Nanosecond transient absorption spectroscopy of coenzyme B12. Quantum yields and spectral dynamics.

Photolysis of adenosylcobalamin leads to homolytic cleavage, similar to many of the B12-dependent enzyme reactions. Therefore, we have used photolysis to study the structure and lability of the cobalt-carbon bond. The nanosecond quantum yield for adenosylcobalamin is 0.23 +/- 0.04, higher than reported previously. The acidified form of adenosylcobalamin, so called "base-off" B12, has a much lower quantum yield at 0.045 +/- 0.015, demonstrating an inverse correlation between cobalt-carbon bond strength and quantum yield. Investigation of the wavelength dependence of the quantum yield shows that there is a highly efficient transmission of energy from the corrin ring to the cobalt-carbon bond. A comparison of nanosecond transient and static spectra showed small spectral differences. Therefore, any spectral relaxation of a sterically distorted corrin ring may be detectable only at sub-nanosecond timescales. Spectral analysis also provides data on the kinetics of recombination. In the absence of enzyme, geminate rebinding must be substantial, since the rate of Co(II) and deoxyadenosyl radical recombination is near the diffusion controlled limit. Therefore, it is likely that the enzyme functions to pull the geminate partners apart, perhaps as suggested previously, through a conformational change. The importance of geminate recombination in the mechanism of homolytic cleavage is further supported by a comparison of our results with picosecond transient absorption studies.