Cytochrome P450-Catalyzed Binding of 3-Methylsulfonyl- DDE and o,p’-DDD in Human Adrenal Zona Fasciculata/Reticularis
ÖRJAN LINDHE, BRITT SKOGSEID, AND INGVAR BRANDT
Department of Environmental Toxicology (Ö.L., I.B.), Uppsala University, Norbyvägen 18A, S-752 36 Uppsala, Sweden; and Endocrine Oncology Unit (B.S.), Department of Medical Sciences, University Hospital, S-751 85 Uppsala, Sweden
3-Methylsulfony1-2,2’-bis(4-chlorophenyl)-1,1’-dichloroethene (MeSO2-DDE) is a potent, tissue-specific toxicant that induces necrosis of the adrenal zona fasciculata following a local CYP11B1-catalyzed activation to a reactive intermediate in mice. Autoradiography was used to examine CYP11B1-cata- lyzed binding of MeSO2-[14C]DDE and the adrenocorticolytic drug 2-(2-chlorophenyl)-2-(4-chlorophenyl)-1,1-dichloreth- ane; (o,p’-[14C]DDD, Mitotane, Lysodren) in human adrenal tissue slice culture. Both compounds gave rise to a selective binding in the one sample of normal adrenal zona fasciculata/ reticularis, leaving zona glomerulosa and the adrenal medulla devoid of binding. Addition of the CYP11B1 selective inhibitor metyrapone (50 µM) reduced MeSO2-[14C]DDE binding below the detection limit, whereas o,p’-[14C]DDD binding was re- duced only by 42%. Selective binding of MeSO2-[14C]DDE and
o,p’-[14C]DDD was also observed in an aldosterone-producing adrenocortical carcinoma and in a nonfunctional adrenocor- tical hyperplasia. Exposure of slices from the normal adrenal cortex to MeSO2-DDE (25 M) resulted in an increased accu- mulation of 11-deoxycorticosterone, 11-deoxycortisol and an- drostenedione in the medium, and exposure to o,p’-DDD (25 UM) did not alter the steroid secretion pattern. No histologi- cal changes were found in either MeSO2-DDE- or o,p’-DDD- exposed slices, compared with nonexposed slices. We suggest that MeSO2-DDE might act as a potent adrenocorticolytic agent in humans. Further studies are needed to establish the usefulness of MeSO2-DDE as a possible alternative for the treatment of adrenocortical hypersecretion and tumor growth. (J Clin Endocrinol Metab 87: 1319-1326, 2002)
T HE ADRENOCORTICOLYTIC ACTIVITY of 2-(2-chlo- rophenyl)-2-(4-chlorophenyl)-1,1-dichlorethane; (o,p’- DDD, Mitotane, Lysodren) was first described in 1949 in dogs (1). o,p’-DDD has subsequently proved to be a tissue- selective toxicant, following local metabolic activation and irreversible protein binding in the adrenal cortex in several species including human (2), dog (3), domestic fowl (4), and mink (5). By virtue of its tissue-selective toxicity, o,p’-DDD is currently used as an adrenocorticolytic drug for treatment of adrenocortical carcinoma and Cushing’s syndrome (6-8). The effective dose for treatment of adrenocortical cancer gives a plasma concentration higher than 14 µg/ml (44 [M), whereas plasma concentration below 10 µg/ml (31 µM) seems therapeutically insufficient (9, 10). Only one-third of the patients (194 of 551) who were not cured by surgery, responded to o,p’-DDD treatment (7). In addition to hypo- cortisolism, o,p’-DDD gives rise to dose-dependent side ef- fects in the gastrointestinal tract (nausea, vomiting, and di- arrhea) and central nervous system (dizziness and headache). Treatment-related unspecific effects such as weakness and fatigue are also observed (10-12). In a sub- stantial proportion of patients, these side effects are intoler- able at therapeutic doses, and the drug has had to be withdrawn.
