Phenolic and nonphenolic ring deiodinations of iodothyronines in cultured hepatocarcinoma cell hemogenate from monkey

Iodothyronine monodeiodinase activities in homogenates of cultured monkey hepatocarcinoma cells were measured by the deiodination of [3,5-¹²⁵I]triido-l-thyronine or 3-[3′5′-¹²⁵I]triido-l-thyronine (phenolic ring-labeled ‘reverse’ triiodothyronine). The assay system utilized a small ion-exchange column (AG50W-X4, 0.9×～1 cm) to measure ¹²⁵I^?. Both deiodinases were destroyed by boiling for 1 min.Maximal nonphenolic ring deiodination was observed at pH 7.9 whereas maximal phenolic ring deiodination was at pH 6.3. Both reactions were enhanced strongly by dithiothreitol (0.1–5 mM), and slightly by 5 mM β-mercaptoethanol. Phenolic ring deiodination was strongly inhibited by 0.1 mM propylthiouracil. Nonphenolic ring deiodination was accelerated by EDTA (1.2 mM) and inhibited by Mg²⁺ (5 mM). Methylmercaptoimidazol and Mg²⁺, Ca²⁺ and Mn²⁺ (0.1–1.0 mM) had little or no effect on either reaction, but Zn²⁺ (0.1 mM) strongly inhibited both.Both reactions were inhibited by excess iodothyronine analogues at 10 mM to 10μM, and thyroxine was shown to be a competitive inhibitor in both cases. On the basis of relative affinities and inhibitory effects, it appears that the order of affinity for the phenolic ring deiodinase is 3,3′,5′-triiodo-l-thyronine-(rT₃) > l-thyroxine(T₄) > 3,4,3′-triido-l-thyronine(T₃), whereas for the nonphenolic ring deiodinase the order is T₃ > T₄ > rT₃. Diiodotyrosine did not affect their deiodination.     

Activation and inactivation of thyroxine by cultured rat hepatoma cells

The metabolism of thyroxine, 3,3′,5-triiodothyronine and 3,3′,5′-triiodothyronine was investigated in rat hepatoma cell cultures (R117-21B). These iodothyronines were labeled with ¹²⁵I in the phenolic ring and the metabolites were analyzed by ion-exchange column chromatography.When thyroxine was incubated with the cells at 37°C, its glucuronide was the major product and a little increase in ¹²⁵I^? was detected. Although 3,3′,5-triiodothyronine was not observed in the incubation medium, this metabolite was clearly identified in the ethanol extract obtained from the cell homogenates after 24 h incubation.This cell line also metabolized labeled 3,3′,5-triiodothyronine added to culture medium. After 24 h incubation, 3,3′,5-triiodothyronine glucuronide was the major metabolite and iodothyronine sulfates were also formed. The sulfates contained, 3,3′,5-triiodothyronine and 3,3′-diiodothyronine sulfates and an unknown component.In the metabolism of 3,3′,5′-triiodothyronine, the cells were very active in carrying out glucuronidation and phenolic ring deiodination, and this metabolism yielded 3,3′,5′-triiodothyronine and 3,3′-diiodothyronine glucuronides. The iodide fraction contained a small amount of 3,3′-diiodothyronine sulfate.These results show that the R117-21B rat hepatoma cells metabolize the thyroid hormones and their analogs by phenolic and nonphenolic ring deiodinations, by glucuronidation and by sulfation.     

Phenolic and nonphenolic ring deiodinations of iodothyronines in cultured hepatocarcinoma cell homogenate from monkey.

Iodothyronine monodeiodinase activities in homogenates of cultured monkey hepatocarcinoma cells were measured by the deiodination of [3.5-(125)I]-diiodo-L-thyronine or 3-[3',5'-(125)I]triiodo-L-thyronine (phenolic ring-labeled 'reverse' triiodothyronine). The assay system utilized a small ion-exchange column (AG50W-X4, O.9 X approximately 1 cm) to measure 125I-. Both deiodinases were destroyed by boiling for 1 min. Maximal nonphenolic ring deiodination was observed at pH 7.9 whereas maximal phenolic ring deiodination was at pH 6.3. Both reactions were enhanced strongly by dithiothreitol (0.1-5mM), and slightly by 5 mM beta-mercaptoethanol. Phenolic ring deiodination was strongly inhibited by 0.1 mM propylthiouracil. Nonphenolic ring deiodination was accelerated by EDTA (1.2 MM) and inhibited by Mg(2+) (5mM). Methylmercaptoimidazol and Mg(2+), Ca(2+) and Mn(2+) (0.1-1.0 mM) had little or no effect on either reaction, but Zn(2+) (0.1 mM) strongly inhibited both. Both reactions were inhibited by excess iodothyronine analogues at 10 mM to 10 micron M, and thyroxine was shown to be a competitive inhibitor in both cases. On the basis of relative affinities and inhibitory effects, it appears that the order of affinity for the phenolic ring deiodinase is 3,3',5'-triiodo-L-thyronine(rT3) greater than L-thyroxine(T4) greater than 3,5,3'-triiodo-L-thyronine(T3), whereas for the nonphenolic ring deiodinase the order is T3 greater than T4 greater than rT3. Diiodotyrosine did not affect their deiodination.     

