Hypoxanthine, tautomeric forms

Whatever be the difficulties in dealing satisfactorily with the problem of the lactam-lactim tautomerism in hydroxypurines, the predominance of the lactam tautomer granted, there remains the problem of the detailed structure of the most probable lactam form for each isomer. The problem is essentially that of the site of location of the imidazole proton. From that point of view forms 34-38 have to be considered for 2-hydroxypurine, forms 39—42 for 6-hydroxypurine (hypoxanthine), and forms 43-45 for 8-hydroxypurine. There are, in addition, some betaine tautomeric forms but these are probably of low stability and will not be considered further. Before describing the results of theoretical calculations, it may be useful to indicate that from the experimental point of view we may, in this respect, turn again for significant evidence to infrared spectroscopy... 

Fig. 3. (A) Lactim-imino and (B) lactam-amino tautomeric forms of the purine base hypoxanthine.

As is the case for pyrimidines, purines also exist in oxo, thio, and amino tautomeric forms. The lactam-amino and lactim-imino forms of the purine base hypoxanthine are shown in Fig. 3. 

Hypoxanthine is oxidized at carbon 2 by both molybdenum hydroxylases, although xanthine oxidase is much more effective as a catalyst in this reaction [ 10]. A methyl substituent in this position prevents oxidation by either enzyme. Introduction of A-methyl substituents into the hypoxanthine nucleus produces dramatic effects on enzymic oxidation rates and also gives some insight into the productive modes of binding to each enzyme. Thus, it has been proposed that hypoxanthine tautomerizes in the xanthine oxidase-substrate complex to the 3-NH-form with a simultaneous shift of the NH-group in the imidazole ring from position 9 to 7 [ 198,200]. In support of this hypothesis, when tautomerism in the imidazole ring is prevented by substitution at N-7 or N-9, such compounds are almost refractory to oxidation (see Table 3.9)... 

As is well known, the two purines, adenine and guanine, originating from nucleic acids or from high-energy phosphate compounds like ATP or GTP, are catabolized in man to uric acid. The intermediately formed hypoxanthine and xanthine are both oxidized to uric acid by the enzyme xanthine oxidase. This enzyme introduces an oxygen atom between the carbon and hydrogen atom in position Cg. Of the two tautomeric forms of uric acid, the amido (lactam) and the imido (lactim) forms, the latter has a more acid character. 

The amino groups are replaced with oxygen. Although here a biochemical reaction, the same can be achieved under acid-catalysed hydrolytic conditions, and resembles the nucleophilic substitution on pyrimidines (see Section 11.6.1). The first-formed hydroxy derivative would then tautomerize to the carbonyl structure. In the case of guanine, the product is xanthine, whereas adenine leads to hypoxanthine. The latter compound is also converted into xanthine by an oxidizing enzyme, xanthine oxidase. This enzyme also oxidizes xanthine at C-8, giving uric acid. 

The nucleoside formed from hypoxanthine and ribose is known as inosine (Ino or I) and the corresponding nucleotide as inosinic acid. Further substitution at C-2 of -H by -OH and tautomerization yields xanthine (Xan). Its nucleoside is xanthosine (Xao, X). A similar hydroxylation at C-7 converts xanthine to uric acid, an important human urinary excretion product derived from nucleic acid bases. 

There are various forms of tautomerism which operate in the different purine species. (1) Prototropy which involves attachment of the proton to any one of the four ring nitrogen atoms (Scheme 5). Corresponding CH tautomers, for example (52), seem to be of little significance. (2) Amine-imine tautomerism which operates in the aminopurines such as adenine (Scheme 6). (3) Lactam-lactim tautomerism as in the hydroxypurines such as hypoxanthine (Scheme 7) and the related thioxo-thiol tautomerism (53) and (54) in the biologically imporfant mercaptopurines (Scheme 8). The subject has recently been discussed in some detail <76AHC(Si)502>. 

Lactam-lactim interconversion and the tautomerism between the thione and thiol forms, which could occur in the pyrimidine portion of hypoxanthine and 6-mercapto-purine, respectively, have been investigated by using the chemical shift of the C-6 carbon. The relative position of the C-6 resonance made it possible to calculate the amount of N -H tautomer by using Eq. (3)... 

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