Dennis Synetos

Eukaryotic ribosomal proteins lacking a eubacterial counterpart: important players in ribosomal function

The ribosome is a macromolecular machine responsible for protein synthesis in all organisms. Despite the enormous progress in studies on the structure and function of prokaryotic ribosomes, the respective molecular details of the mechanism by which the eukaryotic ribosome and associated factors construct a polypeptide accurately and rapidly still remain largely unexplored. Eukaryotic ribosomes possess more RNA and a higher number of proteins than eubacterial ribosomes. As the tertiary structure and basic function of the ribosomes are conserved, what is the contribution of these additional elements? Elucidation of the role of these components should provide clues to the mechanisms of translation in eukaryotes and help unravel the molecular mechanisms underlying the differences between eukaryotic and eubacterial ribosomes. This article focuses on a class of eukaryotic ribosomal proteins that do not have a eubacterial homologue. These proteins play substantial roles in ribosomal structure and function, and in mRNA binding and nascent peptide folding. The role of these proteins in human diseases and viral expression, as well as their potential use as targets for antiviral agents is discussed.

Mutations in yeast ribosomal proteins S28 and S4 affect the accuracy of translation and alter the sensitivity of the ribosomes to paromomycin

Ribosomal proteins S12, S5 and S4 of Escherichia coli are essential for the control of translational accuracy. Their yeast equivalents, i.e., S28, S4 and S13, have also been implicated in this process. Using a poly(U)-dependent cell-free translation system, we determined the accuracy of translation and the sensitivity to antibiotic paromomycin of yeast ribosomes carrying mutant ribosomal proteins S28 and/or S4. Our results confirm by quantitative biochemical methods previous genetic data showing that proteins S28 and S4 are involved in the decoding activity of the ribosome and interact to control translational accuracy. We find that the suppressor mutation SUP44 in yeast S4, decreased the accuracy of translation. To examine the effect of mutant S28, we disrupted RPS28B and introduced in RPS28A the same substitutions that cause hyperaccurate translation or antibiotic resistance in bacteria. Three of these substitutions (Lys-62-->Asn, Thr or Gln) similarly increased translational accuracy in vitro or antibiotic resistance. In the presence of the SUP44 mutation, these substitutions partially reversed the decrease of translational accuracy caused by SUP44. However, the Lys-62-->Arg substitution decreased translational accuracy and caused antibiotic sensitivity both in nonsuppressor and in SUP44 haploids. These results establish the role of Lys-62 of S28 in optimizing translational accuracy and provide a more precise view of the functional role of two important ribosomal proteins.

Studies on the catalytic rate constant of ribosomal peptidyltransferase

A detailed kinetic analysis of a model reaction for the ribosomal peptidyltransferase is described, using fMet-tRNA or Ac-Phe-tRNA as the peptidyl donor and puromycin as the acceptor. The initiation complex (fMet-tRNA X AUG X 70 S ribosome) or (Ac-Phe-tRNA X poly(U) X 70 S ribosome) (complex C) is isolated and then reacted with excess puromycin (S) to give fMet-puromycin or Ac-Phe-puromycin. This reaction (puromycin reaction) is first order at all concentrations of S tested. An important asset of this kinetic analysis is the fact that the relationship between the first order rate constant kobs and [S] shows hyperbolic saturation and that the value of kobs at saturating [S] is a measure of the catalytic rate constant (k cat) of peptidyltransferase in the puromycin reaction. With fMet-tRNA as the donor, this kcat of peptidyltransferase is 8.3 min-1 when the 0.5 M NH4Cl ribosomal wash is present, compared to 3.8 min-1 in its absence. The kcat of peptidyltransferase is 2.0 min-1 when Ac-Phe-tRNA replaces fMet-tRNA in the presence of the ribosomal wash and decreases to 0.8 min-1 in its absence. This kinetic procedure is the best method available for evaluating changes in the activity of peptidyltransferase in vitro. The results suggest that peptidyltransferase is subjected to activation by the binding of fMet-tRNA to the 70 S initiation complex.

