Study on conformational states of Escherichia coli tRNAPhe in solution by a modulation-free ESR-spectrometer.

A modulation free Electron Spin Resonance spectrometer was used for the registration of spectral absorption lines of a spin-labeled Escherichia coli phenylalanine tRNA in solution with low (less than 0.1%) line shape distortion. The analysis of line shape of two different spin-labels introduced into position 8 revealed that phenylalanine tRNA in solution exists as a mixture of two conformers, the equilibria between conformers being dependent on pH, concentration of magnesium and functional state of tRNA (deacylated, aminoacylated or peptidylated). There are no overall structural rearrangements upon aminoacylation or peptidylation of tRNA. The observed small changes of spectral line shape can be assigned to shifts in conformational equilibria.

Interaction of N-acetyl-phenylalanyl-tRNAPhe with 70S ribosomes of Escherichia coli.

The interaction of N--Acetyl--Phe--tRNA Phe with 70 S ribosomes is a reversible process in the absence as well as in the presence of messenger. The equilibrium binding constants of these interactions were measured at different magnesium concentrations and temperatures and thermodynamical quantities computed. The enthalpy of the formation of complexes with the P site of ribosomes is larger by 6,000 cal/mol in the presence of poly (U) than in the presence of poly (C) or in total absence of messenger. Free energy differences are rather small, the association constants differ less than one order of magnitude. The association constant of N--Acetyl--Phe--tRNA Phe with the A site of ribosomes is 30--50 times lower than with the P site even in the presence of poly (U).

The interconversion of conformers of phenylalanyl-tRNA with different affinity to 70S ribosomes of Escherichia coli.

Earlier the existence of two conformers of Phe-tRNAPhe of E. coli was demonstrated because one of them yields complexes with 70S-poly(U) of extremely high affinity and the other with at least a 105 lower binding constant. We denote the first conformer as HAC (high affinity conformer) and the second as LAC (low affinity conformer). This high difference in binding constants was used for studying the process of reversible interconversion of conformers of Phe-tRNAPhe. The transition kinetics of LAC to HAC in conditions when the latter is stable (in the presence of magnesium ions) was studied and a high value of activation energy (35 kcal/mole) found. The interconversion is the first order reaction and equilibrium does not depend of overall Phe-tRNA concentration.