Protein synthesis antibiotic inhibition

The tetracycline antibiotics have a high chelating ability for polyvalent cations. This may have some relationship to their mechanism of protein synthesis inhibition, which is... 

It has been known for some time that tetracyclines are accumulated by bacteria and prevent bacterial protein synthesis (Fig. 4). Furthermore, inhibition of protein synthesis is responsible for the bacteriostatic effect (85). Inhibition of protein synthesis results primarily from dismption of codon-anticodon interaction between tRNA and mRNA so that binding of aminoacyl-tRNA to the ribosomal acceptor (A) site is prevented (85). The precise mechanism is not understood. However, inhibition is likely to result from interaction of the tetracyclines with the 30S ribosomal subunit because these antibiotics are known to bind strongly to a single site on the 30S subunit (85). 

Early studies by Terawaki and Greenberg on the antibiotic activity of carzinophilin established that it inhibited DNA synthesis but not RNA or protein synthesis in E. coli strain Bo and in Bacillus subtilis [134]. They also found that exposure to carzinophilin removed the transforming capacity of B. subtilis DNA [135]. They... 

Tetracycline and its derivative doxycycline are antibiotics widely used in the treatment of bacterial infections. They also exert an antimalarial activity. Tetracyclines inhibit the binding of aminoacyl-tRNA to the ribosome during protein synthesis. 

What could be the signal for the induction of the cold shock proteins It has been observed that shifting E. coli cells from 37 to 5 °C results in an accumulation of 70S monosomes with a concomitant decrease in the number of polysomes [129]. Further, it has been shown that a cold shock response is induced when ribosomal function is inhibited, e.g. by cold-sensitive ribosomal mutations [121] or by certain antibiotics such as chloramphenicol [94]. These data indicate that the physiological signal for the induction of the cold shock response is inhibition of translation caused by the abrupt shift to lower temperature. Then, the cold shock proteins RbfA, CsdA and IF2 associate with the 70S ribosomes to convert the cold-sensitive nontranslatable ribosomes into cold-resistant translatable ribosomes. This in turn results in an increase in cellular protein synthesis and growth of the cells. 

MANY ANTIBIOTICS WORK BECAUSE THEY SELECTIVELY INHIBIT PROTEIN SYNTHESIS IN BACTERIA... 

Other antibiotics inhibit protein synthesis on all ribosomes (puromycin) or only on those of eukaryotic cells (cycloheximide). Puromycin (Figure 38—11) is a structural analog of tyrosinyl-tRNA. Puromycin is incorporated via the A site on the ribosome into the carboxyl terminal position of a peptide but causes the premature release of the polypeptide. Puromycin, as a tyrosinyl-tRNA analog, effectively inhibits protein synthesis in both prokaryotes and eukaryotes. Cycloheximide inhibits peptidyltransferase in the 60S ribosomal subunit in eukaryotes, presumably by binding to an rRNA component. 

A variety of compounds, including several antibiotics, inhibit protein synthesis by affecting one or more of the steps involved in protein synthesis. 

Of the fonr possible optical isomers of chloramphenicol, only the o-threo form is active. This antibiotic selectively inhibits protein synthesis in bacterial ribosomes by binding to the 50S subunit in the region of the A site involving the 23 S rRNA. The normal binding of the aminoacyl-tRNA in the A site is affected by chloramphenicol in such a... 

Inhibition of protein synthesis is the antibacterial mechanism shared by most groups of antibiotics, though the exact action differs. 

Mupirocin is a topical antibiotic that inhibits isoleucyl tRNA synthetase with the subsequent inhibition of protein synthesis. Mupirocin has become a mainstay in the treatment of Staph, aureus infection and colonization during hospital outbreaks, and it is in this organism that acquired resistance has arisen (Gilbart etal. 1993). 

Urease assay. When Proteus mirabilis grows in a urea-containing medium it hydrolyses the urea to ammonia and consequently raises the pH of the medium. This production of urease is inhibited by aminoglycoside antibiotics (inhibitors of protein synthesis Chapter 8). In practice, it is difficult to obtain reliable results by this method. 

The macrolide erythromycin inhibits protein synthesis and resistance is induced by N -dimethyl-ation of adenine within the 23S rRNA, which results in reduced affinity of ribosomes for antibiotics related to erythromcin (Skinner et al. 1983). Sulfonamides function by binding tightly to chromosomal dihydropteroate synthetase and resistance to sulfonamides is developed in the resistance plasmid through a form of the enzyme that is resistant to the effect of sulfonamides. 

To establish whether rifaximin, like the other members of the rifamycin family [36, 58], specifically inhibits bacterial RNA synthesis the effect of this antibiotic as well as that of rifampicin and chloramphenicol on RNA (via 3H-uridine incorporation), DNA (via 3H-thymidine incorporation) and protein (via 35S-methionine incorporation) synthesis was studied in growing cultures of Escherichia coli [59], While chloramphenicol reduced protein synthesis, both rifaximin and rifampicin inhibited RNA synthesis in a concentration-dependent fashion. In contrast, none of them affected 3H-thymidine incorporation into DNA. These data suggest that rifaximin, like rifampicin, inhibits RNA synthesis by binding the (3 subunit of the bacterial DNA-dependent RNA polymerase [60],... 

Transcription and protein synthesis in the chloroplast can be inhibited by antibiotics because chloroplast ribosomes are similar in structure to those of bacteria. Chloroplast ribosomes are 70S in size, comprising a large 50S subunit (containing... 

Transcriptional inhibitors could be used simultaneously. Rifampicin blocks chloroplast and mitocondrian RNA synthesis [23, 24], while tagetitoxin is a very specific inhibitor of chloroplast RNA polymerase [25]. Treatment with these antibiotics does not inhibit Rubisco SSU synthesis since the promoter is part of the nuclear genome, while the cytosolic ribosomes are not affected by streptomycin. Therefore SSU promoters can be used to drive transgene expression and facilitate the accumulation of recombinant proteins. Expressed proteins are targeted to a suitable cellular compartment, such as the cytoplasm, apoplastic space or chloroplast, depending on the nature of the protein. 

Tetracyclines are a group of antibiotics derived from bacteria. Chlortet-racycline was isolated from Streptomyces aureofaciens and oxytetracycline from Streptomyces rimosus. Tetracychnes act by binding to receptors on the bacterial ribosome and inhibit bacterial protein synthesis. 

Certain antibiotics (for example, chloramphenicol) inhibit mitochondrial protein synthesis, but not cytoplasmic protein synthesis, because mitochondrial ribosomes are similar to prokaryotic ribosomes. 

Aminomethyl- cyclines Amino- methyl- cycline MK-2764 (PTK-0796 BAY 73-7388) (153) Antibacterial (broad spectrum antibiotic against MRS A, MDR Streptococcus pneumoniae and vancomycin-resistant enterococci) Inhibits bacterial protein synthesis Phase III (treatment of hospital infections in both oral and i.v. injectable formulations) Paratek/Novartis 810... 

The use of antibiotics for the control of plant virus diseases( ) is of interest. Several antibiotics have been tested for inhibition of replication of viral nucleic acid and/or protein synthesis within the host cell. Chloramphenicol, cycloheximide, actinomycin D and others are the most used antibiotics and the disease caused by tobacco mosaic... 

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