EPR of Cu+2 binding to apo-yeast enolase.

We have studied the electron paramagnetic resonance (epr) spectra of complexes of apo-yeast enolase with 65Cu+2 in the presence and absence of substrate and magnesium ion. An unusual epr spectrum with large g parallel, large g and A rhombicity and very narrow line-widths (10 G) is seen for the first two 65Cu+2 bound in the presence of substrate 2-phosphoglycerate (2PGA). the epr parameters, consistent with rhombic and tetragonal distortion of an octahedral geometry of the coordination sphere of the Cu+2 are g = (2.123, 2.042, 2.405) and A = (2.58, 4.19, 12.0) mK. The high g parallel and absence of super-hyperfine splitting are strong evidence for absence of nitrogen ligands. In the presence of Mg+2 and 2PGA, the Cu+2-enolase solutions exhibit a complex epr spectrum reflecting exchange and dipolar interaction between the first two Cu+2 ions bound. The spectra of Cu+2 plus enolase in the presence and absence of Mg+2 without 2PGA are distinct but not unambiguous, each reflecting at least two inequivalent binding sites. In addition to providing information on the geometry and location of the divalent cation binding sites, the data show unequivocally that imidazole residues, previously found to have a role in catalysis, do not participate in Cu+2 binding. Although Cu+2 does not activate the enzyme, direct binding measurements show that Cu+2 competes stoichiometrically with the activating ion, Mg+2. A reinterpretation of earlier Mn+2 enolase studies is proposed to reconcile the Cu+2 and Mn+2 data.