Exposure to environmental endocrine disruptors may interfere with nervous system’s activity. Fungicides such as tebuconazole, triadimefon, and vinclozolin have antifungal activities and are used to prevent fungal infections in agricultural plants. In the present study, we studied effects of tebuconazole, triadimefon, and vinclozolin on rat’s neurosteroidogenic 5α-reductase 1 (5α-Red1), 3α-hydroxysteroid dehydrogenase (3α-HSD), and retinol dehydrogenase 2 (RDH2). Rat’s 5α-Red1, 3α-HSD, and RDH2 were cloned and expressed in COS-1 cells, and effects of these fungicides on them were measured. Tebuconazole and triadimefon competitively inhibited 5α-Red1, with IC50 values of 8.670 ± 0.771 × 10−6 M and 17.390 ± 0.079 × 10−6 M, respectively, while vinclozolin did not inhibit the enzyme at 100 × 10−6 M. Triadimefon competitively inhibited 3α-HSD, with IC50 value of 26.493 ± 0.076 × 10−6 M. Tebuconazole and vinclozolin weakly inhibited 3α-HSD, with IC50 values about 100 × 10−6 M, while vinclozolin did not inhibit the enzyme even at 100 × 10−6 M. Tebuconazole and triadimefon weakly inhibited RDH2 with IC50 values over 100 × 10−6 M and vinclozolin did not inhibit this enzyme at 100 × 10−6 M. Docking study showed that tebuconazole, triadimefon, and vinclozolin bound to the steroid-binding pocket of 3α-HSD. In conclusion, triadimefon potently inhibited rat’s neurosteroidogenic enzymes, 5α-Red1 and 3α-HSD.
Health & Family Planning Commission of Zhejiang Province11-CX292014C370172017KY4661. Introduction
Exposure to environmental endocrine disruptors may interfere with nervous system’s activity. Fungicides such as tebuconazole (TEB) [1], triadimefon (TRI) [2], and vinclozolin (VCZ) [3] have a wide range of antifungal activities and are used to prevent fungal infections for agricultural plants. Therefore, exposure to these chemicals is very common. These fungicides contain at least one triazole or imidazole moiety in the chemical structure (Scheme 1). It is believed that these fungicides block the synthesis of fungus steroid, ergosterol. Ergosterol is a membrane component, and, therefore, these chemicals can disrupt cell membrane assembly of fungi to kill the fungi [4].
The chemical structure of fungicides.
These fungicides may interfere with the steroid biosynthesis in mammals. For example, azole fungicides reduce the estrogen production via blocking aromatase [5, 6]. Neurosteroids are another set of steroids which have neurological activity [7]. These neurosteroids include allopregnanolone (ALLO) and 5α-androstane-3α, 17β-diol (DIOL) [7]. Although the classic steroids such as progesterone, estrogen, and testosterone act via binding to their respective nuclear receptors (progesterone, estrogen, and androgen receptors), neurosteroids allosterically activate the membrane GABA-A receptors and potentiate the central inhibition, causing anxiolytic, anticonvulsant, analgesic, and sedative effects [7, 8]. GABA-A receptors are widely present in the nervous system to exert inhibitory action on nerve activity [7].
ALLO and DIOL biosynthesis requires brain 5α-reductase 1 (5α-Red1) and 3α-hydroxysteroid dehydrogenase (3α-HSD). 5α-Red1 is a smooth endoplasmic reticulum NADPH-dependent enzyme [9], catalyzing progesterone or testosterone into dihydroprogesterone and dihydrotestosterone, respectively [10] (Scheme 2). 3α-HSD, a cytosolic enzyme, catalyzes these two steroids into ALLO or DIOL, respectively [11]. In rat’s brain, microsomal NAD+-dependent retinol dehydrogenase 2 (RDH2) catalyzes the reverse reaction of ALLO or DIOL back to dihydroprogesterone and dihydrotestosterone, thus controlling the levels of these neurosteroids [12] (Scheme 2). Therefore, in the present study, we examined their direct effects on these neurosteroidogenic enzymes and their differential sensitivity.
The biosynthesis and metabolism of neurosteroids, allopregnanolone and androstanediol, by three distinct enzymes: NADPH-dependent 5α-reductase 1 (SRD5A1), NADPH-dependent cytosolic 3α-hydroxysteroid dehydrogenase (AKR1C14), and NAD+- dependent microsomal retinol dehydrogenase 2 (RDH2).