Aryl methyl sulfones of DDE and PCBs were first identi- fied in blubber of Baltic gray seal (13). The sulfones form in
the mercapturic acid pathway, involving sequential meta- bolic transformation during enterohepatic circulation (14). Several of the methyl sulfones are characterized by a highly cell- and tissue-selective distribution pattern in the body. 3-Methylsulfonyl-2,2’-bis(4-chloro-[14C]phenyl)-1,1’-dichlo- roethene (MeSO2-[14C]DDE) was originally found to give rise to a cell-specific irreversible binding in mouse adrenal zona fasciculata cells in vivo (15). MeSO2-DDE was subsequently demonstrated to be a highly potent adrenal toxicant that induces mitochondrial degeneration and cell death following a CYP11B1-catalyzed metabolic activation in the murine ad- renal cortex (15-17). Adrenocortical cell death and reduced plasma corticosterone levels is seen in fetal and suckling mice following exposure of the pregnant or lactating dam to MeSO2-DDE (18-20). The toxicity of MeSO2-DDE in the fetal adrenal zona fasciculata is effectively blocked by maternal metyrapone treatment in mice (20). A relationship among time, dose, and extent of zona fasciculata damage is evident in adult mice (17). As demonstrated by metabolic binding studies using the mitochondrial fraction of human adrenal homogenate from four subjects, the human adrenal cortex also seems capable of forming irreversibly bound MeSO2- [14C]DDE-protein adducts (21).
The dechlorinated DDT metabolite DDE is the major per- sistent environmental pollutant present in human blood and breast milk worldwide (22). In the past decade, high DDE levels have been reported in Mexico (23, 24), Brazil (25), Ukraine (26), and Zimbabwe (27). In Swedish breast milk samples, the level of p,p’-DDE is correlated to that of MeSO2- DDE (360 and 1.5 ng/g lipid, respectively) (28, 29). The
Abbreviations: BG, Background; CYP, cytochrome P450; DMSO, di- methylsulfoxide; MeSO2-DDE, 3-methylsulfonyl-2,2’-bis(4-chloro- phenyl)-1,1’-dichloroethene; o,p’-DDD, 2-(2-chlorophenyl)-2-(4-chlo- rophenyl)-1,1-dichlorethane; PSL, photo-stimulated luminescence.
corresponding levels of p,p’-DDE and MeSO2-DDE in Mex- ican breast milk are as high as 13,900 and 130 ng/g lipid, corresponding to about 15 nmol MeSO2-DDE/liter milk (Bergman, Å., personal communication).
We have recently described a simple precision-cut tissue slice culture procedure, with which to examine MeSO2-DDE- induced irreversible binding as well as functional and mor- phological changes in the adrenal cortex (30). In the present study, we used this procedure to examine cytochrome P450- catalyzed irreversible binding of MeSO2-[14C]DDE and o,p’- [14C]DDD in human adrenal tissue ex vivo.
Materials and Methods
Adrenal tissue
Normal adrenal tissue, cortex as well as apparently unaffected me- dulla, was obtained from a 34-yr-old female MEN type 2 patient oper- ated on for an ipsilateral pheochromocytoma.
Tissue from a lymph node metastasis of an aldosterone-producing adrenocortical carcinoma was obtained from a 54-yr-old male.
Tissue from a bilateral nonfunctioning adrenocortical hyperplasia was obtained from a 58-yr-old female.
Informed consent was given by all three patients.
Chemicals
MeSO2-[14C]DDE (495 MBq/mmol), unlabeled MeSO2-DDE, and o,p’-[14C]DDD (414 MBq/mmol) were kindly donated by Åke Bergman (Department of Environmental Chemistry, Stockholm University, Stock- holm, Sweden) (31, 32). As determined by gas chromatography mass spectroscopy, radiochemical purity values were more than 99%. Tetra- cosactide (Synacten depot, 1 mg/ml) was obtained from Ciba (V. Fröl- unda, Sweden), dimethylsulfoxide (DMSO), and agarose (type VII, low melting temperature) were from Sigma (St. Louis, MO). Methacrylate Technovit 7100 was obtained from Kulzer (Wehrheim, Germany). All liquids and dyes were from Merck and Co. (Darmstadt, Germany) ex- cept chloroform, which came from Prolabo (Paris, France). Liquid film NTB 2 was purchased from Kodak (Rochester, NY).