Effect of thyroid hormone analogues on the displacement of 125I-L-triiodothyronine from hepatic and heart nuclei in vivo: possible relationship to hormonal activity

The capacity of iodotyrosines and iodothyronine analogues to displace tracer[¹²⁵I] L-3,5,3′ triiodothyronine from specific nuclear binding sites in rat liver and heart was related to the displacement capacity of nonradioactive triiodothyronine. Iodotyrosines and L-3,3′,5′ triiodothyronine (“reverse T₃”) were devoid of displacement activity. Analogues with 3,5 substitution in the “inner” ring and single “bulk” substitution in the 3′ position in the phenolic ring exhibited the strongest displacement activity. When the distribution, fractional removal rates and metabolic conversion of the analogues were taken into account, displacement activity appeared to correlate well with the reported thyromimetic activity. These results support the biologic relevance of the nuclear sites.     

Thyroid hormone: Aldosterone antagonism in cultured epithelial cells

Thyroid hormone (T₃) has been demonstrated to inhibit the action of aldosterone on sodium transport in toad urinary bladder and rat kidney. We have exammined the effect of T₃ on aldosterone action and specific nuclear binding in cultured epithelial cells derived from toad urinary bladder. In cell line TB6-C, addition of 5·10⁻⁸ M T₃ to culture media for up to 3 days results in no change in short-circuit current or transepithelial resistance. This concentration of T₃ completely inhibits the maximal increase in short-circuit current in response to 1·10⁻⁷ M aldosterone. The inhibition can be demonstrated with 18 h preincubation or with simultaneous addition of T₃ and aldosterone. The half-maximal concentration for the inhibition of the aldosterone effect is approx. 5·10⁻⁹ M T₃. T₃ has no effect on cyclic AMP-stimulated short-circuit current in these cells. The effect of T₃ on nuclear binding of [³H]aldosterone was examined using a filtration assay with data analysis by at least-squares curve-fitting program. Best fit was obtained with a model for two binding sites. The dissociation constants for the binding were K′_d1 = (0.82 ± 0.36)·10⁻¹⁰ M and K′_d2 = (3.2±0.60)·10⁻⁸ M.The half-maximal concentration for aldosterone-stimulated sodium transport in these cells is approx. 1·10⁻⁸ M. Analysis of nuclear aldosterone binding in cells preincubated for 18 h with 5·10⁻⁸ M T₃ showed a K′_d1 = (0.15 ± 0.10)·10⁻¹⁰ M and K′_d2 = (3.5 ± 0.10)·10⁻⁸ M. We conclude that T₃ i action of aldosterone on sodium transport at a site after receptor binding in the nucleus.     

The role of selenium in thyroid hormone metabolism and effects of selenium deficiency on thyroid hormone and iodine metabolism

Selenium deficiency impairs thyroid hormone metabolism by inhibiting the synthesis and activity of the iodothyronine deiodinases, which convert thyroxine (T₄) to the more metabolically active 3,3′-5 triiodothyronine (T₃). Hepatic type I iodothyronine deiodinase, identified in partially purified cell fractions using affinity labeling with [¹²⁵I]N-bromoacetyl reverse triiodothyronine, is also labeled with⁷⁵Se by in vivo treatment of rats with⁷⁵Se-Na₂SeO₃. Thus, the type I iodothyronine 5′-deiodinase is a selenoenzyme. In rats, concurrent selenium and iodine deficiency produces greater increases in thyroid weight and plasma thyrotrophin than iodine deficiency alone. These results indicate that a concurrent selenium deficiency could be a major determinant of the severity of iodine deficiency.     

