A Quantitative Basis for a Scale of Na<sup>+</sup> Affinities of Organic and Small Biological Molecules in the Gas Phase

Hoyau, Sophie; Norrman, Kion; McMahon, T. B.; Ohanessian, Gilles

doi:10.1021/ja9841198

Cited by 276 publications

(443 citation statements)

References 63 publications

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“…To test the mechanism and increase the number of investigated sodiated amino acids in H/D exchange the gas-phase reactions of AlaNa [15][16][17][18][19][20]. Present findings, together with earlier results [10,11] indicate that in H/D exchange experiments only the ZW form of sodiated amino acid is probed.…”

Section: H/d Exchange Reactionsmentioning

confidence: 76%

Gas phase H/D exchange of sodiated amino acids: Why do we see zwitterions?

Rožman

Bertoša

Klasinc̆

et al. 2006

J. Am. Soc. Mass Spectrom.

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Section: H/d Exchange Reactionsmentioning

confidence: 76%

Gas phase H/D exchange of sodiated amino acids: Why do we see zwitterions?

Rožman

Bertoša

Klasinc̆

et al. 2006

J. Am. Soc. Mass Spectrom.

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“…After identifying the four ground states of the eleven different alkali metal-bound derivatives by HF/basis1 level optimizations 5 and by judgment, their geometries are refined at the B3P86/basis1 level 34 in order to obtain these results more accurately. All of these alkali metal-bound derivatives hold the Cs symmetries except VIЈ and IXЈ, which have C1 symmetries.…”

Section: A Ascertainment Of the Ground-state Isomersmentioning

confidence: 99%

Structure and property of glycine’s derivatives bound by multications (H+, Li+, and Na+): A theoretical study

Han

2002

The Journal of Chemical Physics

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The calculations using several different methods (B3P86, MP2, MP3, MP4SDQ, and CCSD) and basis sets [6-31G*, 6-31+G*, and 6-311+G(2df,2pd)] have been first performed for 15 glycine derivatives (one Gly–2H+, one Gly–3H+, five Gly–H+Li+ isomers, three Gly–H+Na+ isomers, three Gly–Li+Na+ isomers, and two Gly–2Na+ isomers) formed by multications (H+, Li+ or Na+) and different active sites of a glycine molecule. These calculations yield accurate geometric structures, relative energies, bond energies, vibrational frequencies, infrared intensities, and charge distributions. The comparisons of relative energy for each isomer show that both Gly–2H+ and Gly–3H+ derived from the most stable neutral glycine hold the lowest energies among their respective corresponding isomers. For the Gly–2H+, two protons are, respectively, bound to the amino nitrogen and the syn carbonyl oxygen of the most stable neutral glycine molecule. On the basis of the Gly–2H+, the derivative Gly–3H+ can be generated when the third proton binds to the hydroxyl oxygen. For five Gly–H+Li+ isomers, three Gly–H+Na+ isomers, three Gly–Li+Na+ isomers, and two Gly–2Na+ isomers, each of their corresponding ground state possesses the structure with the heavier cation coordinated to carbonyl oxygen and the lighter one to the anti-amino nitrogen of another kinds of neutral glycine molecule. The bond energies first reveal that some of these derivatives must surmount an activation energy barrier in the course of some cation (proton) dissociating from it. The origin of these barriers are investigated and discussed. Finally characteristic frequency calculations imply that the study is very important in the search of the glycine derivatives by rotational spectroscopy, or for the identification of their isomers by their infrared bands.

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“…Proton affinities have been mostly determined measuring the equilibrium constants for gas-phase proton transfer between two bases. In the last decade, introduction of computational chemistry based methods has provided an alternative way to determine accurately the proton affinities of single amino acids [19,20] and sodium affinities of small organic molecules [21]. Thermochemical properties of various UV and IR matrices were evaluated by means of B3LYP density functional molecular orbital calculations [22].…”

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confidence: 99%

A density functional theory (DFT) study on gas-phase proton transfer reactions of derivatized and underivatized peptide ions generated by matrix-assisted laser desorption ionization

Brancia

Stener

Magistrato

2009

J. Am. Soc. Mass Spectrom.

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In this study, classic molecular dynamics (MD) simulations followed by density functional theory (DFT) calculations are employed to calculate the proton transfer reaction enthalpy shifts for native and derivatized peptide ions in the MALDI plume. First, absolute protonation and deprotonation enthalpies are calculated for native peptides (RPPGF and AFLDASR), the corresponding hexyl esters and three common matrices ␣-cyano-4-hydroxycinnamic acid (4HCCA), 2,5-dihydroxybenzoic acid (DHB), and 6 aza-2-thiothymine (ATT). From the proton exchange reaction calculations, protonation and deprotonation of the neutral peptides are thermodynamically favorable in the gas phase as long as the corresponding protonated/ deprotonated matrix ions are present in the plume. Moreover, the gain in proton affinity shown by the ester ions suggests that the increase in ion yield is likely to be related to an easier proton transfer from the matrix to the peptide. (J Am Soc Mass

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A Quantitative Basis for a Scale of Na⁺ Affinities of Organic and Small Biological Molecules in the Gas Phase

Cited by 276 publications

References 63 publications

Gas phase H/D exchange of sodiated amino acids: Why do we see zwitterions?

Gas phase H/D exchange of sodiated amino acids: Why do we see zwitterions?

Structure and property of glycine’s derivatives bound by multications (H+, Li+, and Na+): A theoretical study

A density functional theory (DFT) study on gas-phase proton transfer reactions of derivatized and underivatized peptide ions generated by matrix-assisted laser desorption ionization

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A Quantitative Basis for a Scale of Na+ Affinities of Organic and Small Biological Molecules in the Gas Phase

Cited by 276 publications

References 63 publications

Gas phase H/D exchange of sodiated amino acids: Why do we see zwitterions?

Gas phase H/D exchange of sodiated amino acids: Why do we see zwitterions?

Structure and property of glycine’s derivatives bound by multications (H+, Li+, and Na+): A theoretical study

A density functional theory (DFT) study on gas-phase proton transfer reactions of derivatized and underivatized peptide ions generated by matrix-assisted laser desorption ionization

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A Quantitative Basis for a Scale of Na⁺ Affinities of Organic and Small Biological Molecules in the Gas Phase