Structures and energetics of complexation of metal ions with ammonia, water, and benzene: A computational study

Sharma, Bhaskar; Neela, Y. Indra; Sastry, G. Narahari

doi:10.1002/jcc.24288

Cited by 16 publications

(16 citation statements)

References 94 publications

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“…These observations and explanation are in agreement with general chemical intuition and literature reports of an increase in the electrostatic contribution to the bindinge nergy in complexeso fa lkali metals and nucleophilesw ith an increase in the corresponding M-N distance. [53] The two metal ions are aligned with two CÀHg roups connecting the heme pyrrole rings on opposite sides of the structure (see Figure S1). The coordination of these metals with aw ater molecule further increases the M-N distances (see Figures S7-S10).…”

Section: Resultsmentioning

confidence: 99%

How Do Metal Ions Modulate the Rate‐Determining Electron‐Transfer Step in Cytochrome P450 Reactions?

Dixit

Warwicker

Visser

2020

Chemistry A European J

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Cytochrome P450 (CYP450)e nzymes play important roles in maintaining human health andt heir reaction rates are dependento nt he first electron transfer from the reduction partner.I nterestingly,e xperimental work has shown that this step is highly influenced by the addition of metal ions. To understand the effect of externalp erturbations on the CYP450 first reduction step, we have performed ac omputational studyw ith model complexes in the presence of metal and organic ions, solvent molecules, and an electricf ield. The results show that these medium-rangei nteractions affect the driving force as well as electron-transfer rates dramatically.Based on the location, distance, and direction of the ions/electric field, the catalytic reaction rates are enhanced or impaired. Calculations on al arge crystal structure with bonded alkali metal ions indicated inhibition patterns of the ions. Therefore, we predict that the activef orms of the naturalC YP450i sozymes will not have more than one alkali metal ion bound in the second-coordination sphere. As such, this study provides an insighti nto the activity of CYP450 enzymes and the effects of ions and electric field perturbations on their activity.

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Section: Resultsmentioning

confidence: 99%

How Do Metal Ions Modulate the Rate‐Determining Electron‐Transfer Step in Cytochrome P450 Reactions?

Dixit

Warwicker

Visser

2020

Chemistry A European J

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“…Especially, the understanding of noncovalent interactions involving metal ion binding is expected to provide valuable insights for structural and functional properties of molecular systems. 44 Particularly, the site of metal cation binding confirms the electron localization in the corresponding region of a molecular system. 40 Molecular electrostatic potential (MESP) is a scalar field, used extensively 38, [45][46][47] in the literature for exploring reactivity patterns of molecules and their noncovalent interactions.…”

Section: Introductionmentioning

confidence: 63%

Unveiling electrostatic portraits of quinones in reduction and protonation states

2018

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Quinones are known to perform diverse functions in a variety of biological and chemical processes as well as molecular electronics owing to their redox and protonation properties. Electrostatics chiefly governs intermolecular interaction behaviour of quinone states in such processes. The electronic distribution of a prototypical quinone, viz., p-benzoquinone, with its reduction and protonation states (BQS) is explored by molecular electrostatic potential (MESP) mapping using density functional theory. The reorganization of electronic distribution of BQS and their interaction with electrophiles are assessed for understanding the movement of ubiquinone in bacterial photosynthetic reaction centre, by calculating their binding energy with a model electrophile viz., lithium cation (Li +) at B3LYP/6-311+G(d,p) level of theory. The changes in the values of the MESP minima of BQS states alter their interacting behaviour towards Li +. A good correlation is found between the value of MESP minimum of BQS and the Li + binding strength at the respective site. To acquire more realistic picture of the proton transfer process to quinone with respect to its reduction state in the photosynthetic reaction center, interaction of BQS with model protonated motifs of serine, histidine as well as NH + 4 is explored. Further, the electronic conjugation of the reduced states of 9,10-anthraquinone is probed through MESP for understanding the switching nature of their electronic conductivity.

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“…An exploration of orbital splitting based on different symmetries indicated that octahedral ligand field splitting produced a close Table 2. Values for experimental and theoretical binding energies (BE) taken from Sharma et al 19 and the ligand field stabilization energy (LFSE) in relative units of D 0 for atomic transition metal cations and their electronic configurations (see text).…”

Section: Correlation With Lfsesmentioning

confidence: 99%

“…A very useful survey of both experimental and theoretical binding energies has very recently been reported for first-row atomic transition metal cations ligated with ammonia (see Table 1 in Sharma et al. 19 ). These are included in Table 2 which shows that there is generally good agreement between experiment and theory.…”

Section: Correlation With Ligand Binding Energiesmentioning

confidence: 99%

See 1 more Smart Citation

Ligation kinetics as a probe for gas-phase ligand field effects: Ligation of atomic transition metal cations with ammonia at room temperature

Blagojevic

Lavrov

Koyanagi

et al. 2019

Eur J Mass Spectrom (Chichester)

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The kinetics of ammonia ligation to atomic first and second row transition metal cations were measured in an attempt to assess the role of ligand field effects in gas-phase ion-molecule reaction kinetics. Measurements were performed at 295 AE 2 K in helium bath gas at 0.35 Torr using an inductively coupled plasma/selected-ion flow tube tandem mass spectrometer. The atomic cations were produced at ca. 5500 K in an inductively coupled plasma source and were allowed to decay radiatively and to thermalize by collisions with argon and helium atoms prior to reaction. A strong correlation was observed across the periodic table between the measured rate coefficients for ammonia ligation and measured/calculated bond dissociation energies. A similar strong correlation is seen with the ligand field stabilization energy. So ligand field stabilization energies should provide a useful predictor of relative rates of ligation of atomic metal ions.

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Structures and energetics of complexation of metal ions with ammonia, water, and benzene: A computational study

Cited by 16 publications

References 94 publications

How Do Metal Ions Modulate the Rate‐Determining Electron‐Transfer Step in Cytochrome P450 Reactions?

How Do Metal Ions Modulate the Rate‐Determining Electron‐Transfer Step in Cytochrome P450 Reactions?

Unveiling electrostatic portraits of quinones in reduction and protonation states

Ligation kinetics as a probe for gas-phase ligand field effects: Ligation of atomic transition metal cations with ammonia at room temperature

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