Spectroscopic and computational studies of the azide-adduct of manganese superoxide dismutase: definitive assignment of the ligand responsible for the low-temperature thermochromism.

Abstract

A variety of spectroscopic and computational techniques have been used to examine the thermochromic transition previously reported for the oxidized state of Mn-dependent superoxide dismutase from E. coli in the presence of substrate analog azide (N(3)-Mn(3+)SOD).[Whittaker, M. M.; Whittaker, J. W. Biochemistry 1996, 35, 6762-6770.] Although previous spectroscopic studies had shown that this thermochromic event corresponds to a change in coordination number of the active-site Mn(3+) ion from 6 to 5 as temperature is increased, the ligand that dissociates in this conversion had yet to be identified. Through the use of electronic absorption, circular dichroism (CD), and magnetic CD (MCD) spectroscopies, both d-->d and ligand-to-metal charge-transfer (LMCT) transition energies have been determined for native Mn(3+)SOD (possessing a five-coordinate Mn(3+) center) and Y34F N(3)-Mn(3+)SOD (forming a six-coordinate N(3)-Mn(3+) adduct at all temperatures). These two systems provide well-defined reference points from which to analyze the absorption and CD data obtained for N(3)-Mn(3+)SOD at room temperature (RT). Comparison of excited-state spectroscopic data reveals that Mn(3+)SOD and RT N(3)-Mn(3+)SOD exhibit virtually identical d-->d transition energies, suggesting that these two species possess similar geometric and electronic structures and, thus, that azide does not actually coordinate to the active-site Mn(3+) ion at RT. However, resonance Raman spectra of both N(3)-Mn(3+)SOD and Y34F N(3)-Mn(3+)SOD at 0 degrees C exhibit azide-related vibrations, indicating that azide does interact with the active site of the native enzyme at this temperature. To gain further insight into the nature of the azide/Mn(3+) interaction in RT N(3)-Mn(3+)SOD, several viable active-site models designed to promote either dissociation of coordinated solvent, Asp167, or azide were generated using DFT computations. By utilizing the time-dependent DFT method to predict absorption spectra for these models of RT N(3)-Mn(3+)SOD, we demonstrate that only azide dissociation is consistent with experimental data. Collectively, our spectroscopic and computational data provide evidence that the active site of N(3)-Mn(3+)SOD at RT exists in a dynamic equilibrium, with the azide molecule either hydrogen-bonded to the second-sphere Tyr34 residue or coordinated to the Mn(3+) ion. These results further highlight the role that second-sphere residues, especially Tyr34, play in tuning substrate (analog)/metal ion interactions.