K. Cao et al., SYNTHESIS AND STRUCTURE ELUCIDATION OF ESTROGEN QUINONES CONJUGATED WITH CYSTEINE, N-ACETYLCYSTEINE, AND GLUTATHIONE, Chemical research in toxicology, 11(8), 1998, pp. 909-916
Catechol estrogen quinones (CE-Q) have been implicated as ultimate car
cinogenic metabolites in estrogen-induced carcinogenesis. CE-Q may cov
alently bind to DNA to initiate cancer. These quinones can also be con
jugated with glutathione, a reaction that prevents damage to DNA by CE
-Q. The glutathione conjugates are then catabolized through mercapturi
c acid biosynthesis to cysteine and N-acetylcysteine conjugates. This
may be the most important detoxification pathway of CE-Q. The chemical
synthesis and characterization of these conjugates are the first esse
ntial steps to better understand their function in biological systems.
Eighteen conjugates were synthesized by reaction of estrone-3,4-quino
ne (E-1-3,4-Q), estradiol-3,4-quinone (E-2-3,4-Q), estrone-2,3-quinone
(E-1-2,3-Q), or estradiol-2,3-quinone (E-2-2,3-Q) with various sulfur
: nucleophiles, RSH, in which R is the cysteine, N-acetylcysteine, or
glutathione moiety. Reactions of E-1-3,4-Q and E-2-3,4-Q produce regio
specifically 4-OHE1-2-SR and 4-OHE2-2-SR, respectively, in almost quan
titative yield. E-1-2,3-Q and E-2-2,3-Q react regioselectively and qua
ntitatively to form S-OHE1(E-2)-1-SR and 8-OHE1(E-2)-4-SR, in which th
e l-isomers are always the major products. The ratio between 1 and 4 i
somers is 3.5 for cysteine, 2.7 for N-acetylcysteine, and 2.5 for glut
athione. The synthesized conjugates will be used as standards in the i
dentification of these compounds formed in biological systems.