Biopolym. Cell. 1995; 11(1):30-35.
http://dx.doi.org/10.7124/bc.0003CE
Prototropic molecular-zwitterion tautomerism of hypoxanthine: AMI calculation in vacuum
1Govorun D. M., 1Kondratyuk I. V., 1Zheltovsky N. V.
  1. Institute of Molecular Biology and Genetics, NAS of Ukraine
    Kiev, Ukraine

Abstract

The prototropic molecular-zwitterion tautomerism of hypoxanthine (Hyp) was investigated by means of semiempirical quantum mechanical AMI method with full parameters optimization in vacuum. It was established that rnolecular-zwitterion family of Xan occupies the energetical range about 26 ccal/mol and it consists of 12 structural isomers – 10 molecular and 2 zwitterion; all they are plant dipole-stable structures. According to calculation, at the room temperature in the gase phase there are two energetically prevalent molecular ketone tautomers of Hyp–N9H and N7H. More polar form N9H is the main (82 %). At the same condition concentration of enol tautomers is less than 0.2%. These results are quantitative conformation of tautomeric equilibrium of Hyp in vacuum, which was investigate from IR spectra of low temperature matrix isolation (Sheina G. G. et ah, 1986). Under transition to solvent with universal solvation mechanism the equilibrium shifts some more to the N9H tautomer (98.6 %); concentrations of all other tautomers except NTH (1.4 %) are very small. It was established, that the main ilid form (which has iminoproton at Nl, N7 and N9 atoms and has no C8H proton) is an intermediate state of hydrogen-deutero-tritium exchange of C8H group in vacuum. The calculated value of energetical barier of this reaction is in a good agreement with the experimental data, and, to our mind, this agree confirms the ilid mechanism of hydrogen-deutero-tritium exchange of C8H group in the water under the acidic and neutral pH In the frame of results obtained the reasons of «substitution» of guanine to Hyp in an-ticodon triplets of tRNA are discussed.
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References

[1] Saenger W. Principles of nucleic acid structure. New York: Springer, 1984 556 p.
[2] Sheina GG, Radchenko YeD, Stepanian SG, Ivanov AYu, Blagoi YuP. Vibration spectra of hypoxanthine. Biofizika. 1986; 31(4):555-60.
[3] Sheina GG, Stepanian SG, Radchenko ED, Blagoi YP. IR spectra of guanine and hypoxanthine isolated molecules. J. Mol. Struct. 1987;158:275–92.
[4] Sheina GG. Prototropic tautomerism of purine and pyrimidine bases of nucleic acids: Dis. ... Dr. Khim. nauk. Kiev: Inst bioorg. Chemistry and petrochemistry of Sciences of Ukraine, 1992; 42p
[5] Burshteyn KN, Shorygin PL. Quantum chemical calculations in organic chemistry and molecular spectroscopy. Moscow: Nauka, 1989. 104 p.
[6] Norinder U. A theoretical reinvestigation of the nucleic bases adenine, guanine, cytosine, thymine and uracil using AM1. J Mol Struct. 1987;151:259–69.
[7] Sabio M, Topiol S Lumma Jr WC. An investigation of tautomerism in adenine and guanine. J Phys Chem. 1990; 94 (4):1366-1372.
[8] Govorun DN, Danchuk VD, Mishchuk YR, Kondratyuk IV, Radomsky NF, Zheltovsky NV. AM1 calculation of the nucleic acid bases structure and vibrational spectra. J Mol Struct. 1992;267:99–103.
[9] Kondratyuk IV, Govorun DM, Zheltovskyy MV. Prototropic tautomerism of molecular xanthine. Dopovidi Nats Akad Nauk Ukrainy. 1995; (4):109-12.
[10] Rambidi NG. Molecular structure in terms of experimenter-evolution of concepts and problems. Zh. Strukt Khim. 1982. 232(6):113-33.
[11] Urazovskiy SS. On the molecular polymorphism (to build a new theory of polymorphism). Kiev: Academy of Sciences of the USSR, 1950; 72 p.
[12] Samoshin V. V., Zefirov N. S. Conformational transformations of organic molecules in solution. Zhurn. Vsesoyuz. khim. obshchestva im. D. I. Mendeleyeva. 1984; 29(5):521-30.
[13] Morozov YuV, Vazhulina NP. Electronic structure, spectroscopy and reactivity of molecules: nucleobases, vitamins B6 and their analogs. Moscow: Nauka, 1989. 288 p.
[14] Poltev VI, Bruskov VI, Shuliupina NV, Rein R, Shibata M, Ornstein R, Miller J. Genotoxic modification of nucleic acid bases and biological consequences of it. Review and prospects of experimental and computational investigations. Mol Biol (Mosk). 1993;27(4):734-57.
[15] Govorun DM, Mishchuk YAR, Kondratyuk IV, Zheltovs'kiy MV. About nonplanarity hydrogenbinded complementary pairs of DNA bases: Proc. I Ukrainian-Polish symposium on hydrogen bonding. Odessa, 1992: 26.
[16] Boerth DW, Harding FX. Theoretical investigation of acidity and isotope exchange in purine nucleotide cations. J Am Chem Soc. 1985;107(10):2952–69.
[17] Agranovich IM. Conformational features of DNA in solution and in biological objects, revealed by the slow H1-H3 - exchange: Author. dis. ... kand. khim. nauk, Moscow: USSR Academy of Sciences Institute of Molecular Biology, 1985 21 p.