Hydrogen burst associated with nitrogenase-catalyzed reactions.

Abstract

We have used a membrane-leak mass spectrometer to follow the time courses of H2 evolution and substrate reduction by nitrogenase [reduced ferredoxin:dinitrogen oxidoreductase (ATP-hydrolyzing), EC 1.18.6.1]. In the absence of added substrates, dinitrogenase passes all of its electrons to protons to form H2, but when a reducible substrate is added the electrons from dinitrogenase are shared between protons and the added substrate so that the steady-state rate of H2 production is decreased. If a reducible substrate is added before the nitrogenase reaction is initiated, a pre-steady-state burst of H2 is evident upon initiation of the reaction. This burst is associated with all the substrates of nitrogenase examined i.e., N2, N2O, C2H2, NaN3, and NaCN. The H2 burst is stoichiometric with dinitrogenase, but not with dinitrogenase reductase. In the H2 burst phase, 1 H2 is evolved per dinitrogenase molybdenum. Although a change in the ratio of nitrogenase components changed the initial rate of the H2 burst, the stoichiometry was not affected. Production of H2 by the burst in the presence of a high concentration of substrate is terminated after production of 1 H2 per dinitrogenase molybdenum, and a steady-state rate of H2 production is established. This response suggests that the H2 burst is not a catalytic event but a result of a once-only activation process.