Preparation and incubation of tissue slices
Adrenal tissue was placed in ice-cold isotonic saline solution after removal and kept on ice until embedded in 3% agarose. Precision-cut slices (200 um) were prepared in a Krumdieck tissue slicer (Alabama Research and Development, Munford, AL) in ice-cold PBS (33). Slices of about equal size were placed in six-well plates containing culture me- dium on a titanium screen holder and incubated for 24 h (after a 1-h preincubation; 1 slice/well; four to five wells per treatment), as de- scribed elsewhere (30).
To inhibit CYP-dependent enzyme activity in the slices, incubation wells were supplemented with the CYP11B1 (11ß-hydroxylase) inhibitor metyrapone (50 µM) when applicable. To stimulate ACTH-regulated enzyme activity in the slices, the synthetic ACTH-analog tetracosactide (11 nM) was added. The labeled and unlabeled test substances (MeSO2- DDE and o,p’-DDD) were added to the fresh incubation medium, dis- solved in DMSO (not exceeding 0.5% of the total volume). Control slices were cultured in medium containing DMSO only.
Autoradiography
Microautoradiography. Slices were incubated with MeSO2-[14C]DDE (2.6 IM, 1.3 kBq/ml) or o,p’-[14C]DDD (3.8 [M, 2.2 kBq/ml) for 24 h. Fol- lowing incubation, slices were fixed overnight in buffered formaldehyde (4%). The fixed slices were dehydrated, embedded in methacrylate, sectioned, and dipped in liquid NTB2 film emulsion, as described else- where (30). Autoradiograms were exposed (4 C) for 1 yr to enable localization of irreversible binding in metyrapone-treated slices. Auto- radiograms were developed, stained, and examined as previously de- scribed (30).
Radioluminography. Semiquantification of tissue-bound radioactivity was accomplished by apposing tissue sections to imaging plates (BAS-Ip MP 2040S, Fuji Photo Film Co., Ltd., Tokyo, Japan) for 49 d. The radio- activity in the labeled areas of the adrenal sections was recorded by reading the imaging plate in a Phosphoimager (BAS 1500, Fuji Photo Film Co., Ltd.) (34, 35). For semiquantification of the tissue-bound ra- dioactivity, a Windows-based bioimaging analyzer program (Image- Gauge, version 3.122, Fuji Photo Film Co., Ltd., Tokyo, Japan) was used.
To correlate tissue-bound radioactivity and metabolically active re- gions in the incubated slices, the labeled areas of the images were marked selectively at 1 pixel resolution (1 pixel = 100 um). Values obtained were expressed as photo-stimulated luminescence (PSL) minus background (BG) per square millimeter of 2-um-thick tissue sections (PSL-BG)/mm2). The values were adjusted according to the difference in specific activity of the two compounds.
To check the imaging plates with respect to exposure linearity, the same plate was repeatedly exposed to the same sections for 7, 14, 28, 49 and 122 d, reading and erasing the plate between each exposure. To examine interexposure variation, the imaging plate was exposed re- peatedly (three times) for 7 d, reading and erasing the plate between each exposure. Intraexposure variation was measured on three adjacent sec- tions on the same glass slide.
Hormone analysis
Cortisol, 11-deoxycortisol, corticosterone, 11-deoxycorticosterone, al- dosterone, androstenedione, and 17-OH-progesterone concentrations in the medium after 24 h of culture were measured with HPLC using UV detection (241 nm), as described previously (30). The steroid products were separated using a linear gradient of 18-80% acetonitrile (1 ml/ min), obtained by diluting acetonitrile/ tetrahydrofuran (90/10 vol/vol) with methanol/water (40/60 vol/vol) for 32 min. The amounts of ste- roids were expressed as nanomole per slice. The detection level of cortisol/corticosterone was 5 pmol/ml medium. To adjust for differ- ences in slice size, the steroids were expressed as a percentage of the amount of cortisol from the same slice.
