Hyper-accurate ribosomes inhibit growth.

We have compared both in vivo and in vitro translation by ribosomes from wild-type bacteria with those from streptomycin-resistant (SmR), streptomycin-dependent (SmD) and streptomycin-pseudo-dependent (SmP) mutants. The three mutant bacteria translate more accurately and more slowly in the absence of streptomycin (Sm) than do wild-type bacteria. In particular, the SmP bacteria grow at roughly half the rate of the wild-type in the absence of Sm. The antibiotic stimulates both the growth rate and the translation rate of SmP bacteria by approximately 2-fold, but it simultaneously increases the nonsense suppression rate quite dramatically. Kinetic experiments in vitro show that the greater accuracy and slower translation rates of mutant ribosomes compared with wild-type ribosomes are associated with much more rigorous proofreading activities of SmR, SmD and SmP ribosomes. Sm reduces the proofreading flows of the mutant ribosomes and stimulates their elongation rates. The data suggest that these excessively accurate ribosomes are kinetically less efficient than wild-type ribosomes, and that this inhibits mutant growth rates. The stimulation of the growth of the mutants by Sm results from the enhanced translational efficiency due to the loss of proofreading, which more than offsets the loss of accuracy caused by the antibiotic.     

Structural dynamics of bacterial ribosomes. I. Characterization of vacant couples and their relation to complexed ribosomes

Ribosomes not engaged in protein synthesis (vacant couples), in contrast to complexed ribosomes bearing nascent chains, dissociate during sedimentation in sucrose gradients at high g forces and at Mg²⁺ concentrations below 15 mm. As a result of this dissociation, a new peak between the 70 S complexed ribosomes and the free 50 S subunits is observed, the position of which shifts from about 55 S to 70 S as the Mg²⁺ concentration in the gradient is raised from 5 to 15 mm. The apparent 60 S peak consists of 50 S subunits produced during dissociation in the gradient. At low g forces, the sedimentation rate of complexed and vacant ribosomes is indistinguishable, even at 5 mm-Mg²⁺. These sedimentation properties are valid criteria to differentiate vacant and complexed ribosomes. This is shown by converting complexed ribosomes quantitatively into vacant couples by removing the nascent chains through termination release or with puromycin, or by converting vacant couples into initiation complexes with R17 RNA, fMet-tRNA and initiation factors.Ribosomes from cells harvested by slow cooling consist almost entirely of vacant couples, all of which are active in protein synthesis with natural messengers. The structural features responsible for the interaction between subunits are discussed.     

Molecular forces in ribosomes and polynucleotide complexes.

The stability constant of the complex of tRNA with 50S subunits of ribosomes was compared in ordinary and heavy water. A considerable effect (about fourfold) was observed, showing the importance of hydrogen bonds in this interaction. In addition, the isotope effect of complementary polynucleotide interaction was measured for two examples. In the case of the binary complex of heptainosinic acid oligomers with poly(C) in the presence of 10^?3 M MgCl₂, the transfer from ordinary to heavy water gave an increase of the stability constant of about 5%. But in the case of a ternary complex of hexaadenylic acid with poly(U) under the same conditions, the stability constant in D₂O increased threefold. The isotope effect depends strongly on magnesium ion concentration and is possibly due to some specific mechanism of magnesium ion complexing involving water molecules.     

gamma-Carboxyglutamic acid in eukaryotic and prokaryotic ribosomes.

γ-carboxyglutamic acid (GLA) has been assayed in ribosomes of wheat germ and E. coli, and in E. coli ribosomal sub-units, by amino acid analysis of total protein. Results, as nMoles GLA/mg protein, were 18.1 (wheat germ), 58.4 (E. coli), 39.6 and 81.5 (E. coli 30S and 50S sub-units, respectively.) Results for wheat germ and previously reported mammalian ribosomes were highly similar. Hence the level of GLA in eukaryotic ribosomes appears to be approximately constant, but low compared to bacterial (E. coli) ribosomes.     

Peptidyl-puromycin synthesis by free and membrane-bound ribosomes.

The peptidyl transferase reaction, as measured by the formation of peptidyl-puromycin, was compared for free ribosomes and ribosomes bound to two types of membrane, the endoplasmic reticulum and the outer nuclear membrane. In most respects the reaction catalyzed by the three types of ribosome was similar, demonstrating that interaction of the 60 S ribosomal subunit with the membrane has little effect on the functioning of peptidyl transferase, a 60 S protein. However, both the rate and extent of synthesis of peptidyl puromycin were lower for ribosomes bound to the nuclear membrane than for free or microsome-bound ribosomes. This difference appears to be a direct consequence of the ribosome-membrane interaction, since ribosomes stripped from the nuclear membrane could not be distinguished from the other classes of ribosome.     

Structural dynamics of translating ribosomes.

We describe three groups of small angle neutron scattering (SANS) experiments with translating ribosomes: 1) regular protonated (normal abundance hydrogen) particles; 2) two isotopic hybrid particles which are reconstituted from one protonated and the other deuterated subunit; 3) four isotypic hybrid particles differing from each other by the extent of protein and RNA deuteration. Using the SANS contrast variation method the radii of gyration of protein and RNA components in both ribosomal subunits as well as the intersubunit distance in the pre- and post-translocation states were determined. The results obtained suggest the following model of the ribosome as a dynamic machine. The ribosome oscillates between two major conformers differing in geometrical dimensions. The 'active' (pulsating) part of the ribosome is the 30S subunit. We believe that the movement of its 'head' relative to the passive 50S subunit is the main mechanical act of translocation. The radius of gyration of the 30S subunit and the intersubunit distance change upon the movement. This is corroborated by neutron scattering data.