Geometric and electronic structure studies of the binuclear nonheme ferrous active site of toluene-4-monooxygenase: parallels with methane monooxygenase and insight into the role of the effector proteins in O2 activation.

Multicomponent monooxygenases, which carry out a variety of highly specific hydroxylation reactions, are of great interest as potential biocatalysts in a number of applications. These proteins share many similarities in structure and show a marked increase in O2 reactivity upon addition of an effector component. In this study, circular dichroism (CD), magnetic circular dichroism (MCD), and variable-temperature, variable-field (VTVH) MCD have been used to gain spectroscopic insight into the Fe(II)Fe(II) active site in the hydroxylase component of Toluene-4 monoxygenase (T4moH) and the complex of T4moH bound by its effector protein, T4moD. These results have been correlated to spectroscopic data and density functional theory (DFT) calculations on MmoH and its interaction with MmoB. Together, these data provide further insight into the geometric and electronic structure of these biferrous active sites and, in particular, the perturbation associated with component B/D binding. It is found that binding of the effector protein changes the geometry of one iron center and orientation of its redox active orbital to accommodate the binding of O2 in a bridged structure for efficient 2-electron transfer that can form a peroxo intermediate.

Crystal structures and functional studies of T4moD, the toluene 4-monooxygenase catalytic effector protein.

Toluene 4-monooxygenase (T4MO) is a four-component complex that catalyzes the regiospecific, NADH-dependent hydroxylation of toluene to yield p-cresol. The catalytic effector (T4moD) of this complex is a 102-residue protein devoid of metals or organic cofactors. It forms a complex with the diiron hydroxylase component (T4moH) that influences both the kinetics and regiospecificity of catalysis. Here, we report crystal structures for native T4moD and two engineered variants with either four (DeltaN4-) or 10 (DeltaN10-) residues removed from the N-terminal at 2.1-, 1.7-, and 1.9-A resolution, respectively. The crystal structures have C-alpha root-mean-squared differences of less than 0.8 A for the central core consisting of residues 11-98, showing that alterations of the N-terminal have little influence on the folded core of the protein. The central core has the same fold topology as observed in the NMR structures of T4moD, the methane monooxygenase effector protein (MmoB) from two methanotrophs, and the phenol hydroxylase effector protein (DmpM). However, the root-mean-squared differences between comparable C-alpha positions in the X-ray structures and the NMR structures vary from approximately 1.8 A to greater than 6 A. The X-ray structures exhibit an estimated overall coordinate error from 0.095 (0.094) A based on the R-value (R free) for the highest resolution DeltaN4-T4moD structure to 0.211 (0.196) A for the native T4moD structure. Catalytic studies of the DeltaN4-, DeltaN7-, and DeltaN10- variants of T4moD show statistically insignificant changes in k(cat), K(M), k(cat)/K(M), and K(I) relative to the native protein. Moreover, there was no significant change in the regiospecificity of toluene oxidation with any of the T4moD variants. The relative insensitivity to changes in the N-terminal region distinguishes T4moD from the MmoB homologues, which each require the approximately 33 residue N-terminal region for catalytic activity.

Insight into the mechanism of aromatic hydroxylation by toluene 4-monooxygenase by use of specifically deuterated toluene and p-xylene.

The present studies address the mechanism of aromatic hydroxylation used by the natural and G103L isoforms of the diiron enzyme toluene 4-monooxygenase. These isoforms have comparable catalytic parameters but distinct regiospecificities for toluene hydroxylation. Hydroxylation of ring-deuterated p-xylene by the natural isoform revealed a substantial inverse isotope effect of 0.735, indicating a change in hybridization from sp(2) to sp(3) for hydroxylation at a carbon atom bearing the deuteron. During the hydroxylation of 4-(2)H(1)- and 3,5-(2)H(2)-toluene, similar magnitudes of intramolecular isotope effects and patterns of deuterium retention were observed from both isoforms studied, indicating that the active-site mutation affected substrate orientation but did not influence the mechanism of hydroxylation. The results with deuterated toluenes show inverse intramolecular isotope effects for hydroxylation at the position of deuteration, normal secondary isotope effects for hydroxylation adjacent to the position of deuteration, near-quantitative deuterium retention in m-cresol obtained from 4-(2)H(1)-toluene, and partial loss of deuterium from all phenolic products obtained from 3,5-(2)H(2)-toluene. This combination of results suggests that an active site-directed opening of position-specific transient epoxide intermediates may contribute to the chemical mechanism and the high degree of regiospecificity observed for aromatic hydroxylation in this evolutionarily specialized diiron enzyme.