Histology
MeSO2-DDE and o,p’-DDD (dissolved in DMSO) were added to the wells in amounts corresponding to a final concentration of 25 µM in the medium. Following incubation, slices were embedded in methacrylate and prepared for light microscopy as above. For reference purposes, some adrenal slices were fixed directly after sectioning.
Statistical evaluation of data
Statistical analysis performed using one-way ANOVA (Bonferroni’s multiple comparison test as the posttest) to analyze hormone concen- trations, t test to analyze bound radioactivity, and linear regression test to analyze exposure linearity. Significance was assigned a value of P less than 0.05. All tests were performed with Prism software version 3.0 for Windows (GraphPad Software, Inc., San Diego, CA).
Results
Autoradiography
As determined by light microscopy, autoradiograms of adrenal slices exposed to MeSO2-[14C]DDE (Figs. 1 and 2, A and B) or to o,p’-[14C]DDD (Fig. 3, A and B) showed a high and selective labeling of zona fasciculata and zona reticularis in the one sample of normal adrenal cortex. The labeling of zona reticularis was markedly stronger than that of zona fasciculata. Zona glomerulosa and the adrenal medulla were devoid of bound radioactivity exceeding that of the background level (Figs. 2, E and F, and 3, E and F).
As determined by radioluminography, no significant dif- ference in the amount of tissue-bound radioactivity between MeSO2-[14C]DDE- and o,p’-[14C]DDD-exposed slices could be detected (Fig. 4). The images of tissue-bound radioactivity
A
B
C
semiquantified with radioluminography closely matched the images of the microautoradiograms (Fig. 1). In slices exposed to metyrapone and MeSO2-[14C]DDE, binding in zona fas- ciculata/reticularis was inhibited below the detection limit (P < 0.05) at 49 d of exposure (Figs. 2, C and D, and 4). In metyrapone-exposed slices, irreversible o,p’-[14C]DDD- binding in zona fasciculata / reticularis was inhibited by 42 plus or minus 12% (± SEM; P < 0.05), compared with slices ex- posed only to o,p’-[14C]DDD (Figs. 3, C and D, and 4).
With increasing exposure time, the slopes of the linear regression lines for MeSO2-[14C]DDE and o,p’-[14C]DDD dif- fered significantly from that of the background (r2 > 0.96; P < 0.01). Variation in (PSL-BG)/mm2 values between different exposures of the same MeSO2-[14C]DDE-exposed slice was less than 8% (35.6 ± 2.8; mean ± SEM). Intraexposure vari- ation was less than 2% (113.8 ± 1.5; mean ± SEM) for three adjacent sections.
Slices from a lymph node metastasis of an aldosterone- producing adrenocortical carcinoma, exposed to MeSO2- [14C]DDE (Fig. 2, G and H) or to o,p’-[14C]DDD (Fig. 3, G and H) showed a selective binding of both compounds to the adrenocortical carcinoma cells. No labeling above the back- ground level could be observed in surrounding tissues.
In slices from a bilateral nonfunctioning adrenocortical hyperplasia, the levels (for both compounds) of bound ra- dioactivity were about one-third of that in normal adrenal tissue (P < 0.001, data not shown). The binding of both compounds was inhibited to the same extent with metyra- pone treatment as in the normal tissue.
Steroid hormone secretion
Cortisol, 11-deoxycortisol, corticosterone, 11-deoxycorti- costerone, aldosterone, androstenedione, and 17-OH- progesterone were all detected in the culture medium after 24 h. Cortisol and corticosterone were the major secreted steroids, representing 53% and 29%, of the total steroid se- cretion from nonexposed control slices. In MeSO2-DDE- or o,p’-DDD-exposed (25 [M) slices, no significant difference in cortisol or corticosterone secretion could be observed, com- pared with control slices. No difference could be observed between MeSO2-DDE- or o,p’-DDD-exposed slices (Fig. 5A). A significant increase in 11-deoxycorticosterone secretion to the medium was observed in MeSO2-DDE-exposed slices, compared with o,p’-DDD-exposed slices and control slices (Fig. 5B; P < 0.05). Androstenedione secretion was also in- creased in MeSO2-DDE-exposed slices, compared with o,p’- DDD-exposed slices (Fig. 5B; P < 0.05). 11-Deoxycortisol was detectable only in the culture medium of MeSO2-DDE-ex- posed slices (Fig. 5B).
