Comparison of salicylate and D-phenylalanine for detection of hydroxyl radicals in chemical and biological reactions

被引：7

作者：

Bailey, SM ^{[1
]}

Fauconnet, AL ^{[1
]}

Reinke, LA ^{[1
]}

机构：

[1] UNIV OKLAHOMA,HLTH SCI CTR,COLL PHARM,DEPT PHARMACOL & TOXICOL,OKLAHOMA CITY,OK 73190

来源：

REDOX REPORT | 1997年 / 3卷 / 01期

关键词：

D O I：

10.1080/13510002.1997.11747086

中图分类号：

Q5 [生物化学]; Q7 [分子生物学];

学科分类号：

071010 ; 081704 ;

摘要：

Hydroxylation of salicylate and D-phenylalanine was measured to test the usefulness of these compounds for hydroxyl radical (HO .) detection in chemical and biological systems. When HO . were produced by the photolytic decomposition of hydrogen peroxide, nearly equal amounts of 2,5- and 2,3-dihydroxybenzoic acid (DHBA) were produced from salicylate, with catechol as a minor product. In the photolytic reaction, nearly equal concentrations of p,m-, and o-tyrosine were formed from D-phenylalanine. When salicylate or D-phenylalanine was present with Fenton reagents or in iron(II) autoxidation systems, the relative proportions of hydroxylated products were similar to those observed after photolysis, although less total products were usually detected. In contrast, when similar experiments were conducted with isolated hepatic microsomes and perfused livers, 2,5-DHBA was the primary product from salicylate, and p-tyrosine was the major product from D-phenylalanine. Cytochrome P-450 enzymes can hydroxylate salicylate to produce 2,5-DHBA, and it is likely that phenylalanine hydroxylase produces most of the p-tyrosine detected in hepatic tissues. Thus, although both salicylate and D-phenylalanine are useful probes for hydroxyl radical formation in chemical systems, hydroxylated products formed from enzymatic reactions complicate interpretation of data from both compounds in vivo.

引用

页码：17 / 22

页数：6

共 20 条

[1] THE AUTOXIDATION OF IRON(II) IN AQUEOUS SYSTEMS - THE EFFECTS OF IRON CHELATION BY PHYSIOLOGICAL, NONPHYSIOLOGICAL AND THERAPEUTIC CHELATORS ON THE GENERATION OF REACTIVE OXYGEN SPECIES AND THE INDUCEMENT OF BIOMOLECULAR DAMAGE [J].

BURKITT, MJ ;

GILBERT, BC .

FREE RADICAL RESEARCH COMMUNICATIONS, 1991, 14 (02) :107-123

[2] CRITICAL-REVIEW OF RATE CONSTANTS FOR REACTIONS OF HYDRATED ELECTRONS, HYDROGEN-ATOMS AND HYDROXYL RADICALS (.OH/.O-) IN AQUEOUS-SOLUTION [J].

BUXTON, GV ;

GREENSTOCK, CL ;

HELMAN, WP ;

ROSS, AB .

JOURNAL OF PHYSICAL AND CHEMICAL REFERENCE DATA, 1988, 17 (02) :513-886

[3]

FLOYD R A, 1986, Journal of Free Radicals in Biology and Medicine, V2, P13, DOI 10.1016/0748-5514(86)90118-2

[4] SENSITIVE ASSAY OF HYDROXYL FREE-RADICAL FORMATION UTILIZING HIGH-PRESSURE LIQUID-CHROMATOGRAPHY WITH ELECTROCHEMICAL DETECTION OF PHENOL AND SALICYLATE HYDROXYLATION PRODUCTS [J].

FLOYD, RA ;

WATSON, JJ ;

WONG, PK .

JOURNAL OF BIOCHEMICAL AND BIOPHYSICAL METHODS, 1984, 10 (3-4) :221-235

[5]

FUJIMOTO S, 1987, AGR BIOL CHEM TOKYO, V51, P2851

[6] AROMATIC HYDROXYLATION AS A POTENTIAL MEASURE OF HYDROXYL-RADICAL FORMATION INVIVO - IDENTIFICATION OF HYDROXYLATED DERIVATIVES OF SALICYLATE IN HUMAN-BODY FLUIDS [J].

GROOTVELD, M ;

HALLIWELL, B .

BIOCHEMICAL JOURNAL, 1986, 237 (02) :499-504

[7] HYDROXYLATION OF SALICYLATE BY MICROSOMAL FRACTIONS AND CYTOCHROME-P-450 - LACK OF PRODUCTION OF 2,3-DIHYDROXYBENZOATE UNLESS HYDROXYL RADICAL FORMATION IS PERMITTED [J].

INGELMANSUNDBERG, M ;

KAUR, H ;

TERELIUS, Y ;

PERSSON, JO ;

HALLIWELL, B .

BIOCHEMICAL JOURNAL, 1991, 276 :753-757

[8]

ISHIMITSU S, 1986, CHEM PHARM BULL, V34, P768

[9]

ISHIMITSU S, 1985, CHEM PHARM BULL, V33, P3387

[10]

KAUFMAN S, 1993, ADV ENZYMOL RAMB, V67, P77

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