Antibiotic-induced ribosomal assembly defects result from changes in the synthesis of ribosomal proteins (original) (raw)
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Antimicrobial Agents and Chemotherapy, 2008
Several protein synthesis inhibitors are known to inhibit ribosome assembly. This may be a consequence of direct binding of the antibiotic to ribosome precursor particles, or it could result indirectly from loss of coordination in the production of ribosomal components due to the inhibition of protein synthesis. Here we demonstrate that erythromycin and chloramphenicol, inhibitors of the large ribosomal subunit, affect the assembly of both the large and small subunits. Expression of a small erythromycin resistance peptide acting in cis on mature ribosomes relieves the erythromycin-mediated assembly defect for both subunits. Erythromycin treatment of bacteria expressing a mixture of erythromycin-sensitive and -resistant ribosomes produced comparable effects on subunit assembly. These results argue in favor of the view that erythromycin and chloramphenicol affect the assembly of the large ribosomal subunit indirectly.
Erythromycin inhibition of 50S ribosomal subunit formation in Escherichia coli cells
Molecular Microbiology, 2001
The effects of erythromycin on the formation of ribosomal subunits were examined in wild-type Escherichia coli cells and in an RNase E mutant strain. Pulse±chase labelling kinetics revealed a reduced rate of 50S subunit formation in both strains compared with 30S synthesis, which was unaffected by the antibiotic. Growth of cells in the presence of [ 14 C]-erythromycin showed drug binding to 50S particles and to a 50S subunit precursor sedimenting at about 30S in sucrose gradients. Antibiotic binding to the precursor correlated with the decline in 50S formation in both strains. Erythromycin binding to the precursor showed the same 1:1 stoichiometry as binding to the 50S particle. Gel electrophoresis of rRNA from antibiotic-treated organisms revealed the presence of both 23S and 5S rRNAs in the 30S region of sucrose gradients. Hybridization with a 23S rRNAspecific probe confirmed the presence of this species of rRNA in the precursor. Eighteen 50S ribosomal proteins were associated with the precursor particle. A model is presented to account for erythromycin inhibition of 50S formation.
Molecular microbiology, 2006
achievements paved the way for the development of new ribosome-targeting antibiotics, some of which have already entered medical practice. The recent progress, problems and new directions of research of ribosome-targeting antibiotics are discussed in this review.
MicroReview Antibiotics and the ribosome
2006
The ribosome is one of the main antibiotic targets in the cell. Recent years brought important insights into the mode of interaction of antibiotics with the ribosome and mechanisms of antibiotic action. Ribosome crystallography provided a detailed view of the interactions between antibiotics and rRNA. Advances in biochemical techniques let us better understand how the binding of small organic molecules can interfere with functions of an enzyme four orders of magnitude larger than the inhibitor. These and other achievements paved the way for the development of new ribosome-targeting antibiotics, some of which have already entered medical practice. The recent progress, problems and new directions of research of ribosome-targeting antibiotics are discussed in this review.
Journal of Biological Chemistry, 1999
Structural analysis of the 16 S rRNA in the 30 S subunit and 70 S ribosome in the presence of ribosome-specific antibiotics was performed to determine whether they produced rRNA structural changes that might provide further insight to their action. An UV cross-linking procedure that determines the pattern and frequency of intramolecular 16 S RNA cross-links was used to detect differences reflecting structural changes. Tetracycline and spectinomycin have specific effects detected by this assay. The presence of tetracycline inhibits the cross-link C967؋C1400 completely, increases the frequency of cross-link C1402؋1501 twofold, and decreases the cross-link G894؋U244 by one-half without affecting other cross-links. Spectinomycin reduces the frequency of the cross-link C934؋U1345 by 60% without affecting cross-linking at other sites. The structural changes occur at concentrations at which the antibiotics exert their inhibitory effects. For spectinomycin, the apparent binding site and the affected crosslinking site are distant in the secondary structure but are close in tertiary structure in several recent models, indicating a localized effect. For tetracycline, the apparent binding sites are significantly separated in both the secondary and the three-dimensional structures, suggesting a more regional effect.