Histology
After 24 h of culture, no obvious histological differences could be observed between control slices and MeSO2-DDE- or o,p’-DDD-exposed (25 µM) slices. Compared with slices fixed immediately after slicing, cultured control slices were not visibly different (data not shown).
A
B
ZF
ZR
M
ZE
M
Control
C
D
Metyrapone
E
F
ZG
ZF
ZG
ZF
Control
G
H
AC
AC
Adrenocortical Carcinoma
A
B
ZF
ZR
M
ZF
ZR
M
Control
C
D
Metyrapone
E
F
ZG
ZF
ZG
ZF
Control
G
H
AC
AC
Adrenocortical Carcinoma
75
*
*
(PSL-BG)/mm2
50-
25
Below detection limit
0
MeSO2-DDE
MeSO2DDE+Metyrapone
o,p’-DDD
o,p’-DDD+Metyrapone
Discussion
Our previously reported findings in mouse adrenal tissue exposed to MeSO2-[14C]DDE ex vivo showed that strong ir- reversible binding was confined to zona fasciculata. In con- trast, o,p’-[14C]DDD-binding was very weak, compared with that of MeSO2-[14C]DDE. Interestingly, however, there was a selective localization of o,p’-[14C]DDD binding to both zona fasciculata and zona reticularis in the mouse adrenal cortex (30).
In this study we found a strong MeSO2-[14C]DDE-derived binding in human adrenal tissue that was confined to both zona fasciculata and zona reticularis in a normal cortex. Irre- versible o,p’-[14C]DDD-binding was localized in a similar way. Even though MeSO2-[14C]DDE concentration in the medium was almost half that of o,p’-[14C]DDD, the levels of binding were of roughly equal strength. In mouse, the MeSO2-DDE-activating enzyme CYP11B1 is expressed only in zona fasciculata (36). In the human adrenal cortex, CYP11B1 is expressed in both zona fasciculata and zona reticularis but not in zona glomerulosa, the adrenal medulla, or the capsule (37, 38). CYP11B1 was also found in an aldosterone-producing adenoma as well as in two incidentally detected adrenocor- tical adenomas (38). These discrepancies support the con- tention that CYP11B1 catalyzes activation of MeSO2-DDE to a reactive metabolite also in normal and cancerous human adrenal cortex.
Metyrapone is a potent CYP11B1 inhibitor that blocks syn- thesis of cortisol from 11-deoxycortisol (86%, 5 µM) in V79 hamster cells transfected with the human CYP11B1 gene (37). We have recently reported that metyrapone inhibits irre- versible MeSO2-[14C]DDE binding and corticosterone secre- tion in mouse adrenal slice culture and mouse adrenal ho- mogenate (15, 30, 39). Exposure of cultured human adrenal slices to metyrapone (50 µM) reduced irreversible MeSO2- [14C]DDE binding below the detection limit, whereas o,p’- [14C]DDD binding was reduced by only 42%. Provided that
A
1000
nmol steroid/ml medium
750
500
250
0
Cortisol
Corticosterone
Control
MeSO2-DDE
o,p-DDD
B
3
*
*
*
% of cortisol
2
1
·
.
·
.
0
Androstenedione
11-Deoxycorticosterone
11-deoxycortisol
the metabolic activation of o,p’-DDD is mainly dependent on CYP11B1, a more complete inhibition of binding would be expected. The observed inhibition of o,p’-[14C]DDD binding therefore supports the contention that another enzyme was also involved in the activation of o,p’-DDD in both human and mouse adrenal cortex. In mouse, CYP11B2 is expressed only in zona glomerulosa (36). Because no binding was ob- served in zona glomerulosa, either in human or mouse adrenal tissue, CYP11B2 was probably not involved in the metabolic activation of o,p’-DDD. If another enzyme in the steroid synthesis chain is involved, it seems likely that o,p’-DDD
binding would occur also in other steroid-secreting organs, such as testis and ovary. Indeed, we have preliminary find- ings showing that o,p’-[14C]DDD is bound in rat ovary gran- ulosa cells (Lindhe Ö, unpublished data). More studies re- garding the identities of o,p’-DDD-activating enzymes are needed.
