Summary
We have compared the sensitivities to different translation inhibitors of the syntheses of enzymes from various cell compartments. Alkaline and acid phosphatases were chosen as representative of periplasmic enzymes. Aminopeptidase N and β-galactosidase represented peripheral membrane protein and cytoplasmic enzyme respectively. Antibiotics of low polarity such as spectinomycin and tetracycline, when used at low concentrations, caused a preferential inhibition of exported proteins compared to total cell proteins, to aminopeptidase N and to β-galactosidase. Synthesis itself was inhibited as demonstrated by immunochemical assay of the amount of proteins synthesized in the presence or absence of spectinomycin. Temperature-dependance of the penetration of spectinomycin as reported by its effect, indicated that this drug does not enter the cell by simple dissolution in the membrane lipids but rather enters at specific sites of the cell envelope. In contrast to low polarity inhibitors, a polar antibiotic such as kanamycin did not cause any preferential inhibition of the syntheses of exported proteins. By using radioactive tetracycline (0.025, 0.1 and 0.2 μg/ml) we have investigated the distribution of this antibiotic between free and membrane-bound polysomes isolated without the use of lysozyme. Three times as much tetracycline was found in the membrane-bound compared to free polysomes fraction.
Therefore we propose that preferential sensitivity of synthesis of exported proteins to translation inhibitors of low polarity reflects a preferential binding of these antibiotics to membrane-bound polysomes fractions in Escherichia coli. We thus suggest that this preferential binding occurs since the site of entry of weakly ionized antibiotics used in this study, correspond to the site of synthesis and transfer of exported proteins.
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Communicated by H.G. Wittmann
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Piovant, M., Varenne, S., Pagès, J.M. et al. Preferential sensitivity of syntheses of exported proteins to translation inhibitors of low polarity in Escherichia coli . Molec. Gen. Genet. 164, 265–274 (1978). https://doi.org/10.1007/BF00333156
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DOI: https://doi.org/10.1007/BF00333156