Steady-state kinetic analysis of soluble methane mono-oxygenase from Methylococcus capsulatus (Bath).

Abstract

A steady-state kinetic analysis of purified soluble methane mono-oxygenase of Methylococcus capsulatus (Bath) was performed. The enzyme was found to follow a concerted-substitution mechanism. Methane binds to the enzyme followed by NADH, which reacts to yield reduced enzyme and NAD+. The reduced enzyme-methane complex binds O2 to give a second ternary complex, which breaks down to release water and methanol. In this way the enzyme can control the supply of electrons to the active site to coincide with the arrival of methane. Product-inhibition studies (with propylene as substrate) supported the reaction mechanism proposed. Ki values for NAD+ and propylene oxide are reported. The Km for NADH varied from 25 microM to 300 microM, depending on the nature of the hydrocarbon substrate, and thus supports the proposed reaction sequence. With methane as substrate the Km values for methane, NADH and O2 were shown to be 3 microM, 55.8 microM and 16.8 microM respectively. With propylene as substrate the Km values for propylene, NADH and O2 were 0.94 microM, 25.2 microM and 12.7-15.9 microM respectively. Methane mono-oxygenase was shown to be well adapted to the oxidation of methane compared with other straight-chain alkanes.