Radioluminography proved to be a quick and sensitive way to quantify levels of metabolite binding in the human adrenal cortex. Combined with the exact localization of bind- ing obtained by microautoradiography, radioluminography is an efficient means to semiquantify the levels of bound MeSO2-[14C]DDE and o,p’-[14C]DDD adducts in the target cells (30). The linear increase in PSL/mm2 values during long exposure times and low exposure-to-exposure variation favors the quantitative use of radioluminography.
The adrenal cortex is complex with regard to the hormone secretion pattern. Adrenal endocrine disrupting substances have several enzymes to target, and the possible effects on homeostasis are numerous. By using precision-cut adrenal slice culture, we show that a number of steroids can be quantified in the culture medium and that changes in secre- tion pattern can be observed. Slice culture facilitates inves- tigations of effects caused by several compounds in one single individual. This method gave us the opportunity for comparisons of the drug effects per se without disturbance of interindividual variation. In our study on slices from one normal adrenal cortex, the concentration of o,p’-DDD (25 [M) did not produce any visible effect on steroid secretion, compared with control. Interestingly, at the same concen- tration and below the therapeutically effective o,p’-DDD plasma concentration, MeSO2-DDE (25 µM) gave rise to an increased accumulation of 11-deoxycorticosterone, 11- deoxycortisol, and androstenedione in the culture medium. This finding indicates a reduced CYP11B1 activity. In the human adrenocortical carcinoma cell-line H295R, MeSO2- DDE exposure reduced CYP11B1-catalyzed cortisol forma- tion after 24 h (Johansson, M., submitted for publication). Decreased corticosterone plasma levels have also been ob- served in suckling mouse pups following a single injection of MeSO2-DDE (6 mg/kg) to the lactating dam (18). In ho- mogenate incubations of cells from four specimens of human adrenal cortex, the apparent Km value of MeSO2-DDE bind- ing to protein was 17 times lower than that of o,p’-DDD (1.4 and 24 µM, respectively) (21). This implies that MeSO2-DDE might be toxic at lower doses than o,p’-DDD. These findings support the contention that MeSO2-DDE is a tissue-selective toxicant in the human adrenal cortex.
We conclude that one can examine steroid secretion from human adrenal slices ex vivo and suggest that the slice culture procedure could be useful for evaluating the endocrine dis- rupting potential of chemicals and pharmaceutical products. We also suggest that MeSO2-DDE be evaluated as a sus- pected human adrenal toxicant, especially with regard to the risk posed to suckling infants in developing countries. The numbers of human adrenals so far examined are limited and further studies needed. However, considering the low po- tency and the potentially severe side effects frequently ob- served following o,p’-DDD treatment (10-12), we propose that MeSO2-DDE should be evaluated as a possible alterna-
tive in the therapy of adrenocortical hypersecretion and tu- mor growth. (A patent application has been filed.)
Acknowledgments
Margareta Mattsson is acknowledged for excellent technical assis- tance, Dr. Åke Bergman (Department of Environmental Chemistry, Stockholm University, Stockholm, Sweden) for preparation of the 14C- labeled DDT derivatives, and M. Sci. Maria Johansson for helpful sug- gestions on the HPLC separation protocol.
Received August 1, 2001. Accepted November 14, 2001.
Address all correspondence and requests for reprints to: Dr. Ingvar Brandt, Department of Environmental Toxicology, Uppsala University, Norbyvägen 18 A, S-752 36 Uppsala, Sweden. E-mail ingvar.brandt @ebc.uu.se.
This work was supported financially by the Foundation for Strategic Environmental Research (MISTRA) and the Royal Swedish Academy of Sciences.
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