Soluble Methane Monooxygenase Component Interactions Monitored by <sup>19</sup>F NMR

Jones, Jason C.; Banerjee, Rahul; Shi, Ke; Semonis, Manny M.; Aihara, Hideki; Pomerantz, William C. K.; Lipscomb, John D.

doi:10.1021/acs.biochem.1c00293

Cited by 11 publications

(25 citation statements)

References 67 publications

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“…Indeed, recent studies suggest that O 2 binding, activation, and the reaction of the activated species with hydrocarbons occurs in the sMMOH:MMOB complex after dissociation of MMOR. 27 The kinetic, regiospecific, and structural changes in sMMOH and sMMOH catalysis caused by MMOB binding have been investigated by several approaches, but none has been more informative than the application of targeted MMOB variants. 21,[27][28][29][32][33][34]37,44,45 The crystal structures of the MMOB variants in complex with sMMOH shown in this report reveal discrete and distinct perturbations within sMMOH.…”

Section: ■ Discussionmentioning

confidence: 99%

“…27 The kinetic, regiospecific, and structural changes in sMMOH and sMMOH catalysis caused by MMOB binding have been investigated by several approaches, but none has been more informative than the application of targeted MMOB variants. 21,[27][28][29][32][33][34]37,44,45 The crystal structures of the MMOB variants in complex with sMMOH shown in this report reveal discrete and distinct perturbations within sMMOH. Some of these changes can now be correlated with the effects on catalysis and regulation seen during sMMO turnover, and these aspects are discussed here.…”

Section: ■ Discussionmentioning

confidence: 99%

“…25,26 The final and perhaps most elegant aspect of MMOB regulation is described by a recently proposed dynamic equilibrium model that explains how sMMO avoids reductive quenching of Q by MMOR. 27 MMOB and MMOR were shown to bind with similar affinities to sMMOH and to compete for the same binding site near the buried diiron cluster. The distinct roles of MMOR and MMOB, diiron cluster reduction versus O 2 binding, respectively, are manifested only when the correct pair of sMMO components forms a complex.…”

Section: ■ Introductionmentioning

confidence: 92%

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X-ray Crystal Structures of Methane Monooxygenase Hydroxylase Complexes with Variants of Its Regulatory Component: Correlations with Altered Reaction Cycle Dynamics

et al. 2021

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Full activity of soluble methane monooxygenase (sMMO) depends upon the formation of a 1:1 complex of the regulatory protein MMOB with each alpha subunit of the (αβγ)2 hydroxylase, sMMOH. Previous studies have shown that mutations in the core region of MMOB and in the N- and C-termini cause dramatic changes in the rate constants for steps in the sMMOH reaction cycle. Here, X-ray crystal structures are reported for the sMMOH complex with two double variants within the core region of MMOB, DBL1 (N107G/S110A), and DBL2 (S109A/T111A), as well as two variants in the MMOB N-terminal region, H33A and H5A. DBL1 causes a 150-fold decrease in the formation rate constant of the reaction cycle intermediate P, whereas DBL2 accelerates the reaction of the dinuclear Fe(IV) intermediate Q with substrates larger than methane by three- to fourfold. H33A also greatly slows P formation, while H5A modestly slows both formation of Q and its reactions with substrates. Complexation with DBL1 or H33A alters the position of sMMOH residue R245, which is part of a conserved hydrogen-bonding network encompassing the active site diiron cluster where P is formed. Accordingly, electron paramagnetic resonance spectra of sMMOH:DBL1 and sMMOH:H33A complexes differ markedly from that of sMMOH:MMOB, showing an altered electronic environment. In the sMMOH:DBL2 complex, the position of M247 in sMMOH is altered such that it enlarges a molecular tunnel associated with substrate entry into the active site. The H5A variant causes only subtle structural changes despite its kinetic effects, emphasizing the precise alignment of sMMOH and MMOB required for efficient catalysis.

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Section: ■ Discussionmentioning

confidence: 99%

Section: ■ Discussionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 92%

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X-ray Crystal Structures of Methane Monooxygenase Hydroxylase Complexes with Variants of Its Regulatory Component: Correlations with Altered Reaction Cycle Dynamics

et al. 2021

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“…ΔΔG < 0 indicates that the mutant is more stable than the wild-type. The thermostability of multiple proteins has been improved using the PoPMuSiC algorithm [9,28,29]. HoTMuSiC is a computational tool that uses an artificial neural network to predict the change in melting temperature ΔT m , upon the introduction of single-point mutations, based on the imperfect correlation of thermodynamics and thermal stabilities [30].…”