Simultaneous determination of stable isotopically labelled l-histidine and urocanic acid in human plasma by stable isotope dilution mass spectrometry

A capillary gas chromatographic—mass spectrometric method for the simultaneous determination of stable isotopically labelled l-histidine (l-[3,3-²H₂,1′,3′-¹⁵N₂]histidine, l-His-[M + 4]) and urocanic acid ([3-²H,1′,3′-¹⁵N₂]urocanic acid, UA-[M + 3]) in human plasma was developed using dl-[2,3,3,5′-²H₄,2′-¹³C,1′,3′-¹⁵N₂]histidine (dl-His-[M + 7]) and [2,3,5′-²H₃,2′-¹³C,1′,3′-¹⁵N₂]urocanic acid (UA-[M + 6]) as internal standards. l-Histidine and urocanic acid were derivatized to ^αN-(trifluoroacetyl)-^imN-(ethoxycarbonyl)-l-histidine n-butyl ester and ^imN-(ethoxycarbonyl)urocanic acid n-butyl ester. Quantification was carried out by selected ion monitoring of the molecular ions of the respective derivatives of l-His-[M + 4], dl-His-[M + 7], UA-[M + 3] and UA-[M + 6]. The sensitivity, specificity, precision and accuracy of the method were demonstrated to be satisfactory for measuring plasma concentrations of l-His-[M + 4] and UA-[M + 3] following administration of trace amounts of l-His-[M + 4] to humans.     

The role of selenium in thyroid hormone metabolism and effects of selenium deficiency on thyroid hormone and iodine metabolism

Selenium deficiency impairs thyroid hormone metabolism by inhibiting the synthesis and activity of the iodothyronine deiodinases, which convert thyroxine (T₄) to the more metabolically active 3,3′–5 triiodothyronine (T₃). Hepatic type I iodothyronine deiodinase, identified in partially purified cell fractions using affinity labeling with [¹²⁵I]N-bromoacetyl reverse triiodothyronine, is also labeled with⁷⁵Se by in vivo treatment of rats with⁷⁵Se−Na₂SeO₃. Thus, the type I iodothyronine 5′-deiodinase is a selenoenzyme. In rats, concurrent selenium and iodine deficiency produces greater increases in thyroid weight and plasma thyrotrophin than iodine deficiency alone. These results indicate that a concurrent selenium deficiency could be a major determinant of the severity of iodine deficiency.     

The localization of phenolic and tyrosyl ring thyroxine deiodination in rat and mouse retina

To elucidate T₄ metabolism in various cell types of rat retina, 5-monodeiodinating and 5′-monodeiodinating activities were studied in retinal cell layers obtained by selective cytotoxic action of monosodium glutamate on bipolar and ganglion cell layers and by iodoacetate effect on photoreceptor cells. Concomitantly these enzyme activities were studied in C3H/HeN mouse retina genetically deprived of photoreceptor cells. Deiodinase activities were low in rat and mouse retina deprived of photoreceptors. The 5′-monodeiodination rate of T₄ was higher than T₄ tyrosyl ring deiodination in cell layers examined and the highest values were found in the photoreceptor cells. Data support the hypothesis that phenolic and tyrosyl ring deiodinase activities are present in the photoreceptor cells. Their reciprocal changes may regulate the nuclear function which in turn controls the rhythmical renewal of rod outer segments.     

Sex steroids modulate rat anterior pituitary and liver iodothyronine deiodinase activities.

In this study, we investigated the sex hormone regulation of 5'-iodothyronine deiodinase activity, which is responsible for enzymatic conversion of thyroxine into the bioactive form, triiodothyronine. Pituitary homogenates and liver microsomes from: 1) ovariectomized rats injected with 17-beta-estradiol benzoate and/or progesterone (0.7 and 250 microg/100 g body weight, respectively, subcutaneously, over 10 days); 2) male castrated rats treated or not with 0.4 mg/100 g body weight testosterone propionate, intramuscular, over 7 days, were assayed for type 1 and type 2 deiodinase activity in the pituitary. Enzyme activities were measured by release of (125)I from deiodination of (125)I reverse triiodothyronine under varying assay conditions. Estrogen stimulated anterior pituitary and liver type 1 deiodinase activity in ovariectomized rats (45 and 30 %, p < 0.05). Progesterone inhibited the liver enzyme (40 %, p < 0.05), and had no effect on the pituitary, but in both tissues, blocked estrogen stimulatory effect on type 1 deiodinase. In males, testosterone normalized the reduced liver type 1 deiodinase of castrated rats. However, in the pituitary, castration increased (50 %) type 1 deiodinase independent of testosterone treatment, suggesting the existence of a inhibitory testicular regulator of pituitary type 1 enzyme. Treatments did not alter pituitary type 2 deiodinase activity. In conclusion, gonads and sex steroids differentially modulate type 1 deiodinase activity in rat pituitary and liver.     

