Toward the understanding of the metabolism of levodopa I. DFT investigation of the equilibrium geometries, acid-base properties and levodopa-water complexes

Levodopa (LD) is used to increase dopamine level for treating Parkinson's disease. The major metabolism of LD to produce dopamine is decarboxylation. In order to understand the metabolism of LD; the electronic structure of levodopa was investigated at the Density Functional DFT/B3LYP level of t...

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Bibliographic Details
Published inInternational journal of molecular sciences Vol. 13; no. 4; pp. 4321 - 4339
Main Authors Elroby, Shabaan A K, Makki, Mohamed S I, Sobahi, Tariq R, Hilal, Rifaat H
Format Journal Article
LanguageEnglish
Published Switzerland MDPI AG 01.04.2012
Molecular Diversity Preservation International (MDPI)
Subjects
Chemical bonds
Chemistry
Decarboxylation
DFT
Dopamine
Dopamine - biosynthesis
Dopamine - metabolism
Equilibrium
Geometry
Humans
Hydrogen Bonding
Investigations
levodopa
Levodopa - chemistry
Levodopa - metabolism
Levodopa - therapeutic use
Metabolism
Models, Chemical
Models, Molecular
NBO
Parkinson Disease - drug therapy
Parkinson's disease
protonation/deprotonation
Water - chemistry
Egypt
NBO
DFT
levodopa
parkinson’s disease
protonation/deprotonation
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Summary:Levodopa (LD) is used to increase dopamine level for treating Parkinson's disease. The major metabolism of LD to produce dopamine is decarboxylation. In order to understand the metabolism of LD; the electronic structure of levodopa was investigated at the Density Functional DFT/B3LYP level of theory using the 6-311+G** basis set, in the gas phase and in solution. LD is not planar, with the amino acid side chain acting as a free rotator around several single bonds. The potential energy surface is broad and flat. Full geometry optimization enabled locating and identifying the global minimum on this Potential energy surface (PES). All possible protonation/deprotonation forms of LD were examined and analyzed. Protonation/deprotonation is local in nature, i.e., is not transmitted through the molecular framework. The isogyric protonation/deprotonation reactions seem to involve two subsequent steps: First, deprotonation, then rearrangement to form H-bonded structures, which is the origin of the extra stability of the deprotonated forms. Natural bond orbital (NBO) analysis of LD and its deprotonated forms reveals detailed information of bonding characteristics and interactions across the molecular framework. The effect of deprotonation on the donor-acceptor interaction across the molecular framework and within the two subsystems has also been examined. Attempts to mimic the complex formation of LD with water have been performed.
ISSN:1422-0067
1661-6596
1422-0067
DOI:10.3390/ijms13044321