Protein synthesis in Bacillus subtilis: II. Selective translation of natural mRNAs and its possible relation to the species-specific inhibition of protein synthesis by lincomycin and erythromycin

Abstract

Vacant ribosomal couples from Bacillus subtilis W168 incorporate only very small amounts of amino acids into polypeptides in response to Escherichia coli cellular RNA or bacteriophage f2 RNA, but are observed to form initiation complexes in the presence of f2 RNA. Vacant ribosomal couples from E. coli acquire pressure-resistance, but do not bind fMet-tRNA, when incubated with B. subtilis RNA in the absence of ribosomal wash fraction. The implied mRNA binding in the absence of salt wash fraction, taken with previously reported observations of salt wash-independent translation of mRNAs from Grampositive bacteria, suggests that mRNAs from Gram-positive bacteria have an active functional character which is masked or absent in mRNAs from Gram-negative sources. It is proposed that this property of B. subtilis mRNAs is required by B. subtilis ribosomes for some translational function subsequent to the formation of the 70 S initiation complex, and that f2 RNA, while it is bound by B. subtilis ribosomes in initiation complexes, is not translated because it lacks this feature. The antibiotic lincomycin has been found to inhibit translation of natural mRNAs in vitro in systems from Gram-positive bacteria at concentrations 10 to 100 times lower than those necessary to inhibit translation in systems from Gram-negative species. Lincomycin does not inhibit formation of initiation complexes by vacant couples from B. subtilis or E. coli. Taken with the published findings of other investigators, these results are interpreted as indicating that the first translocation step following assembly of the initiation complex may coincide with a transition between distinct “initiating” and “elongating” states of the ribosome, and that this transition may involve structural elements, and possibly mechanisms, which are different in Gram-positive systems than in Gram-negative systems. A comprehensive model is constructed to account for the results of these studies and for the published findings of other investigators. It is proposed that some feature of Gram-positive mRNA, perhaps a vestige of early protein synthetic systems, is required by the ribosomes of Gram-positive bacteria to facilitate the transition between initiating and elongating ribosomal states. Inhibition of protein synthesis by lincomycin and the similarly species-specific macrolide antibiotic erythromycin is interpreted as an allosteric effect on the transition between initiating and elongating ribosomal states, in which the different binding affinities of ribosomes from Gram-positive and Gram-negative bacteria for the drugs are related to the functional differences between the two types of systems at this critical step. The implications of this interpretation of interspecies translational specificity for mechanisms of translational control in the cell and for the nature of the divergence of bacterial protein synthesis systems into Gram-positive and Gram-negative types are discussed.