Protein synthesis in Bacillus subtilis. I. Hydrodynamics and in vitro functional properties of ribosomes from B. subtilis W168.

On the basis of their sedimentation properties, the ribosomal particles in crude extracts of Bacillus subtilis W168 are characterized as pressure-sensitive couples, pressure-resistant couples, or non-associating subunits. Pressure-sensitive couples dissociate into subunits, yielding a peak at 60 S in the gradient profile, on sedimentation at high speed in the presence of 10 to 15 mm-Mg²⁺. Under the same conditions, pressure-resistant couples sediment at 70 S. Under certain conditions, pressure-resistant couples apparently aggregate, possibly in 70 S · 70 S dimers. Procedures are described for the isolation of pressure-sensitive couples from B. subtilis. The isolated couples are shown by chemical fixation experiments to require approximately twice the Mg²⁺ concentration required by Escherichia coli couples to remain associated at atmospheric pressure.All three types of B. subtilis ribosome incorporate amino acids into acid-insoluble material in the presence of B. subtilis cellular RNA, B. subtilis ribosomal salt wash fraction, and E. coli post-ribosomal supernatant. Overall incorporation, dependence on added RNA, and dependence on salt wash fraction are greatest with pressure-sensitive couples. The products of protein synthesis in vitro stimulated by total B. subtilis RNA appear to be a low molecular weight subset of the proteins synthesized most abundantly in vivo. Incubation of pressure-sensitive couples with cellular RNA from B. subtilis, fMet-tRNA_f^Met, ribosomal salt wash fraction and GTP results in their conversion to pressure-resistant couples, with concomitant and stoichiometric binding of fMet-tRNA to the 70 S species. It is concluded that in B. subtilis as in E. coli, pressure-sensitive couples are “vacant”, while pressure-resistant couples are “complexed” with messenger RNA. fMet-tRNA-bearing complexed couples are interpreted as initiation complexes in which ribosomes have bound mRNA, presumably at initiation sites. Their formation in vitro is strictly dependent on RNA, salt wash fraction and fMet-tRNA when vacant ribosomal couples are used.