Streptomycin, protein synthesis inhibition

Streptomycin Protein synthesis inhibition Deafness, vestibular dysfunction, nephrotoxicity... 

Streptomycin Protein synthesis inhibition see Aminoglycoside, pages 187-188) Deafness Vestibular dysfunction Nephrotoxicity... 

Tetracyclines are a family of antibiotics which display a characteristic 4-fused-core ring structure (Figure 1.16). They exhibit broad antimicrobial activity and induce their effect by inhibiting protein synthesis in sensitive microorganisms. Chlortetracycline was the first member of this family to be discovered (in 1948). Penicillin G and streptomycin were the only antibiotics in use at that time, and chlortetracycline was the first antibiotic employed therapeutically that retained its antimicrobial properties upon oral administration. Since then, a number of additional tetracyclines have been discovered (all produced by various strains of Streptomyces), and a variety of semi-synthetic derivatives have also been prepared (Table 1.18). 

Streptomycin and other aminoglycosides inhibit bacterial protein synthesis by binding... 

The selection of transformed chloroplasts usually involves the use of an antibiotic resistance marker. Spectinomycin is used most routinely because of the high specificity it displays as a prokaryotic translational inhibitor as well as the relatively low side effects it exerts on plants. The bacterial aminoglycoside 3 -adenyltransferase gene (ciadA) confers resistance to both streptomycin and spectinomycin. The aadA protein catalyzes the covalent transfer of an adenosine monophosphate (AMP) residue from adenosine triphosphate (ATP) to spectinomycin, thereby converting the antibiotic into an inactive form that no longer inhibits protein synthesis for prokaryotic 70S ribosomes that are present in the chloroplast. 

All aminoglycosides act by inhibiting protein synthesis of bacteria by directly combining with ribosomes. They penetrate the outer cytoplasmic membrane and inhibit protein synthesis. Streptomycin combines with the bacterial 30S ribosomes and inteferes with the mRNA-ribosome combination. Other aminoglycosides bind to additional sites on SOS subunit as well as to 30S-50S interface. 

Inside the cell, aminoglycosides bind to specific 30S-subunit ribosomal proteins (S12 in the case of streptomycin). Protein synthesis is inhibited by aminoglycosides in at least three ways (Figure 45-3) (1) interference with the initiation complex of peptide formation (2) misreading of mRNA, which causes incorporation of incorrect amino acids into the peptide and results in a nonfunctional or toxic protein and (3) breakup of polysomes into nonfunctional monosomes. These activities occur more or less simultaneously, and the overall effect is irreversible and lethal for the cell. 

The glycoside/aminoglycoside antibiotics, like the macrolides, exert a bacteriostatic effect due to selective inhibition of bacterial protein synthesis, with the exception of novobiocin (26). The compounds neomycin (27), spectinomycin (28) and streptomycin (29) bind selectively to the smaller bacterial 30S ribosomal subunit, whilst lincomycin (30) binds to the larger 50S ribosomal subunit (cf. macrolides). Apramycin (31) has ribosomal binding properties, but the exact site is uncertain (B-81MI10802). Novobiocin (26) can inhibit nucleic acid synthesis, and also complexes magnesium ion, which is essential for cell wall stability. 

Inhibition of protein synthesis Streptomycin Tetracyclines Inhibits initiation stage Inhibits binding of aminoacyl-tRNA to 30S ribosomal subunit... 

Inhibition of protein synthesis by aminoglycoside antibiotics, especially by streptomycin, is bactericidal (rev.46)). The antibiotic binds to the smaller ribosomal subunit and leads to the formation of abortive initiation complexes of ribosomes, streptomycin and amino acyl tRNA which progressively trap ribosomes in the form of such biologically irreversible complexes. When protein synthesis is prematurely terminated by puromycin and ribosomes are thus made available for reinitiation of de novo protein biosynthesis, the bactericidal action of streptomycin is accelerated47). Destruction of ribosomes under the influence of primaquine operationally also results in non-occurrence of protein synthesis and in a marked bactericidal effect48, 49 ... 

D. Treatment of bacterial infections Antibiotics that selectively affect bacterial function and have minimal side effects in humans are usually selected to treat bacterial infections. Rifampicin, which inhibits the initiation of prokaryotic RNA synthesis, is used to treat tuberculosis. Streptomycin, tetracycline, chloramphenicol, and erythromycin inhibit protein synthesis on prokaiyotic ribosomes and are used for many infections. Chloramphenicol affects mitochondrial ribosomes and must be used with caution. 

Examples of antibiotics that attack bacteria by inhibiting protein synthesis at the ribosomal level include the following tetracycline antibiotics (e.g. chlortetracycline) aminoglycoside antibiotics (e.g. neomycin, streptomycin) macrolide antibiotics (e.g. erythromycin, clarithromycin, azithromycin) also chloramphenicol, fusidic acid and lincosamides (e.g. clindamycin). 

The answer is e. (Murray, pp 452-467. Scriver, pp 3-45. Sack, pp 1-40. Wilson, pp 101-120.) Puromycin is virtually identical in structure to the 3 -terminal end of tyrosinyl-tRNA. In both eukaryotic and prokaryotic cells, it is accepted as a tyrosinyl-tRNA analogue. As such, it is incorporated into the carboxy-terminal position ol a peptide at the aminoacyl (A) site on ribosomes, causing premature release of the nascent polypeptide. Thus, puromycin inhibits protein synthesis in both human and bacterial cells. Streptomycin, like tetracycline and chloramphenicol, inhibits ribosomal activity. Mitomycin covalently cross-links DNA, which prevents cell replication. Rifampicin is an inhibitor of bacterial DNA-dependent RNA polymerase. 

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