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| 3: Adv Exp Med Biol 2001;500:559-76 |
Eaton DL, Bammler TK, Kelly EJ.
Center for Ecogenetics and Environmental Health, Department of Environmental
Health, University of Washington, Seattle 98195, USA.
It is now evident that most, if not all, of the remarkable species differences
in susceptibility to AFB hepatocarcinogenesis is due in large part, if not
exclusively, to differences in biotransformation. Certainly the relative rate of
oxidative formation of the proximate carcinogen, AFB-8,9-exo-epoxide, is an
important determinant of species and interindividual differences in
susceptibility to AFB. However, mice produce relatively large amounts of
exo-AFBO, yet are highly resistant to AFB-hepatocarcinogenesis because they
express a particular form of GST with remarkably high catalytic activity toward
the exo-epoxide of AFB. Rats, which are highly susceptible to AFB
hepatocarcinogenesis,can be made resistant through dietary induction of an
orthologous form of GST that is normally expressed in only very small amounts.
Based on these findings in laboratory animal models, there is great interest in
identifying chemicals and/or specific dietary constituents that could offer
protection against AFB-hepatocarcinogenesis to humans. Current experimental
strategies have focused on the antiparasitic drug, oltipraz, which induces
protection in rats and has also shown some promise in humans. The mechanism of
protection in rats appears to be via induction of an alpha class GST with high
catalytic activity toward AFBO (rGSTA5-5). vet human alpha class GST proteins
that are constitutively expressed in the liver (hGSTA1 and hGSTA2) have little,
if any activity toward AFBO. Rather, it appears that mu class GSTs may be
responsible for the very low, but potentially significant, detoxification
activity toward AFBO. Oltipraz and certain dietary constituents may induce mu
class GSTs in human liver, and this could afford some protection against the
genotoxic effects of AFBO. However, it also appears that oltipraz, and perhaps
certain dietary constituents, act as competitive inhibitors of human CYP1A2. As
CYP1A2 appears to mediate most of the activation of AFB to exo-AFBO in human
liver at low dietary concentrations of AFB encountered in the human diet, much
of the putative protective effects of oltipraz could be mediated via inhibition
of CYP1A2 rather than induction of GSTs. There is now evidence that human
microsomal epoxide hydrolase (mEH) could play a role in protecting human DNA
from the genotoxic effects of AFB, although the importance of this
detoxification pathway, relative to mu class GSTs, remains to be elucidated.
Oltipraz is an effective inducer of mEH in rats (Lamb Franklin, 2000), and thus
induction of this pathway in humans could also potentially contribute to the
protective effects of this drug toward AFB genotoxicity. Because the dihydrodiol
of AFB may contribute indirectly to the carcinogenic effects of AFB via protein
adduction and subsequent hepatotoxicity, the recently characterized human
aflatoxin aldehyde reductase (AFAR) may also offer some protection against
AFB-induced carcinogenicity in humans. Current and future dietary and/or
chemointervention strategies aimed at reducing the carcinogenic effects of AFB
in humans should consider all of the possible mechanistic approaches for
modifying AFB-induced genotoxicity.
Publication Types:
PMID: 11764998
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