S5, which was maintained in all the revertants that were checked. Genetic analysis indicated that RD was a double mutant: one mutation, which alone conferred a spectinomycin resistant phenotype on the strain, was located in the strA region of the E. coli chromosome and was represented by the mutation in S5. The other mutation, which conferred the dependence on spectinomycin, mapped close to the rif locus.

Erythromycin resistant mutations in Bacillus subtilis cause temperature sensitive sporulation

All of several hundred erythromycin resistant single site mutants of Bacillus subtilis W168 are temperature senstive for sporulation. The mutants and wild type cells grow vegetatively at essentially the same rates at both permissive (30 degrees C) and nonpermissive (47 degrees C) temperatures. In addition cellular protein synthesis, cell mass increases and cell viabilities are similar in mutant and wild type strains for several hours after the end of vegetative growth (47 degrees C). in the mutants examined, the temperature sensitive periods begin when the sporulation process is approximately 40% completed, and end when the process is 90% completed. At nonpermissive temperatures, the mutants produce serine and metal proteases at 50% of the wild type rate, accumulate serine esterase at 16% of the wild type rate, and do not demonstrate a sporulation related increase in alkaline phosphatase activity. The eryR and spots phenotypes cotransform 100%, and cotransduce 100% using phage PBS1. Revertants selected for ability to sporulate normally at 47 degrees C (spot), simultaneously regain parental sensitivity to erthromycin. No second site revertants are found. Ribosomes from eryR spots strains bind erythromycin at less than 1% of the wild type rate. A single 50S protein (L17) from mutant ribosomes shows an altered electrophoretic mobility. Ribosomes from spo+ revertants bind erythromycin like parental ribosomes and their proteins are electrophoretically identical to wild type. These data indicate that the L17 protein of the 50S ribosomal subunit from Bacillus subtilis may participate specifically in the sporulation process.

A strain of Escherichia coli which gives rise to mutations in a large number of ribosomal proteins

A strain of E. coli K12 has been isolated which gives rise to mutations in a large number of ribosomal proteins. Mutant VT, which was derived from A19, shows a novel type of streptomycin dependence and has an altered ribosomal protein S8. Streptomycin-independent isolated from mutant VT contain a great variety of changed proteins on two-dimensional polyacrylamide gels. 120 revertants screened in this way have changes in thirteen 30S proteins and fifteen 50S proteins. Several mutants were found in which additional proteins are present on the ribosome. Further, there is one instance of a ribosomal protein (L1) being absent, and one of apparent doubling of a ribosomal protein (L7/12). The unique properties of mutant VT probably are the result of the altered S8.

Peptidyltransferase activity of ribosomes and a ribosome precursor from a mutant of Escherichia coli

Escherichia coli strain 15-28 is a mutant with a defect in ribosome synthesis that caused the accumulation of ribonucleoprotein ('47S') particles during exponential growth. These particles are precursors to 50S ribosomes that lack three ribosomal proteins. Peptidyltransferase activity and binding at the peptidyl site of the peptidyltransferase centre are greatly decreased in 47S particles. Both these activities are lower in the 50S and 70S ribosomes of strain 15-28 than in its parent. Unusual assembly of the larger ribosomal subunit in strain 15-28 may produce completed ribosomes with diminished biological activity.

A lethal mutation which affects the maturation of ribosomes

A temperature sensitive mutant of Escherichia coli which fails to recover from prolonged carbon starvation, was found to be irreversibly killed by exposure to a nonpermissive temperature (43 degrees C), with a half-life of about half an hour. This bacteriocidal effect of the temperature could be reversed by a number of antibiotics which block protein synthesis but not by blocking DNA synthesis. At the nonpermissive temperature, RNA and the protein synthetic capacities decrease before the DNA synthetic capacity is decreased. Analysis of ribosomal proteins and methylation of them did not reveal any consistent differences between the parental and mutant strains. Analysis of the ribosomal RNA revealed that it is being synthesized in similar amounts as in the parental strain at the nonpermissive temperature, however, after chase its level is decreased. Moreover, the 17S precursor RNA is slow to mature to 16S rRNA in the mutant strain at the nonpermissive temperature. Thus, these studies suggest that the mutation studied here affects a late maturation step in the synthesis of the rRNA. Therefore the gene is designated rimH (for ribosomal modification). All the properties bestowee on the mutant strain are caused by a single pleiotropic mutation which maps at min 14 of the E. coli map. Three point transduction crosses suggest the order rimH, leuS, RNA, LIP. This gene maps outside the two known clusters for ribosomal structural genes.