The effect of propylthiouracil on thyroid-stimulating hormone-induced alterations in iodothyronine secretion from perfused dog thyroids

The aim of this study was to see whether the inhibitory effect of propylthiouracil on thyroidal secretion of 3,5,3′-triiodothyronine (T₃) and 3,3′,5′-triiodothyronine (rT₃) could be reproduced in intensively stimulated thyroids, and to elucidate whether an increase in the fractional deiodination of thyroxine (T₄) to T₃ and rT₃ during iodothyronine secretion might be responsible for the transient fall in the T₄/T₃ and T₄/rT₃ ratios in thyroid secretion seen in the early phase after stimulation of thyroid secretion.For this purpose T₄, T₃ and rT₃ were measured in effluent from isolated dog thyroid lobes perfused in a non-recirculation system using a synthetic hormone free medium. 1 mmol/l propylthiouracil induced a significant reduction in thyroid-stimulating hormone (TSH) stimulated T₃ and rT₃ release while the release of T₄ was unaffected. This supports our previous conclusion that T₄ is partially monodeiodinated to T₃ and rT₃ during thyroid secretion. Infusion of 1 mmol/l propylthiouracil for 30 min or 3 mmol/l propylthiouracil for 120 min did not abolish the transient fall in effluent T₄/T₃ and T₄/rT₃ induced by TSH stimulation. Thus, this phenomenon seems not to depend on intrathyroidal iodothyromine deiodinating processes.     

Bioenergetic impact of tissue-specific regulation of iodothyronine deiodinases during nutritional imbalance

The regulation of energy homeostasis by thyroid hormones is unquestionable, and iodothyronine deiodinases are enzymes involved in the metabolic activation or inactivation of these hormones at the cellular level. T3 is produced through the outer ring deiodination of the prohormone T4, which is catalyzed by types 1 and 2 iodothyronine deiodinases, D1 and D2. Conversely, type 3 iodothyronine deiodinase (D3) catalyzes the inner ring deiodination, leading to the inactivation of T4 into reverse triiodothyronine (rT3). Leptin acts as an important modulator of central and peripheral iodothyronine deiodinases, thus regulating cellular availability of T3. Decreased serum leptin during negative energy balance is involved in the down regulation of liver and kidney D1 and BAT D2 activities. Moreover, in high fat diet induced obesity, instead of increased serum T₃ and T₄ secondary to higher circulating leptin and thyrotropin levels, elevated serum rT3 is found, a mechanism that might impair the further increase in oxygen consumption.     

Molecular Mechanism of Photoperiodic Time Measurement in the Brain of Japanese Quail

In most organisms living in temperate zones, reproduction is under photoperiodic control. Although photoperiodic time measurement has been studied in organisms ranging from plants to vertebrates, the underlying molecular mechanism is not well understood. The Japanese quail (Coturnix japonica) represents an excellent model to study this problem because of the rapid and dramatic photoperiodic response of its hypothalamic‐pituitary‐gonadal axis. Recent investigations of Japanese quail show that long‐day‐induced type 2 deiodinase (Dio2) expression in the mediobasal hypothalamus (MBH) plays an important role in the photoperiodic gonadal regulation by catalyzing the conversion of the prohormone thyroxine (T₄) to bioactive 3,5,3′‐triiodothyronine (T₃). The T₃ content in the MBH is approximately 10‐fold higher under long than short days and conditions, and the intracerebroventricular infusion of T₃ under short days and conditions mimics the photoperiodic gonadal response. While Dio2 generates active T₃ from T₄ by outer ring deiodination, type 3 deiodinase (Dio3) catalyzes the conversion of both T₃ and T₄ into inactive forms by inner ring deiodination. In contrast to Dio2 expression, Dio3 expression in the MBH is suppressed under the long‐day condition. Photoperiodic changes in the expression of both genes during the photoinduction process occur before the changes in the level of luteinizing hormone (LH) secretion, suggesting that the reciprocal changes in Dio2 and Dio3 expression act as gene switches of the photoperiodic molecular cascade to trigger induction of LH secretion.     