2. Experimental Procedures2.1. Chemicals
[3H]Testosterone, [3H] dihydrotestosterone, and [3H] DIOL were obtained from DuPont-New England Nuclear (Boston, MA). Testosterone, dihydrotestosterone, and DIOL were purchased from Steraloids (Newport, RI). TEB, TRI, and VCZ were purchased from Sigma-Aldrich (St. Louis, MO). TEB, TRI, and VCZ were dissolved in DMSO, which is used as a vehicle. Rat 3α-HSD gene Akr1c14 in the expression vector pRc/CMV was a gift from Penning T. M. (University of Pennsylvania, Philadelphia, Pennsylvania). Rat’s 5α-Red1 gene Srd5a1 and RDH2 gene Rdh2 in the expression vector pcDNA1.1 were constructed previously [13]. COS-1 cell line was purchased from ATCC (Manassas, VA).
2.2. Transient Transfection
COS-1 cells were maintained in DMEM medium (Life Technologies, Inc., Gaithersburg, MD) supplemented with 10% fetal calf serum and 5% CO2 at 37°C. For transfection, 1 × 106 cells were seeded per well in a six-well plate and cultured for 24 h in media supplemented with charcoal-stripped fetal calf serum to obtain 50–80% confluence. Transfection was performed by the FuGENE 6 Transfection Reagent (Roche Molecular Biochemicals, Indianapolis, IN) according to the manufacturer’s protocol. 1 µg DNA per well showed maximal efficiency and, therefore, this quantity was used in the transfection assays.
2.3. Preparation of 5α-Red1, 3α-HSD, and RDH2 Proteins
Twenty-four hours after transfection, the COS-1 cells were scraped from dishes and were homogenized in 10 ml 0.01 mM phosphate-buffered saline containing (0.25 M) sucrose and nuclei and large cell debris were removed by centrifugation at 1500 ×g for 10 min. Microsomal and cytosolic fractions were harvested after subsequent centrifugation at 10,000 ×g for 1 h and at 105,000 ×g for 1 h twice. The protein concentrations in cell lysates and subcellular fractions were measured using a kit (number 500-0006, Bio-Rad Laboratories, Inc., Hercules, CA) with bovine serum albumin as a standard. The concentrations of rat’s 5α-Red1, 3α-HSD, and RDH2 proteins were 20 mg/ml. The proteins were used for the measurement of 5α-Red1, 3α-HSD, and RDH2 activities.
2.4. Measurement of 5α-Red1, 3α-HSD, and RDH2 Activities
5α-Red1 activity was measured by incubating 1000 nM testosterone spiked with 60,000 dpm of [3H] testosterone as the substrate, 10 μg SRD5A1-containing microsomal protein, and 0.2 mM NADPH in 250 µl PBS (pH = 7.2). 3α-HSD activity was measured by incubating 1000 nM dihydrotestosterone spiked with 60,000 dpm of [3H]-dihydrotestosterone as the substrate, 10 μg 3α-HSD-containing cytosolic protein, and 0.2 mM NADPH in 250 µl PBS (pH = 7.2). RDH2 activity was measured by incubating 1000 nM DIOL spiked with 630,000 dpm of [3H] DIOL as the substrate, 10 μg RDH2-containing microsomal protein, and 0.2 mM NAD+ in 250 µl PBS (pH = 7.2). 100 µM fungicides were incubated in the respective reaction mixture at 37°C for 60 min for the initial inhibition test. The inhibitory potency of fungicides was measured relative to the control (only DMSO). Each fungicide was dissolved in DMSO and an aliquot (1 µl) of each fungicide was added to the reaction mixture at a final concentration of 0.4%, at which concentration DMSO did not inhibit 5α-Red1, 3α-HSD, or RDH2 activities. The reaction was stopped with 1 ml ice-cold ether. The steroids were extracted with ether after vigorous vortexing. The organic ether layer was transferred to the new glass tube and dried under nitrogen. The steroids were separated chromatographically on the thin layer plate in chloroform and methanol (90 : 3, v/v), and the radioactivity was measured using a scanning radiometer (System AR2000, Bioscan Inc., Washington, DC) as previously described [14]. The percentage conversion of testosterone into dihydrotestosterone (for 5α-Red1), dihydrotestosterone into DIOL (for 3α-HSD), and DIOL into dihydrotestosterone (for RDH2) was calculated by dividing the radioactive counts identified as the respective steroids by the total counts of control DMSO.
2.5. Determination of Enzyme Kinetics
The enzyme kinetics was determined by adding 0.0315–10 µM testosterone or dihydrotestosterone or DIOL for 5α-Red1, 3α-HSD, and RDH2. The Michaelis–Menten equation was used by GraphPad (Version 6, GraphPad Software Inc., San Diego, CA) to calculate the apparent Michaelis–Menten constant (Km) and the apparent maximum velocity (Vmax). The initial velocity (Vo) depends on the apparent Km, Vmax, and the substrate concentration ([S]) as Vo=Vmax[S]/(Km+[S]).
