Many tRNAs undergo tertiary folding transitions at temperatures well below the main thermally induced (hyperchromic) transition. Such transitions are essentially isochromic and isoenthalpic and display an absolute requirement for divalent cations; however, the nature of the structural transition is not known for any tRNA. Using a combination of transient electric birefringence (TEB) and gel electrophoretic measurements, we have characterized the influence of magnesium ions on the apparent angle between the anticodon and acceptor stems of a yeast tRNA(Phe) construct. TEB is a particularly sensitive method for quantifying the bends introduced in RNA by various nonhelix elements. In the current instance, the tRNA construct comprises an unmodified tRNA(Phe) molecule in which the anticodon and acceptor stems have been extended by approximately 70 bp to more effectively "report" the interstem angles. Upon the addition of sub-millimolar concentrations of magnesium ions, the tRNA core undergoes a substantial rearrangement in tertiary structure, passing from an open form with an apparent interstem angle of approximately 150 degrees to a conformation with an interstem angle of approximately 70 degrees (200 microM Mg2+). Further addition of magnesium ions results in a minor adjustment of the apparent interstem angle to approximately 80-90 degrees, in line with earlier results. Finally, the magnesium-induced structural transition is essentially isochromic, in agreement with previous observations with native tRNAs. The current results suggest that changes in local divalent ion concentration in the ribosome could profoundly affect the global conformations of tRNAs during the translation cycle.