Section: Selection Of Thermostability Predicting Software Programs and Mutation Screening Principlesmentioning

confidence: 99%

“…However, owing to their unpredictability and long-range effects, mutants with improved thermostability are not readily obtained [5,6]. With the development of structural and computational biology, protein structures can be obtained efficiently through experimental determination and computational prediction [7][8][9][10]. In recent years, based on protein structure and energy function, the prediction of mutations stabilizing the folded protein structure has improved considerably.…”

Section: Introductionmentioning

confidence: 99%

Rational Design of Pepsin for Enhanced Thermostability via Exploiting the Guide of Structural Weakness on Stability

et al. 2021

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Enzyme thermostability is an important parameter for estimating its industrial value. However, most naturally produced enzymes are incapable of meeting the industrial thermostability requirements. Software programs can be utilized to predict protein thermostability. Despite the fast-growing number of programs designed for this purpose; few provide reliable applicability because they do not account for thermodynamic weaknesses. Aspartic proteases are widely used in industrial processing; however, their thermostability is not able to meet the large-scale production requirements. In this study, through analyzing structural characteristics and modifying thermostability using prediction software programs, we improved the thermostability of pepsin, a representative aspartic protease. Based on the structural characteristics of pepsin and the experimental results of mutations predicted by several energy-based prediction software programs, it was found that the majority of pepsin’s thermodynamic weaknesses lie on its flexible regions on the surface. Using computational design, mutations were made based on the predicted sites of thermodynamic weakness. As a result, the half-lives of mutants D52N and S129A at 70°C were increased by 200.0 and 66.3%, respectively. Our work demonstrated that in the effort of improving protein thermostability, identification of structural weaknesses with the help of computational design, could efficiently improve the accuracy of protein rational design.

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Unidentical Twins: Geometrically Similar but Chemically Distinct Metal‐Free Sites in Boron Oxide for Methane Oxidation to HCHO, CO and CO₂

Rawal,

Gupta

2024

Chemistry A European J

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Metal‐free boron‐based catalysts such as boron oxide (B2O3) and boron nitride (h‐BN) are promising catalysts for the methane oxidation to HCHO and CO. The B2O3 catalyst contains various probable boron sites (B1 to B6), which may be responsible for methane oxidation. In this work, we utilized density functional theory to compare two relevant geometrically identical boron sites (B2 and B4) for their reactivities. The two sites are explored in‐detail for the conversion of methane to formaldehyde (M2F), carbon monoxide and carbon dioxide. The B4 site activates the methane C−H bond easily as compared to the B2 site. In M2F conversion, the rate‐determining step for the B2 site is the co‐activation of dioxygen and methane, whereas over the B4 site, formaldehyde formation is the rate‐determining step. The computationally‐determined RDS for the B4 site coincides well with the reported experiments. It is further revealed that this site also prefers the formation of CO over CO2, which is in‐line with the experiments in literature. It is also shown through orbital analysis that methanol formation does not occur during methane oxidation. We employed descriptors such as condensed Fukui functions and global electrophilicity index to chemically distinct these twin sites.

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Soluble Methane Monooxygenase Component Interactions Monitored by ¹⁹F NMR

Cited by 11 publications

References 67 publications

X-ray Crystal Structures of Methane Monooxygenase Hydroxylase Complexes with Variants of Its Regulatory Component: Correlations with Altered Reaction Cycle Dynamics

X-ray Crystal Structures of Methane Monooxygenase Hydroxylase Complexes with Variants of Its Regulatory Component: Correlations with Altered Reaction Cycle Dynamics

Rational Design of Pepsin for Enhanced Thermostability via Exploiting the Guide of Structural Weakness on Stability

Unidentical Twins: Geometrically Similar but Chemically Distinct Metal‐Free Sites in Boron Oxide for Methane Oxidation to HCHO, CO and CO₂

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Soluble Methane Monooxygenase Component Interactions Monitored by 19F NMR

Cited by 11 publications

References 67 publications

X-ray Crystal Structures of Methane Monooxygenase Hydroxylase Complexes with Variants of Its Regulatory Component: Correlations with Altered Reaction Cycle Dynamics

X-ray Crystal Structures of Methane Monooxygenase Hydroxylase Complexes with Variants of Its Regulatory Component: Correlations with Altered Reaction Cycle Dynamics

Rational Design of Pepsin for Enhanced Thermostability via Exploiting the Guide of Structural Weakness on Stability

Unidentical Twins: Geometrically Similar but Chemically Distinct Metal‐Free Sites in Boron Oxide for Methane Oxidation to HCHO, CO and CO2

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Product

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Soluble Methane Monooxygenase Component Interactions Monitored by ¹⁹F NMR

Unidentical Twins: Geometrically Similar but Chemically Distinct Metal‐Free Sites in Boron Oxide for Methane Oxidation to HCHO, CO and CO₂