Atrial and brain natriuretic peptides share binding sites on cultured cells from the rat trachea

Summary We examined the distribution of binding sites for alpha-atrial natriuretic peptide (¹²⁵I-ANP_1–28) and the recently discovered porcine brain natriuretic peptide (¹²⁵I-pBNP) on immunocytochemically identified cells in dissociated culture preparations of the rat trachea. Specific binding sites for both ¹²⁵I-ANP_1–28 and ¹²⁵I-pBNP were evenly distributed over distinet subpopulations of smooth muscle myosin-like immunoreactive muscle cells, fibronectin-like immunoreactive fibroblasts and S-100-like immunoreactive glial cells. Neither keratin-like immunoreactive epithelial cells nor protein gene product 9.5-like immunoreactive paratracheal neurones expressed natriuretic peptide binding sites, although autoradiographically labelled glial cells were seen in close association with both neuronal cell bodies and neurites. The binding of each radiolabelled peptide was abolished by the inclusion of either excess (1 M) unlabelled rat ANP or excess unlabelled porcine BNP, suggesting that ANP and BNP share binding sites in the trachea. Furthermore, the ring-deleted analogue, Des-[Gln¹⁸, Ser¹⁹, Gly²⁰, Leu²¹, Gly²²]-ANF_4–23-NH₂, strongly competed for specific ¹²⁵I-ANP_1–28 and ¹²⁵I-pBNP binding sites in the tracheal cultures; this suggests that virtually all binding sites were of the clearance (ANP-C or ANF-R₂) receptor subtype.     

Effect of Cold Exposure on Thyroid Hormone Metabolism and Nuclear Binding in Rat Brain

In this study we examined whether adult rat brain tissue (cerebral hemispheres) would under cold exposure respond with changes in the local metabolism and nuclear binding of thyroid hormones (T₃, T₄). Adult, control rats kept at 22°C and cold exposed (4°C, 20 h) rats were injected with trace of ¹²⁵I-T₄ or ¹²⁵I-T₃ returned to their respective environment and sacrificed four hours later. The radioactive hormonal forms were identified and quantified in the cytoplasmic and nuclear fractions. It was found that in cold exposed rats injected with ¹²⁵I-T₄, the total cytoplasmic radioactivity was higher than that of controls. This increase was not associated with ¹²⁵I-T₄ but it reflected an increase (88 %) in its deiodination product ¹²⁵I-T₃ (¹²⁵I-T₃ (T₄)). Although total cytoplasmic ¹²⁵I-T₄ did not change, there was a decrease (28%) in its protein free cytoplasmic fraction. ¹²⁵I-T₃ (T₄) and ¹²⁵I-T₄ bound to the nuclear fraction were found to decrease by 58 and 46% respectively. Cold exposed animals injected with ¹²⁵I-T₃ also showed an increase in cytoplasmic ¹²⁵I-T₃ (81%) and a decrease in ¹²⁵I^– (40%) whereas ¹²⁵I-T₃ bound to the nuclear fraction decreased by 64%. These results indicate that cold exposure of rats decreases brain local T₃ metabolism and nuclear binding while it does not effect local T₄ metabolism.     

Haemoglobin adducts of aromatic amines: diamines and polyaromatic amines

Aromatic amines and nitroarenes are important antioxidants and intermediates in the synthesis of dyes, pesticides and plastics. In the present paper we introduce methods for the synthesis of deuterated standards: 3-[²H₈]aminofluoranthene, 3,3′-dimethyl-[²H₄]benzidine, [²H₄]benzidine, N′-acetyl-[²H₄]benzidine, 2,4-[²H₆]toluenediamine, 2,6-[²H₆]toluenediamine. These standards have been used for the quantification of haemoglobin adducts of diamines and polyaromatic amines. Haemoglobin was hydrolysed in 0.1 M sodium hydroxide and the hydrolysate extracted with dichloromethane. The extracts were derivatised with heptafluorobutyric anhydride and analysed by GC–MS with negative chemical ionisation. In one run up to 15 aromatic amines can be determined: 6-aminochrysene, 3-aminofluoranthene, 2-aminofluorene, 1-aminopyrene, benzidine, 3,3′-dichlorobenzidine, 3,3′-dimethoxybenzidine, 3,3′-dimethylbenzidine, 3,3′-methylenedianiline, 4,4′-methylenedianiline, N′-acetyl-benzidine, N′-acetyl-4,4′-methylenedianiline, 4,4′-methylene bis(2-chloroaniline), 2,4-toluenediamine and 2,6-toluenediamine.     

