9-methylguanine and 1-methylimidazole

9-methylguanine has been researched along with 1-methylimidazole* in 1 studies

Other Studies

1 other study(ies) available for 9-methylguanine and 1-methylimidazole

Article	Year
On the competition of the purine bases, functionalities of peptide side chains, and protecting agents for the coordination sites of dicationic cisplatin derivatives. Journal of the American Chemical Society, 2002, May-22, Volume: 124, Issue:20 The Pt-L bond energies of simple triammineplatinum(II) complexes, [Pt(NH(3))(3)L](2+), with oxygen-, nitrogen-, and sulfur-containing donor ligands L have been predicted and rationalized using density functional theory. The ligands L have been chosen as models for functionalities of peptide side chains, for sulfur-containing protecting agents, and for adenine and guanine sites of the DNA as the ultimate target of platinum anticancer drugs. Calculation of the Pt-L bond energy in [Pt(NH(3))(3)L](2+) reveals that the soft metal center of triammineplatinum(II) prefers N ligands over S ligands. This remarkable result has been discussed in light of several interpretations of the hard and soft acids and bases principle. The concept of orbital-symmetry-based energy decomposition has been employed for the determination of the contributions from sigma and pi orbital interactions, electrostatics, and intramolecular hydrogen bonding to the Pt-L bond energy. The calculations show that considerable differences in the bond energies of the triammineplatinum(II) complexes with N-heterocycles such as 1-methylimidazole, 9-methyladenine, and 9-methylguanine arise from electrostatics rather than from orbital interactions. Surprisingly, the net stabilization by hydrogen bonding between the (Pt)N-H group and the oxygen of 9-methylguanine is as weak as the intramolecular hydrogen bond in the aqua complex [Pt(NH(3))(3)(H(2)O)](2+), challenging the common hypothesis that DNA-active anticancer drugs require carrier ligands with N-H functionalities because of their hydrogen-bonding ability. The influence of a polarizable environment on the stability of the complexes has been investigated systematically with the dependence of the dielectric constant epsilon. With increasing epsilon, the complexes with S-containing ligands are more strongly stabilized than the complexes of the N-containing heterocycles. At epsilon = 78.4, the dielectric constant of water, 9-methylguanine remains the only purine derivative investigated which is competitive to neutral sulfur ligands. These findings are particularly important for a rationalization of the results from recent experimental studies on the competition of biological donor ligands L for coordination with the metal center of [Pt(dien)L](2+) (dien = 1,5-diamino 3-azapentane). Topics: Adenine; Antineoplastic Agents; Cisplatin; DNA Adducts; Guanine; Imidazoles; Ligands; Molecular Structure; Peptides; Static Electricity	2002

Article

Year

On the competition of the purine bases, functionalities of peptide side chains, and protecting agents for the coordination sites of dicationic cisplatin derivatives.

Journal of the American Chemical Society, 2002, May-22, Volume: 124, Issue:20

The Pt-L bond energies of simple triammineplatinum(II) complexes, [Pt(NH(3))(3)L](2+), with oxygen-, nitrogen-, and sulfur-containing donor ligands L have been predicted and rationalized using density functional theory. The ligands L have been chosen as models for functionalities of peptide side chains, for sulfur-containing protecting agents, and for adenine and guanine sites of the DNA as the ultimate target of platinum anticancer drugs. Calculation of the Pt-L bond energy in [Pt(NH(3))(3)L](2+) reveals that the soft metal center of triammineplatinum(II) prefers N ligands over S ligands. This remarkable result has been discussed in light of several interpretations of the hard and soft acids and bases principle. The concept of orbital-symmetry-based energy decomposition has been employed for the determination of the contributions from sigma and pi orbital interactions, electrostatics, and intramolecular hydrogen bonding to the Pt-L bond energy. The calculations show that considerable differences in the bond energies of the triammineplatinum(II) complexes with N-heterocycles such as 1-methylimidazole, 9-methyladenine, and 9-methylguanine arise from electrostatics rather than from orbital interactions. Surprisingly, the net stabilization by hydrogen bonding between the (Pt)N-H group and the oxygen of 9-methylguanine is as weak as the intramolecular hydrogen bond in the aqua complex [Pt(NH(3))(3)(H(2)O)](2+), challenging the common hypothesis that DNA-active anticancer drugs require carrier ligands with N-H functionalities because of their hydrogen-bonding ability. The influence of a polarizable environment on the stability of the complexes has been investigated systematically with the dependence of the dielectric constant epsilon. With increasing epsilon, the complexes with S-containing ligands are more strongly stabilized than the complexes of the N-containing heterocycles. At epsilon = 78.4, the dielectric constant of water, 9-methylguanine remains the only purine derivative investigated which is competitive to neutral sulfur ligands. These findings are particularly important for a rationalization of the results from recent experimental studies on the competition of biological donor ligands L for coordination with the metal center of [Pt(dien)L](2+) (dien = 1,5-diamino 3-azapentane).

Topics: Adenine; Antineoplastic Agents; Cisplatin; DNA Adducts; Guanine; Imidazoles; Ligands; Molecular Structure; Peptides; Static Electricity

2002