Edwin Sonneveld

Quantitative structure‐activity relationship modeling on in vitro endocrine effects and metabolic stability involving 26 selected brominated flame retardants

In this work, quantitative structure-activity relationships (QSARs) were developed to aid human and environmental risk assessment processes for brominated flame retardants (BFRs). Brominated flame retardants, such as the high-production-volume chemicals polybrominated diphenyl ethers (PBDEs), tetrabromobisphenol A, and hexabromocyclododecane, have been identified as potential endocrine disruptors. Quantitative structure-activity relationship models were built based on the in vitro potencies of 26 selected BFRs. The in vitro assays included interactions with, for example, androgen, progesterone, estrogen, and dioxin (aryl hydrocarbon) receptor, plus competition with thyroxine for its plasma carrier protein (transthyretin), inhibition of estradiol sulfation via sulfotransferase, and finally, rate of metabolization. The QSAR modeling, a number of physicochemical parameters were calculated describing the electronic, lipophilic, and structural characteristics of the molecules. These include frontier molecular orbitals, molecular charges, polarities, log octanol/water partitioning coefficient, and two- and three-dimensional molecularproperties. Experimental properties were included and measured for PBDEs, such as their individual ultraviolet spectra (200-320 nm) and retention times on three different high-performance liquid chromatography columns and one nonpolar gas chromatography column. Quantitative structure-activity relationship models based on androgen antagonism and metabolic degradation rates generally gave similar results, suggesting that lower-brominated PBDEs with bromine substitutions in ortho positions and bromine-free meta- and para positions had the highest potencies and metabolic degradation rates. Predictions made for the constituents of the technical flame retardant Bromkal 70-5DE found BDE 17 to be a potent androgen antagonist and BDE 66, which is a relevant PBDE in environmental samples, to be only a weak antagonist.

Expression of retinoic acid 4-hydroxylase (CYP26) during mouse and Xenopus laevis embryogenesis.

Retinoids are important signal molecules during vertebrate embryonic development and their synthesis as well as catabolism should therefore be strictly regulated. The retinoic acid (RA) 4-hydroxylase, belonging to the cytochrome P450 family CYP26, is an enzyme catalyzing the 4-hydroxylation of RA, thereby regulating RA homeostasis. Here we describe the temporal and spatial expression patterns of mouse (mCYP26) and Xenopus laevis (xCYP26) homologues. In mouse, expression is detected in uterine crypt, around differentiating cartilage, several regions of the head, regions of the pharynx, the neural retina, and several regions of the trunk. In Xenopus, Northern blot analysis shows presence of xCYP26 transcripts before the MBT and an increased expression level during gastrulation. Whole-mount in situ hybridization shows a specific expression pattern arising at onset of gastrulation, with a ring around the blastopore. By mid gastrulation there is an anterior and a posterior expression domain, each of which gets more complex later in development. There are some important similarities and differences in expression pattern between Xenopus and mouse.

Autoinduction of Retinoic Acid Metabolism to Polar Derivatives with Decreased Biological Activity in Retinoic Acid-sensitive, but Not in Retinoic Acid-resistant Human Breast Cancer Cells

Previous studies have shown that all-trans-retinoic acid (RA) inhibits in vitroproliferation of hormone-dependent human breast cancer cells but not the growth of hormone-independent cells. Here we report on RA metabolism in breast cancer cells as examined by high performance liquid chromatography analysis and found a correlation with sensitivity to growth inhibition by RA. RA-sensitive T-47D and MCF-7 cells exhibited high rate metabolism to polar metabolites, whereas RA-resistant MDA-MB-231 and MDA-MB-468 cells metabolized RA to a much lesser extent, and almost no polar metabolites could be detected. The high metabolic rate in RA-sensitive cells appears to be the result of autoinduction of RA metabolism, whereas RA-resistant cells showed no such induction of metabolism. We observed furthermore that transfection with retinoic acid receptor-α expression vectors in RA-resistant MDA-MB-231 cells resulted in increased RA metabolism and inhibition of cell proliferation. Metabolism of RA, however, seems not to be required to confer growth inhibition of human breast cancer cells. The biological activity of the polar metabolites formed in RA-sensitive cells was found to be equal or lower than that of RA, indicating that RA itself is the most active retinoid in these cells. Together our data suggest that RA-sensitive cells contain mechanisms to activate strongly the catabolism of RA probably to protect them from the continuous exposure to this active retinoid.

Detection of anabolic androgenic steroid abuse in doping control using mammalian reporter gene bioassays

Anabolic androgenic steroids (AAS) are a class of steroid hormones related to the male hormone testosterone. They are frequently detected as drugs in sport doping control. Being similar to or derived from natural male hormones, AAS share the activation of the androgen receptor (AR) as common mechanism of action. The mammalian androgen responsive reporter gene assay (AR CALUX bioassay), measuring compounds interacting with the AR can be used for the analysis of AAS without the necessity of knowing their chemical structure beforehand, whereas current chemical-analytical approaches may have difficulty in detecting compounds with unknown structures, such as designer steroids. This study demonstrated that AAS prohibited in sports and potential designer AAS can be detected with this AR reporter gene assay, but that also additional steroid activities of AAS could be found using additional mammalian bioassays for other types of steroid hormones. Mixtures of AAS were found to behave additively in the AR reporter gene assay showing that it is possible to use this method for complex mixtures as are found in doping control samples, including mixtures that are a result of multi drug use. To test if mammalian reporter gene assays could be used for the detection of AAS in urine samples, background steroidal activities were measured. AAS-spiked urine samples, mimicking doping positive samples, showed significantly higher androgenic activities than unspiked samples. GC-MS analysis of endogenous androgens and AR reporter gene assay analysis of urine samples showed how a combined chemical-analytical and bioassay approach can be used to identify samples containing AAS. The results indicate that the AR reporter gene assay, in addition to chemical-analytical methods, can be a valuable tool for the analysis of AAS for doping control purposes.