A Dispensable Yeast Ribosomal Protein Optimizes Peptidyltransferase Activity and Affects Translocation

Yeast ribosomal protein L41 is dispensable in the yeast. Its absence had no effect on polyphenylalanine synthesis activity, and a limited effect on growth, translational accuracy, or the resistance toward the antibiotic paromomycin. Removal of L41 did not affect the 60:40 S ratio, but it reduced the amount of 80 S, suggesting that L41 is involved in ribosomal subunit association. However, the two most important effects of L41 were on peptidyltransferase activity and translocation. Peptidyltransferase activity was measured as a second-order rate constant (k cat/K s ) corresponding to the rate of peptide bond formation; thisk cat/K s was lowered 3-fold to 1.15 min−1 mm −1 in the L41 mutant compared with 3.46 min−1mm −1 in the wild type. Translocation was also affected by L41. Elongation factor 2 (EF2)-dependent (enzymatic) translocation of Ac-Phe-tRNA from the A- to P-site was more efficient in the absence of L41, because 50% translocation was achieved at only 0.004 μm EF2 compared with 0.02 μm for the wild type. Furthermore, the EF2-dependent translocation was inhibited by 50% at 2.5 μm of the translocation inhibitor cycloheximide in the L41 mutant compared with 1.2 μm in the wild type. Finally, the rate of EF2-independent (spontaneous) translocation was increased in the absence of L41.

Kinetics of inhibition of peptide bond formation on bacterial ribosomes.

A cell-free system derived from Escherichia coli has been used in order to study the kinetics of inhibition of peptide bond formation with the aid of the puromycin reaction in solution. A similar study has been carried out earlier on a solid support matrix with the same inhibitors. We find that the overall pattern of the kinetics of inhibition is the same in the two systems. At low concentrations of inhibitor there is a competitive phase of inhibition, whereas at higher concentrations of inhibitor the type of inhibition becomes mixed noncompetitive. The values of Ki of the competitive phase in the system in solution are: 5.8 microM (amicetin), 0.2 microM (blasticidin S), 0.5 microM (chloramphenicol), and 0.5 microM (tevenel). The inhibitors amicetin, blasticidin S, and tevenel interact with the ribosome in a reaction which is slower than that of the substrate puromycin, showing clear-cut characteristics of slow-onset inhibition in both systems. Chloramphenicol, on the other hand does not easily show such a delay in solution. It interacts with the ribosome relatively faster than the other three antibiotics. Despite this, chloramphenicol too shows characteristics of time-dependent inhibition.

Two nucleotide substitutions in the A-site of yeast 18S rRNA affect translation and differentiate the interaction of ribosomes with aminoglycoside antibiotics.

Two mutations in the A-site of 18S rRNA of Saccharomyces cerevisiae were investigated. The first, A1491G (rdn15), creates in yeast the same C1409-G1491 base pair as in Escherichia coli and has behaved as an antisuppressor in genetic studies. Ribosomes from rdn15 are error-restrictive but their peptidyltransferase activity remains unchanged. The second mutation, U1495C (rdnhyg1), was initially isolated as a hygromycin-resistant mutation in Tetrahymena thermophila. We show that rdnhyg1 ribosomes are slightly error prone. Mutation rdnhyg1 does not affect catalytic activity, but it affects translocation, confirming the importance of nucleotide 1495 in the ratchet-like movement of the two subunits during translation. Paromomycin, an aminoglycoside antibiotic that binds to the ribosomal A-site, induces translational misreading and causes sensitivity to yeast cells. Mutation rdn15 is shown to be highly sensitive to both effects of paromomycin, while mutation rdnhyg1 is relatively resistant. Tobramycin, another aminoglycoside, does not affect the growth of yeast cells. Like paromomycin, however, it increases the error rate in rdn15 ribosomes relative to wild-type and decreases it in rdnhyg1 ribosomes. These mutations help define the role of two crucial sites in ribosome function and distinguish the modes of action of two aminoglycosides, a useful fact in the search for new strategies in drug design.

Photolabeling of protein components in the pactamycin binding site of rat liver ribosomes

The antitumoral and antibacterial drug pactamycin can be radioactively labeled by iodination without loss of biological activity. Using the labeled pactamycin, the ribosomal binding site of the drug on rat liver ribosomes has been studied by affinity labeling techniques taking advantage of the photoreactive acetophenone group present in the molecule. When 40 S ribosomal subunits are labeled, one major spot of radioactivity is found associated to protein S25. In addition, weaker spots related to proteins S14/15, S10, S17 and S7 can also be detected in the autoradiogram of the two-dimensional gel slab. Since pactamycin inhibits protein synthesis initiation, the proteins forming its binding site must be related to some step of this process. By comparison with results from pactamycin affinity labeling of Escherichia coli ribosomes (Tejedor, F., Amils, R. and Ballesta, J.P.G. (1985) Biochemistry 24, 3667-3672) these proteins could lie in the mRNA and initiation factors binding region of the rat liver ribosome.