Cooperative and Antagonistic Interactions of Peptidyl-tRNA and Antibiotics with Bacterial Ribosomes
European Journal of Biochemistry, 1977
There is a single-site interaction of [mrthylene-'4C]thiamphenicol and [methylene-14C]chloramphenicol with run-off ribosomes with dissociation constants Kd = 6.8 pM and Kd = 4.6 yM respectively. Similar affinities for the antibiotics are observed in polysomes totally deprived of nascent peptides, or bearing nascent peptides on the A-site. However, two types of interaction are observed in endogenous polysomes with some ribosomes bearing nascent peptides on the P-site and others in the A-site. The lower-affinity bindings (dissociation constants Kd = 6.4 pM and Kd = 5.9 pM for thiamphenicol and chloramphenicol respectively) are due to the ribosomes bearing nascent peptides on the A-site. The higher-affinity bindings (dissociation constants Kd = 2.3 yM and Kd = 1.5 pM for thiamphenicol and chloramphenicol, respectively) are due to the ribosomes bearing nascent peptides on the P-site. Therefore binding of nascent peptides to the A-site does not affect the affinities of thiamphenicol and chloramphenicol for the ribosome. On the other hand interaction of the nascent peptides with the P-site of the ribosomes increases the affinities of both antibiotics for the ribosome. Thiamphenicol and chloramphenicol are thus good inhibitors of peptide bond formation in ribosomes and polysomes. Their affinities are increased precisely when the peptidyl-tRNA is placed in the P-site preceeding the peptide bond formation step, which is specifically blocked by the antibiotics.
The bacterial ribosome as a target for antibiotics
Nature Reviews Microbiology, 2005
Many clinically useful antibiotics exert their antimicrobial effects by blocking protein synthesis on the bacterial ribosome. The structure of the ribosome has recently been determined by X-ray crystallography, revealing the molecular details of the antibiotic-binding sites. The crystal data explain many earlier biochemical and genetic observations, including how drugs exercise their inhibitory effects, how some drugs in combination enhance or impede each other's binding, and how alterations to ribosomal components confer resistance. The crystal structures also provide insight as to how existing drugs might be derivatized (or novel drugs created) to improve binding and circumvent resistance.
Molecular Pharmacology, 2003
In a cell-free system derived from Escherichia coli, it is shown that clarithromycin and roxithromycin, like their parent compound erythromycin, do not inhibit the puromycin reaction (i.e., the peptide bond formation between puromycin and AcPhe-tRNA bound at the P-site of 70S ribosomes programmed with heteropolymeric mRNA). Nevertheless, all three antibiotics compete for binding on the ribosome with tylosin, a 16-membered ring macrolide that behaves as a slow-binding, slowly reversible inhibitor of peptidyltransferase. The mutually exclusive binding of these macrolides to ribosomes is also corroborated by the fact that they protect overlapping sites in domain V of 23S rRNA from chemical modification by dimethyl sulfate. From this competition effect, detailed kinetic analysis revealed that roxithromycin or clarithromycin (A), like erythromycin, reacts rapidly with AcPhe-tRNA⅐MF-mRNA⅐70S ribosomal complex (C) to form the encounter complex CA which is then slowly isomerized to a more tight complex, termed C*A. The value of the overall dissociation constant, K A * , encompassing both steps of macrolide interaction with complex C, is 36 nM for erythromycin, 20 nM for roxithromycin, and 8 nM for clarithromycin. Because the off-rate constant of C*A complex does not significantly differ among the three macrolides, the superiority of clarithromycin as an inhibitor of translation in E. coli cells and many Gram-positive bacteria may be correlated with its greater rate of association with ribosomes.