Validation of in vitro screening models for progestagenic activities: Inter-assay comparison and correlation with in vivo activity in rabbits

The PR CALUX® cell line is a stably transfected human U2-OS cell line expressing the human PR and a luciferase reporter construct containing three progesterone-responsive elements coupled to a minimal promoter. The validity of this assay has been studied as an alternative to the McPhail assay in rabbits, an in vivo assay to detect progestins. The PR CALUX assay was characterized by its stable expression of PR protein which leads to induction of endogenous PR target genes by progestins. It was found to have a highly selective response to low levels of different progestins, as well as an insignificant response to other nuclear hormone receptor ligands. As an important step in their validation, the PR CALUX bioassay was compared with another earlier described in vitro bioassay, a Chinese Hamster Ovary (CHO) cell-based PR-CHO reporter gene assay as well as with an in vitro PR-binding (PR-BIN) assay, and the in vivo McPhail assay. This was done using 35 (with the most accurate potency determinations in all tests) and 50 (with less reliable potency determinations in some tests) compounds tested in all assays. The correlation scores between PR CALUX and PR-CHO were r(2)=0.77, and 0.93, respectively; between PR CALUX and PR-BIN r(2)=0.69 and 0.80. Comparison between either the PR CALUX or the PR-CHO transactivation assay and the in vivo McPhail assay revealed very good correlations of r(2)=0.68 (n=35), and 0.85 (n=50). The transactivation assays can discriminate very potent, from potent, weak and inactive compounds rather easily. Besides testing the biological activity of pure chemicals and pharmaceuticals in vitro, the PR CALUX and PR-CHO transactivation assays proved to be relatively good predictors of in vivo progestagenic activity, allowing the use of these assays as prescreening methods or in vitro alternatives.

Selectivity and potency of the retroprogesterone dydrogesterone in vitro

Dydrogesterone is widely used for menstrual disorders, endometriosis, threatened and habitual abortion and postmenopausal hormone replacement therapy. Although progestins have a promiscuous nature, dydrogesterone does not have clinically relevant androgenic, estrogenic, glucocorticoid or mineralocorticoid activities. To date, systematic biochemical characterization of this progestin and its active main metabolite, 20α-dihydrodydrogesterone, has not been performed in comparison to progesterone. The objective of this study was to evaluate the selectivity and potential androgenic/antiandrogenic effects of dydrogesterone and its metabolite in comparison to progesterone and medroxyprogesterone acetate by analyzing their interference with AR signaling in vitro. We characterized dydrogesterone and its metabolite for their binding and transactivation of androgen and other steroid hormone receptors and for their potential inhibitory effects against androgen biosynthetic enzymes, 17β-hydroxysteroid dehydrogenase types 3 and 5 and 5α-reductase types 1 and 2. We found that dydrogesterone resembled progesterone mainly in its progestogenic effects and less in its androgenic, anti-androgenic, glucocorticoid and antiglucocorticoid effects; whereas, 20α-dihydrodydrogesterone showed reduced progestogenic potency with no androgenic, glucocorticoid and mineralocorticoid effects. Effects on the androgen and glucocorticoid receptor differed depending on the technology used to investigate transactivation. Progesterone, but not dydrogesterone and 20α-dihydrodydrogesterone, exerted anti-androgenic effects at the pre-receptor level by inhibiting 5α-reductase type 2. Dydrogesterone, 20α-dihydrodydrogesterone and progesterone inhibited the biosynthesis of testosterone catalyzed by 17β-hydroxysteroid dehydrogenase types 3 and 5; however, due to their micromolar K(i) values, these activities appeared to be not of relevance at therapeutic levels. Overall, our data show that the anti-androgenic potential of dydrogesterone and 20α-dihydrodydrogesterone is less pronounced compared to progesterone.

Prolonged progestin treatment induces the promoter of CDK inhibitor p21Cip1,Waf1 through activation of p53 in human breast and endometrial tumor cells

Progestins are frequently used in the treatment of advanced breast and endometrial cancer. The human breast carcinoma cell line T47D shows a biphasic response to progestins. Short-term progestin treatment leads to enhanced DNA synthesis, while this line is growth inhibited upon prolonged exposure. An important protein involved in growth regulation by progestins in this cell is the CDK inhibitor p21(Cip1,Waf1). We show that after 1 day of progestin treatment in T47D cells, the p21 promoter-proximal region containing Sp1 binding sites is crucial in the induction by progestins. However, after 3 days the activity of the promoter-distal region becomes predominant in T47D cells or the endometrial carcinoma cell line ECC1. This is dependent upon two domains within this region that contain p53 response elements. In ECC1 and T47D cells 3-day progestin treatment induces a reporter containing a p53 response element, but not a mutated version. This induction is due to activation of p53 by progestin, which may be caused by nuclear translocation of p53. These data indicate that upon prolonged exposure, progestins activate p53, in human breast and endometrial tumor cells, which up-regulates the p21(Cip1,Waf1) promoter. This may be an important mechanism involved in progestin-inhibited cellular proliferation in these cells.