Methane monooxygenase (MMO) catalyzes the energy dependent oxidation of methane to methanol in methanotrophic bacteria. 1, 2 In these organisms two different methane monooxygenases have been identified, namely a membrane-associated or particulate MMO (pMMO) and a cytoplasmic or soluble MMO (sMMO). In methanotrophs that express both forms of the enzyme, the copper concentration during growth dictates which MMO is expressed. 2-5 In cells cultured under a low copper/biomass ratio, the sMMO is predominately expressed, whereas cells cultured at higher copper/biomass ratios exclusively express the pMMO (sMMO is not transcribed). 6-8 The sMMO is a well characterized three-component enzyme consisting of a hydroxylase, a reductase and a regulatory protein. 9-12 Spectroscopic and X-ray crystallographic studies have established that the hydroxylase contains an oxygen bridged diiron cluster. 13-16 Here we provide evidence that pMMO contains a diiron cluster as well.Owing to the low specific activity and instability of most pMMO preparations, 6, 17-20 comparatively little is known about the molecular properties of this enzyme. As isolated, pMMO is composed of three polypeptides with molecular masses of 45,000, 26,000, and 23,000 Da with a subunit structure of (αβγ) 3 . 6, 17, 18, 20-22 Most researchers agree that each αβγ contains 2 -3 Cu atoms 2, 6, 17-20, 23 although one group has suggested that 15 Cu atoms are arranged into catalytic and electron transfer trinuclear copper clusters. 22, 24, 25 The 2.8 Å resolution crystal structure of pMMO revealed that each αβγ contained a dicopper site, a mononuclear copper site, and a third site occupied by zinc. 21, 23 However, the preparation used for growing the crystal was inactive and did not contain zinc (which was added to the crystallization buffer). 21, 23The involvement of non-heme iron in methane oxidation by the pMMO has been proposed by some laboratories 6, 17, 26-29 and disputed by others. 22, 24, 30 In our laboratory at Iowa State University we have observed that preparations of pMMO showing highest specific activity contain 1-2 iron atoms. 6 We therefore decided to employ Mössbauer spectroscopy to characterize the iron components. This technique is particularly well suited to explore iron environments that are EPR-silent and optically uninformative in the visible region, as is the Author E-mail : emunck@cmu.edu. Table 1 lists analytical and activity data of our purified pMMO sample and of whole cells grown at high copper (80μM) and iron (40μM); the entries are discussed in the Supporting Information. Figure 1 shows 4.2 K Mössbauer spectra of purified pMMO. The central portion of the 45 mT spectrum ( Figure 1A) exhibits two overlapping doublets with ΔE Q (1) = 1.05 mm/ s, δ(1) = 0.50 mm/s (≈20% of total Fe) and ΔE Q (2) = 2.65 mm/s, δ(1) = 1.25 mm/s (≈18% of total Fe); the δ value of doublet 2 is characteristic of a high-spin Fe 2+ with octahedral N/O coordination. The majority of the iron in the spectrum of Figure 1A, perhaps up to 60% of total Fe, belongs to a heter...
