Regulating the nitrite reductase activity of myoglobin by redesigning the heme active center

Wu, Lei-Bin; Yuan, Hong; Gao, Shu‐Qin; Yong, You; Nie, Changming; Wen, Ge; Lin, Ying‐Wu; Tan, Xiangshi

doi:10.1016/j.niox.2016.04.007

Cited by 27 publications

(22 citation statements)

References 58 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…14a), with the activity of mesoMb ~3.4-fold that of WT Mb. On the other hand, Lin and coworkers [135] found that the NIR activity of Mb can be regulated by redesign of the heme active center instead of modifying the heme group. By studying a series of Mb distal histidine mutants and the channel mutants, it showed that an enhancement of NIR activity was achieved by creation of a water channel to the heme center (H64A mutation) and relocation of the distal histidine (F43H mutation) (Fig.…”

Section: Heme Analogsmentioning

confidence: 99%

See 1 more Smart Citation

Rational design of metalloenzymes: From single to multiple active sites

Lin

2017

Coordination Chemistry Reviews

Self Cite

137

View full text Add to dashboard Cite

Artificial metalloenzymes combine the advantages of both natural enzymes and chemically synthesized models, which have achieved significant progress in the last decade. This review summarizes the recent achievements in rational design of metalloenzymes from single to multiple active sites in natural or de novo protein scaffolds, with a diverse range of functionalities, even beyond those of natural metalloenzymes. These achievements include construction of mononuclear active site by metal substitution or incorporation, design of homo-or hetero-dinuclear site, introduction of Fe-sulfur or other metal clusters, reconstitution of metallo-porphyrins or other metal complexes, and design of dual or multiple active sites in single, dimeric proteins, de novo proteins, protein-protein interfaces, as well as protein oligomers and polymers. Other new trends in recent designs are also discussed. The progress not only elucidates the structural and functional relationship of natural metalloenzymes, but also provides practical clues for design of advanced artificial metalloenzymes with potential applications.

show abstract

Section: Heme Analogsmentioning

confidence: 99%

“…Copyright 2016 Elsevier; (b) Relative reactivities of Mb distal histidine mutants and the channel mutants with respect to that of WT Mb. The X-ray structure of met F43H/H64A Mb was shown for clarification[135].…”

mentioning

confidence: 99%

Rational design of metalloenzymes: From single to multiple active sites

Lin

2017

Coordination Chemistry Reviews

Self Cite

137

View full text Add to dashboard Cite

show abstract

“…Various fungi, including A. muscaria,a lso contribute to the nitrogen cycle with nitrite as possible metabolic substrate. Additionally,r ational design based on metallobiomolecules [62][63][64] hasb een employed for as imilar purpose. [21] Despite such great importance,t he chemical homogeneous reduction of nitrites by inorganic transition metals and internal transition-metal compounds has rarely been investigated.M ost studies focusedo ni ron [33][34][35][36][37][38][39][40][41][42][43][44][45] or copper [46][47][48][49][50][51][52] complexes that mimicked nitrite reductases.H owever,N O 2 À reduction with Ru, [53] Mo, [54][55][56] Ti,C r, [56] Co [57][58][59] andU [60] was also reported.…”

Section: Introductionmentioning

confidence: 99%

Nitrite Reduction in Aqueous Solution Mediated by Amavadin Homologues: N₂O Formation and Water Oxidation

Dias

Bekhti

Kuznetsov

et al. 2018

Chemistry A European J

View full text Add to dashboard Cite

Reactions of two vanadium(IV) complex anions that are homologues of amavadin, [V(HIDPA) ] and [V(HIDA) ] (HIDPA=N-oxyiminodipropionate, HIDA=N-oxyiminodiacetate), with the nitrite ion (NO ) in aqueous solution were investigated by experimental (absorption spectroscopy in the visible range, through measurements of dioxygen formed in solution from water oxidation and identification of nitrogen oxide species of a gaseous atmosphere from nitrite reduction by using an IR analyser) and theoretical methods. Two reactions, mediated by the vanadium complexes, with environmental and biological significance, were observed in this system, namely, reduction of nitrite to N O and oxidation of water to molecular oxygen. The reduction of nitrite, as studied by DFT calculations, occurs through the formation of NO (ΔG =14.3 kcal mol ), which is strongly dependent on pH and slightly endergonic, and is then easily converted into N O, with an overall activation barrier of ΔG =11.8 kcal mol . The later process includes dimerisation of NO assisted by one molecule of the V complex, protonation and oxidation of the formed ONNO ligand by another amavadin molecule or by nitrite, and NO bond cleavage/proton transfer in the ONNOH ligand. The results indicate that amavadin exhibits an unusual nitrite reductase type activity that could be involved in nitrogen metabolism of Amanita muscaria and other fungi containing this vanadium complex.

show abstract

“…In a related study, Lin, Tan, and co-workers created a channel to the heme pocket of Mb by removing distal His64, a gate for O2 binding, and introducing a distal histidine at position 43 (F43H/H64A) [103]. A unique water channel was formed between the heme pocket and the solvent by successive H-bonding interactions of water molecules (W1-W7) in F43H/H64A Mb (Fig.…”

Section: By Introducing An Additional His At Position 43 In the Distamentioning

confidence: 99%

Design of artificial metalloproteins/metalloenzymes by tuning noncovalent interactions

Hirota

Lin

2017

J Biol Inorg Chem

Self Cite

View full text Add to dashboard Cite

Noncovalent weak interactions [hydrophobic interaction and hydrogen (H)-bond] play crucial roles in controlling the functions of biomolecules, and thus have been used to design artificial metalloproteins/metalloenzymes during the past few decades. In this review, we focus on the recent progresses in protein design by tuning the noncovalent interactions, including hydrophobic and H-bonding interactions. The topics include redesign and reuse of the heme pocket and other protein scaffolds, design of the heme protein interface, and de novo design of metalloproteins. The informations not only give insights into the metalloenzyme reaction mechanisms but also provide new reactions for future applications.

show abstract

Regulating the nitrite reductase activity of myoglobin by redesigning the heme active center

Cited by 27 publications

References 58 publications

Rational design of metalloenzymes: From single to multiple active sites

Rational design of metalloenzymes: From single to multiple active sites

Nitrite Reduction in Aqueous Solution Mediated by Amavadin Homologues: N₂O Formation and Water Oxidation

Design of artificial metalloproteins/metalloenzymes by tuning noncovalent interactions

Contact Info

Product

Resources

About

Regulating the nitrite reductase activity of myoglobin by redesigning the heme active center

Cited by 27 publications

References 58 publications

Rational design of metalloenzymes: From single to multiple active sites

Rational design of metalloenzymes: From single to multiple active sites

Nitrite Reduction in Aqueous Solution Mediated by Amavadin Homologues: N2O Formation and Water Oxidation

Design of artificial metalloproteins/metalloenzymes by tuning noncovalent interactions

Contact Info

Product

Resources

About

Nitrite Reduction in Aqueous Solution Mediated by Amavadin Homologues: N₂O Formation and Water Oxidation