Conversion and binding of tetraiodothyronine in developing rat brain

In this study we have examined whether rat brain nuclear thyroid hormone receptors bind T₄ or metabolites of T₄ and whether there is a developmental change in brain T₄ metabolism and binding. Developing animals were injected with trace [¹²⁵I]3,5-tetraiodothyronine ([¹²⁵I]T₄) and after sacrifice brain nuclear and cytoplasmic fractions were examined to determine whether their radioactivity was represented by the injected [¹²⁵I]T₄ or any of its metabolites. Of the radiothyronines specifically bound to the nucleus, 90% was found to be triiodothyronine ([¹²⁵I] T₃) and 10% was [¹²⁵I]T₄. Of the cytoplasmic, protamine sulfate-precipitable fraction, 40% was [¹²⁵I]T₄ and 60% [¹²⁵I]T₃. Inasmuch as the percentage of [¹²⁵I] T₃ found in plasma during the same postinjection interval was similar to that present as contaminant of the injected material, it was concluded that brain [¹²⁵I] T₃ derives from local monodeiodination of T₄ to T₃. The main developmental change observed was a marked decline in the total cytoplasmic and nuclear [¹²⁵I] T₄ uptake. However, with development, the T₃/T₄ ratio remained constant in the nuclear fraction while it decreased in the cytoplasmic fraction. It is concluded that although T₃, deriving from monodeiodianation of T₄, is the main form of thyroid hormone that regulates brain development by its binding to brain nuclear receptors, the fact that T₄ is the most available from during the critical period makes it, indirectly, very important to brain development. Further, the decline observed with development in T₄ uptake and monodeiodination to T₃, may contribute to the concomitantly declining role of thyroid hormones on brain tissue.     

DNA adduct formation in human hepatoma cells treated with 3-nitrobenzanthrone: analysis by the P-postlabeling method

3-Nitrobenzanthrone (3-nitro-7H-benz[d,e]anthracen-7-one, 3-NBA) is a powerful mutagen and a suspected human carcinogen existing in diesel exhaust and airborne particulates. Recently, one of the major presumed metabolites of 3-NBA, 3-aminobenzanthrone (3-ABA), was detected in human urine samples. Here we analyzed DNA adducts formed in 3-NBA-exposed human hepatoma HepG2 cells by a ³²P-postlabeling/thin layer chromatography (TLC) method and a ³²P-postlabeling/polyacrylamide gel electrophoresis (PAGE) method. With HepG2 cells exposed to 3-NBA (0.36–36.4 μM) for 3 h, we obtained three spots or bands corresponding to adducted nucleotides. Two were assigned as 2-(2′-deoxyadenosin-N⁶-yl)-3-aminobenzanthrone-3′-phosphate (dA3′p-N⁶-C2-ABA) and 2-(2′-deoxyguanosin-N²-yl)-3-aminobenzanthrone-3′-phosphate (dG3′p-N²-C2-ABA), with identical mobilities to those of synthetic standards on PAGE analysis. The chemical structure of the substance corresponding to the other spot or band could not be identified. Quantitative analyses revealed that the major adduct was dA3′p-N⁶-C2-ABA and its relative adduct labeling (RAL) value at 36.4 μM of 3-NBA was 200.8 ± 86.1/10⁸ nucleotide.     

Postlabelling analysis of DNA adducts formed in human hepatoma cells treated with 3-nitrobenzanthrone

3-Nitrobenzanthrone (NBA) is one of the most mutagenic nitroaromatic compounds that has been found recently in diesel exhaust and airborne particles. A [³²P]-postlabelling analysis was carried out to examine the adducts in DNA from human hepatoma HepG2 cells treated with NBA. Two major and two minor adduct spots were obtained in the analysis. The structure of the compound obtained from one of the minor adduct spots was identified to be N-acetyl-3-amino-2-(2′-deoxyguanosin-3′,5′-bisphosphate-8-yl)-benzanthrone, based on identical mobility of the compound with that of synthetic standards in thin-layer chromatography and high performance liquid chromatography. This substance is the identical adduct found in our previous in vitro study. The yet-unidentified major adduct spots may be guanosin- and adenosin-benzanthrone adducts without the N-acetyl group.