Elisabeth Cadieux scite author profile

A three-component soluble methane monooxygenase (sMMO) enzyme system catalyzes the hydroxylation of methane to methanol at a carboxylate-bridged diiron center housed in the alpha-subunit of the hydroxylase (MMOH). Catalysis is facilitated by the presence of a regulatory protein (MMOB) and inhibited by MMOD, a protein of unknown function encoded in the sMMO operon. Both MMOB and MMOD are presumed to bind to the same region of the MMOH alpha-subunit. A colorimetric method for monitoring removal of Fe(II) from MMOH was developed using 1,10-phenanthroline and yields apo MMOH with <0.1 Fe/homodimer. With the use of this method, it was possible to investigate the X-ray structure of the apoenzyme and to perform metal reconstitution studies. Using MMOH from Methylococccus capsulatus (Bath), the effects of MMOB and MMOD on metal binding were studied and structural perturbations relevant to the function of this enzyme were identified. X-ray crystal structures of the apo, Mn(II)-soaked, and Co(II)-grown MMOH, determined to 2.3 A or greater resolution, reveal that the presence of metal ions is essential for the proper folding of helices E, F, and H of the alpha-subunit. The active sites of Mn(II)-soaked and Co(II)-grown MMOH are similar to that of reduced, native MMOH with notable differences in the metal-metal distances and ligand coordination sphere that may reflect how this dinuclear metal center might change in the presence of MMOB. MMOB and MMOD decrease the rate of removal of Fe(II) from the enzyme by 22- and 16-fold, respectively. On the basis of previous studies, it is hypothesized that MMOB, and perhaps MMOD, function to block solvent access to the MMOH active site. Finally, ITC studies and the observed disorder in helices E, F, and H in the apo and Mn(II)-soaked structures suggest that these regions of MMOH are critical for MMOB and MMOD binding.

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Biochemical, Mössbauer, and EPR Studies of the Diiron Cluster of Phenol Hydroxylase from Pseudomonas sp. Strain CF 600

Cadieux

Vrajmasu

Achim

et al. 2002

Biochemistry

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Phenol hydroxylase of Pseudomonas sp. strain CF600 comprises three components: DmpP is an FAD- and [2Fe-2S]-containing reductase; DmpM is a cofactorless activator protein; and DmpLNO is the oxygenase. Single turnover experiments established that DmpLNO contains the active site, but requires DmpM for efficient turnover: the steady-state turnover rate reaches a maximum at 1.5 DmpM:1 DmpLNO. Chemical cross-linking experiments showed that DmpM interacts with the large subunit of the DmpLNO oxygenase complex. Mössbauer studies revealed that the active site of the oxygenase can accommodate two types of diiron clusters, each of these cluster types having two equivalent sites. Cluster form I, representing typically around 85% of total Fe, has DeltaE(Q) = 1.73 mm/s and delta = 0.54 mm/s, while cluster II exhibits DeltaE(Q) = 0.79 mm/s and delta = 0.48 mm/s. Studies in strong applied magnetic fields suggest that the two iron sites of cluster I are bridged by an oxo group while sites in cluster II appear to be hydroxo-bridged. Reduction of the samples with dithionite yields the diferrous forms of the clusters. Air oxidation of the reduced samples leads to an increase of the cluster II fraction, accompanied by a corresponding decrease in catalytic activity. The reduced oxygenase samples exhibit at X-band an integer spin EPR signal centered, in parallel mode, at g = 16.6. Quantitative analysis showed that 19% of the clusters contribute to the EPR signal, suggesting that cluster II is the EPR-active species. Incubation with dithiothreitol (DTT) inactivated the oxygenase by a mechanism apparently involving H(2)O(2) generation. In addition, Mössbauer studies of DTT-inactivated enzyme showed that all ferric iron belonged to one diamagnetic diferric cluster with parameters that indicate that DTT coordinates to the cluster.

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On the Role of DmpK, an Auxiliary Protein Associated with Multicomponent Phenol Hydroxylase from Pseudomonas sp. Strain CF600

Powlowski

Sealy

Shingler

et al. 1997

Journal of Biological Chemistry

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DmpK from Pseudomonas sp. strain CF600 represents a group of proteins required by phenol-degrading bacteria that utilize a multicomponent iron-containing phenol hydroxylase. DmpK has been overexpressed in Escherichia coli and purified to homogeneity; it lacks redox cofactors and was found to strongly inhibit phenol hydroxylase in vitro. Chemical cross-linking experiments established that DmpK binds to the two largest subunits of the oxygenase component of the hydroxylase; this may interfere with binding of the hydroxylase activator protein, DmpM, causing inhibition. Since expression of DmpK normally appears to be much lower than that of the components of the oxygenase, inhibition may not occur in vivo. Hence, the interaction between DmpK and the oxygenase manifested in the inhibition and crosslinking results prompted construction of E. coli strains in which the oxygenase component was expressed in the presence and absence of a low molar ratio of DmpK. Active oxygenase was detected only when expressed in the presence of DmpK. Furthermore, inactive oxygenase could be activated in vitro by adding ferrous iron, in a process that was dependent on the presence of DmpK. These results indicate that DmpK plays a role in assembly of the active form of the oxygenase component of phenol hydroxylase.

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Characterization of Active and Inactive Forms of the Phenol Hydroxylase Stimulatory Protein DmpM

Cadieux

Powlowski

1999

Biochemistry

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The stimulatory protein DmpM of phenol hydroxylase from methylphenol-degrading Pseudomonas sp. strain CF600 has been found to exist in two forms. DmpM purified from the native strain was mostly active in stimulating phenol hydroxylase activity, whereas an inactive form accumulated in a recombinant strain. Both forms exhibited a molecular mass of 10 361.3 +/- 1.3 Da by electrospray mass spectrometry, but nondenaturing gel filtration showed molecular masses of 31 600 Da for the inactive form and 11 500 Da for the active form. Cross-linking and sedimentation velocity results were consistent with the inactive form being a dimer. Partial thermal or chemical denaturation, or treatment with trifluoroethanol, readily activated dimeric DmpM. A combination of circular dichroism and fluorescence spectroscopies, activity assays, and native and urea gel electrophoresis were used to further characterize reactivation with urea. These results showed that dissociation of the dimeric form of DmpM precedes denaturation at low protein concentrations and results in activation. The same concentration of urea that effects dissociation also converts the monomeric form to a different conformation.

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