Luminescence and Binding Studies on tRNA Phe

Abstract

The phenylalanine transfer RNA of baker's yeast (tRNA^Phe) contains a base Y of unknown molecular structure next to the anticodon triplet. Since the base Y fluoresces at room temperature (λ_max = 431 nm), its emission properties offer a unique tool for studying conformational and binding properties of tRNA^Phe. The results obtained by these experiments include the following: (1) The quantum yield of fluorescence of Y in tRNA^Phe (φF) is 0.07 ± 0.01 at high Mg²⁺ concentrations (>10^-2 M) and about half that at 10^-3 M or less, indicating a [Mg²⁺]-dependent conformational change of the anticodon loop. (2) The fluorescence of Y isolated from tRNAPhe (Y⁺) is red-shifted by 15 nm compared to Y in tRNA^Phe which suggests a stacked (more hydrophobic) environment for Y in the intact anticodon loop. φF of Y⁺ is 0.035. (3) The solvent isotope effect φF(D₂O)/φF(H₂O) is 1.5 for tRNA^Phe and 1.9 for Y⁺ i.e., Y in tRNA is still hydrated. (4) The temperature dependence of φF in a polar glass shows that quenching occurs only at temperatures at which the glass has sufficiently low viscosity to permit solvent shell relaxation in the excited state. The low-temperature (80°K) fluorescence is blue shifted (λ_max = 409 nm) and the phosphorescence has a decay time of 1.5 seconds, a threshold at 392 nm and a spectral shape like that of guanine. (5) In the presence of 10^-2 M Mg²⁺ penta-uridylate, which contains the codon triplet, a small blue shift and a decrease in φF are observed. This shift can be used to establish the formation of a binary complex between the codon and the anticodon with an association constant of 4 × 10² M^-1, approximately. A similar complex is formed with poly-uridylate but not with poly-cytidylate. In the absence of Mg²⁺ the binary complex is not formed.