- Conformational Analysis of Charged Flexible Molecules in Water by Application of a New Karplus Equation Combined with MM2 Computations: Conformations of Carnitine and Acetylcarnitine
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The solution conformations of carnitine and acetylcarnitine in D2O are estimated from high-resolution 1H NMR coupling data.Conformations and populations of conformers are calculated from vicinal coupling constants by employing a new Karplus relationship with empirically derived substituent constants (Colucci, W.J.; Jungk, S.J.; Gandour, R.D.Magn.Reson.Chem. 1985, 23, 335-343).For this study, substituent constants are assigned for the monosubstituted ethanes: XCH2CH3, where X=-COOH, -OAc, -OH, -N+Me3, -CH2N+Me3, -CH2COOH.Solvent effects are accounted for by measuring the coupling constants of the monosubstituted ethanes under the same conditions employed in the measurement of the carnitine and acetylcarnitine spectra.The assignment of diasteriotopic protons of carnitine and acetylcarnitine is made by analogy with previous experimental work and comparison with the lowest energy conformation as determined by molecular mechanics (MM2) calculations parameterized with atomic charges from ab initio (3-21G) calculations.The vicinal coupling constants are then used to calculate populations of conformers, arising from rotation about the C2-C3 and C3-C4 bonds, in solution.Both compounds adopt a highly preferred g- conformation about the N1-C4-C3-O3 torsion angle.In contrast, the C1-C2-C3-C4 torsion angle exhibits substantial rotational freedom between g- and a.In carnitine, the anti conformer dominates, regardless of the solution pD, whereas in acetylcarnitine the g- conformer is most prevalent.In either compound, ionization from cation to zwitterion results in a net population increase of g-, g- (folded) conformer over the a,g- (extended) conformer.The relative energetics of extended and folded conformers suggest that binding of either carnitine or acetylcarnitine to the enzyme carnitine acetyltransferase occurs with the folded form.
- Colucci, William J.,Gandour, Richard D.,Mooberry, Edward A.
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- Conformational analysis of N,N,N-Trimethyl-(3,3-dimethylbutyl)ammonium iodide by NMR spectroscopy: A sterically hindered trans-standard
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A predominantly trans-1,2-disubstituted ethane system - N,N,N-trimethyl-(3,3-dimethylbutyl)ammonium iodide - is of particular interest for conformational analysis, because it contains both an organic and a highly polar substituent, making it soluble and thus applicable to study in a large variety of solvents. The fraction of the trans conformer of this molecule in a wide range of protic and aprotic solvents was determined by the nuclear magnetic resonance proton couplings to be approximately 90%, in contrast to the previously assumed 100%. The consistently strong preference of the trans conformation should establish N,N,N-trimethyl-(3,3-dimethylbutyl)ammonium iodide as a possibly useful 'trans-standard' in conformational analysis, much more so than 1,2-ditert-butylethane, which has a poor solubility in many solvents. Copyright 2013 John Wiley & Sons, Ltd. A predominantly trans-1,2-disubstituted ethane system - N,N,N-trimethyl-(3,3-dimethylbutyl) ammonium iodide - is of particular interest for conformational analysis, because it is soluble and thus applicable to study in a large variety of solvents. The fraction of the trans conformer of this molecule in a wide range of protic and aprotic solvents was determined by the nuclear magnetic resonance proton couplings to be approximately 90%, in contrast to the previously assumed 100%. The consistently strong preference of the trans conformation should establish N,N,N-trimethyl-(3,3-dimethylbutyl)ammonium iodide as a possibly useful 'trans-standard' in conformational analysis. Copyright
- Liu, Albert Tianxiang,Nag, Mrinmoy,Carroll, William R.,Roberts, John D.
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- CONFORMATION OF DIMETHYLAMINOETHANOL, ITS METHYL ETHER AND OF THE CORRESPONDING TRIMETHYLAMMONIUM IODIDES. NMR AND VIBRATIONAL SPECTRA
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By analysis of fully coupled 13C NMR spectra and of 1H NMR spectra of dimethylaminoethanol, its methyl ether, and of the corresponding trimethylammonium iodides, populations of isomers generated by rotation about the bonds N-CH2, CH2-CH2, and CH2-O in these compounds in solution were determined.By analysis of Raman and infrared spectra of these compounds in the solid and liquid states it was found that in the crystalline state these compounds form structures with parallel N-CH3 and O-CH2 bonds, which are also preffered in the liquid state.
- Stokr, Jan,Schneider, Bohdan,Doskocilova, Danica,Sevcik, Stanislav,Pradny, Martin
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p. 1256 - 1271
(2007/10/02)
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- A Microscopic Hydrophobicity Parameter
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p-Nitrophenyl laurate at 1x1E-5 M in water forms aggregates within which the ester groups hydrolyze slowly (about 1E3 less than a short-chain monomer).Salts of the general structure RNMe3+X- disrupt or destroy the aggregates; the ester groups are thereby "deshielded", and the observed hydrolysis rate increases.The magnitude of the rate increase at a given salt concentration depends on R: the more hydrophobic the R group, the greater the rate enhancement.This observation provided the basis of a "microscopic" hydrophobicity parameter MH which was evaluated for 25 different Rs (e.g., MH=0.73, 0.97, and 1.33 for R=ethyl, n-butyl, and n-hexyl).MH values were used to assess the role of branching, unsaturation, cyclization, aromaticity, halogenation, etc., in hydrophobic association.The parameters correlate well with Hansch ? values for aliphatic substituents but not for aromatic groups.Since the MH scale is based on the specific binding of one molecule to another, it may be well suited for modeling association among bioactive species.
- Menger, F. M.,Venkataram, U. V.
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p. 2980 - 2984
(2007/10/02)
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