7- guanine, formation

Gu, F., Stillwell, W.G., Wishnok, J.S., Shallop, A.J., Jones, R.A., and Tannen-baum, S.R. (2002) Peroxynitrite-induced reactions of synthetic oligo 2 -deoxynu-cleotides and DNA containing guanine formation and stability of a 5-guanid-ino-4-nitroimidazole lesion. 

Guanine formation occurs following oxidation in position 2, to form xanthylic acid." This oxidation has been demonstrated with a DPN-requiring enzyme from bone marrow. Subsequent animation occurs through different mechanisms in animal and bacterial systems. In bone marrow extracts the amide of glutamine is transferred, while in bacterial extracts ammonia is utilized more readily than glutamine. The utilization of ammonia by the bacterial system is accompanied by the hydrolysis of ATP to AMP and PP. In addition to these reactions, it is known that adenine and guanine can be interconverted, but the enzymatic mechanisms are not known. 

The mode of action has been a subject for research for a number of years. While it was originally thought that maleic hydrazide replaced uracil in the RNA sequence, it has been deterrnined that the molecule may be a pyrimidine or purine analogue and therefore base-pair formation is possible with uracil and thymine and there exists the probabiHty of base-pair formation with adenine however, if maleic hydrazide occurs in an in vivo system as the diketo species, then there remains the possibiHty of base-pairing with guanine (50). Whatever the mechanism, it is apparent that the inhibitory effects are the result of a shutdown of the de novo synthesis of protein. 

Saito et al. achieved the first direct confirmation of double alkylation of purine bases by azinomycin B [140]. They incubated azinomycin B with the self-comple-mentary DNA duplex d(TAGCTA)2 and monitored the reaction by HPLC and ion spray MS. They observed initial formation of a monoadduct that was then converted into a crosslinked bisadduct. The crosslink position was identified as between the guanine of one strand and the 5 -adenine on the other strand by thermo-lytic depurination. Further decomposition prevented structural analysis of the azi-... 

There is strong evidence that DNA adduction by these bulky reactive metabolites of PAHs is far from random, and that there are certain hot spots that are preferentially attacked. Differential steric hindrance and the differential operation of DNA repair mechanisms ensure that particular sites on DNA are subject to stable adduct formation (Purchase 1994). DNA repair mechanisms clearly remove many PAH/ guanine adducts very quickly, but studies with P postlabeling have shown that certain adducts can be very persistent—certainly over many weeks. Evidence for this has been produced in studies on fish and Xenopus (an amphibian Reichert et al. 1991 Waters et al. 1994). 

Figure 34-8. Formation of uric acid from purine nucleosides byway of the purine bases hypoxanthine, xanthine, and guanine. Purine deoxyribonucleosides are degraded by the same catabolic pathwayand enzymes,all of which existin the mucosa of the mammalian gastrointestinal tract.

The reactions of the oxadiazolium ions with nucleophiles such as thiophenolSy guanine, and guanosine resulted in methylation of the nucleophiles (53). Thus, the formation of the oxadiazolium ion creates an electrophilic species not... 

Since the results of our experiments with isolated rat liver fractions supported a reaction sequence Initiated by microsomal oxidation of the nitrosamine leading to formation of a carbonium ion, the results of the animal experiment suggested that in the intact hepatocyte, one of the earlier electrophilic intermediates (II, III or V, Figure 1) is intercepted by nucleophilic sites in DNA (exemplified here by the N7 position of guanine) before a carbocation is formed. 

Schimanski, A., Ereisinger, E., Erxleben, A. and Lippert, B. (1998) Interactions between [AuX4] (X = Cl, CN) and cytosine and guanine model nucleobases salt formation with (hemi-) protonated bases, coordination, and oxidative degradation of guanine. Inorganica Chimica Acta, 283, 223. 

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