S. Nesnow et al., QUANTITATIVE AND TEMPORAL RELATIONSHIPS BETWEEN DNA ADDUCT FORMATION IN TARGET AND SURROGATE TISSUES - IMPLICATIONS FOR BIOMONITORING, Environmental health perspectives, 101, 1993, pp. 37-42
DNA-carcinogen adducts offer a potential dosimeter for environmental g
enotoxicants reaching the exposed individual. Because the target tissu
es for many chemical carcinogens are not readily accessible for monito
ring adducts in humans, peripheral blood lymphocytes (PBLs) have serve
d as surrogate sources of exposed DNA. Both benzo[a]pyrene (BaP) and b
enzo[b]fluoranthene (BbF) are widely distributed in the environment as
components of complex mixtures, such as automobile exhaust, cigarette
smoke, foods, water, and urban air. Thus, human exposure to these che
micals is widespread, and they probably contribute to overall human lu
ng cancer risk. The interpretation of the results of such studies woul
d be enhanced by an understanding of the pharmacokinetics of specific
DNA adduct formation and persistence in both target and surrogate tiss
ues. Polycyclic aromatic hydrocarbons (PAHs) were administered to male
Sprague-Dawley rats IP at 100 mg PAH/kg body weight. Lung, liver, and
PBL tissues were harvested 1, 3,7,14,28, and 56 days after treatment.
DNA was extracted from each tissue and P-32-postlabeling analysis of
DNA adducts with nuclease P1 enhancement was conducted. In all three t
issues, BaP-DNA adducts exhibit a similar pattern, reaching a maximum
at 3-4 days, followed by a decrease to 56 days. For BbF, the maximum D
NA adduct levels in each tissue were between 5 and 14 days after injec
tion. By 56 days after administration, the total adducts remaining in
all tissues were measurable. Correlation analyses of the amount of DNA
adducts in lung or liver compared to those found in the PBL of the sa
me animals suggest a range of correlations (R2 = 0.67-0.83). For BaP,
DNA adducts in both liver and lung may be predicted by PBL DNA adduct
levels. For BbF, adduct levels in PBLs directly reflect adduct levels
in the liver and are less predictive of lung adduct levels. The collat
eral pharmacokinetics for DNA adduct persistence in lung, liver, and P
BLs suggest that PBL adduct-based dosimetry may reflect patterns of ad
duction in other less accessible tissues. Thus, PBL DNA adducts may pr
ove to be useful dosimeters for the delivered dose of DNA.