Crystallization and preliminary analysis of native and N-terminal truncated isoforms of toluene-4-monooxygenase catalytic effector protein.

Single crystals have been obtained of the toluene 4-monooxygenase catalytic effector protein, the SeMet-enriched protein and a truncated isoform missing ten amino acids from the N-terminus. Complete X-ray diffraction data sets have been collected and analyzed to 2.0, 3.0 and 1.96 A resolution for the native, SeMet and truncated isoform crystals, respectively. The native and SeMet proteins crystallized in space group P6(1)22 (unit-cell parameters a = b = 86.41 +/- 0.15, c = 143.90 +/- 0.27 A), whereas the truncated isoform crystallized in space group P2(1)3 (a = b = c = 86.70 +/- 0.47 A). Matthews coefficient calculations suggest either two or three molecules per asymmetric unit in the P6(1)22 space group and two molecules per asymmetric unit in the P2(1)3 space group. Experimental phases from MAD analysis of the SeMet isoform and molecular replacement of the truncated isoform confirm the presence of two molecules per asymmetric unit in each case. These crystallographic results are the first available for the evolutionarily related but functionally diversified catalytic effector proteins from the multicomponent diiron monooxygenase family.

Combined participation of hydroxylase active site residues and effector protein binding in a para to ortho modulation of toluene 4-monooxygenase regiospecificity.

Toluene 4-monooxygenase (T4MO) is a diiron hydroxylase that exhibits high regiospecificity for para hydroxylation. This fidelity provides the basis for an assessment of the interplay between active site residues and protein complex formation in producing an essential biological outcome. The function of the T4MO catalytic complex (hydroxylase, T4moH, and effector protein T4moD) is evaluated with respect to effector protein concentration, the presence of T4MO electron-transfer components (Rieske ferredoxin, T4moC, and NADH oxidoreductase), and use of mutated T4moH isoforms with different hydroxylation regiospecificities. Steady-state kinetic analyses indicate that T4moC and T4moD form complexes of similar affinity with T4moH. At low T4moD concentrations, the steady-state hydroxylation rate is linearly dependent on T4moD-T4moH complex formation, whereas regiospecificity and the coupling efficiency between NADH consumption and hydroxylation are associated with intrinsic properties of the T4moD-T4moH complex. The optimized complex gives both efficient coupling and high regiospecificity with p-cresol representing >96% of total products from toluene. Similar coupling and regiospecificity for para hydroxylation are obtained with T3buV (an effector protein from a toluene 3-monooxygenase), demonstrating that effector protein binding does not uniquely determine or alter the regiospecificity of toluene hydroxylation. The omission of T4moD causes an approximately 20-fold decrease in hydroxylation rate, nearly complete uncoupling, and a decrease in regiospecificity so that p-cresol represents approximately 60% of total products. Similar shifts in regiospecificity are observed in oxidations of alternative substrates in the absence or upon the partial removal of either T4moD or T3buV from toluene oxidations. The mutated T4moH isoforms studied have apparent V(max)/K(M) specificities differing by approximately 2-4-fold and coupling efficiencies ranging from 88% to 95%, indicating comparable catalytic function, but also exhibit unique regiospecificity patterns for all substrates tested, suggesting unique substrate binding preferences within the active site. The G103L isoform has enhanced selectivity for ortho hydroxylation with all substrates tested except nitrobenzene, which gives only m-nitrophenol. The regiospecificity of the G103L isoform is comparable to that observed from naturally occurring variants of the toluene/benzene/o-xylene monooxygenase subfamily. Evolutionary and mechanistic implications of these findings are considered.