2.6. Determination of IC50 Values and Inhibitory Modes
The half maximum inhibitory concentration (IC50) of TEB or TRI to inhibit 5α-Red1 was determined by adding 1000 nM of testosterone with 0.2 mM NADPH and 10−8–10−4 M TEB or TRI in 250 μl phosphate-buffered saline (0.1 mM) containing 5α-Red1 protein and incubating each reaction mixture for 60 min. The IC50 value of TRI to inhibit 3α-HSD was determined by adding 1000 nM of dihydrotestosterone with 0.2 mM NADPH and 10−8–10−4 M TRI in 250 μl phosphate-buffered saline (0.1 mM) containing 3α-HSD protein and incubating each reaction mixture for 60 min. For determining the mode of inhibition of 5α-Red1, 10−9–10−5 M testosterone was added to the reaction mixture in the presence of TEB (10 and 20 µM) or TRI (20 and 40 µM) for 5α-Red1. For determining the mode of inhibition of 3α-HSD, 10−9–10−5 M dihydrotestosterone was added to the reaction mixture in the presence of TRI (25 and 50 µM) for 3α-HSD.
2.7. Preparation of Protein and Ligand Structures and Docking
The crystal structure of rat’s 3α-HSD containing NADP+ and testosterone (PDB id 1afs [15]) was used as a docking target for steroid substrate DIOL, TEB, TRI, and VCZ. These chemical structures were obtained from PubChem (https://pubchem.ncbi.nlm.nih.gov) as ligands. Docking calculations were performed with SwissDock, a docking algorithm based on the docking software EADock DSS [16]. The docked file was visualized using the program Chimera 1.1.1 (San Francisco, CA) and the free energy was calculated.
2.8. Statistics
Each experiment was repeated four times. Data were subjected to a nonlinear regression analysis by GraphPad (Version 6, GraphPad Software Inc., San Diego, CA) for IC50 values. Lineweaver–Burk plot was used for the mode of inhibition. Data were subjected to an analysis by ANOVA followed by ad hoc Tukey’s comparison to identify significant differences between the control (CON) and TEB, TRI, or VCZ group. All data are expressed as means ± SEM. The difference was regarded as significant at P<0.05.
3. Results3.1. Effects of Fungicides on 5α-Red1
The conversion of testosterone into DHT is catalyzed by 5α-Red1, which requires NADPH as a cofactor; the apparent Km and apparent Vmax of 5α-Red1 were 1.397 ± 0.35 μM (mean ± SE, n=4) and 3.494 ± 0.287 pmol dihydrotestosterone/mg protein/min (mean ± SE, n=4), respectively (Table 1 and Figure 1(a)). As presented in Figure 1(b), when the highest concentration (100 μM) was tested, TEB and TRI inhibited rat’s 5α-Red1 to 26.94 ± 5.30% and 19.31 ± 3.6% of the control value, respectively, but VCZ only to 74.17 ± 5.57% of the control value. We further calculated the IC50 values of TEB (Figure 1(c)) and TRI (Figure 1(d)), which were 8.670 ± 0.771 and 17.390 ± 0.079 μM, respectively (Table 1). The modes of inhibition of TEB and TRI on 5α-Red1 were found to be competitive against testosterone (Figures 2(a) and 2(b)).
The enzyme kinetic parameters and the half maximal inhibitory concentration (IC50) of fungicides.
Parameters
5α-Red1
3α-HSD
RDH2
Apparent Km (µM)
1.397±0.35
3.148±0.197
2.850±0.037
Apparent Vmax (pmol/mg⋅min)
3.494±0.287
66.69±1.589
529.5±2.612
IC50 (µM)
Tebuconazole
8.670±0.771
~100
>100
Triadimefon
17.39±0.079
26.493±0.076
>100
Vinclozolin
NI
~100
NI
Mean ± SE, n=4. NI: no inhibition at 100 µM.
Kinetics of SRD5A1 and the inhibition of fungicides. Panel (a): kinetics of SRD5A1 with testosterone (T) as the substrate. Panel (b): % inhibition by tebuconazole (TEB), triadimefon (TRI), and vinclozolin (VCZ) at 100 µM. Panels (c) and (d): IC50 values of TEB and TRI. Mean ± SEM; ∗∗∗ indicates a significant difference compared to the control (CON) at P<0.001.
5α-Red1
5α-Red1
5α-Red1:TEB
5α-Red1:TRI
The inhibitory mode of tebuconazole (TEB) and triadimefon (TRI) on rat’s SRD5A1. Lineweaver–Burk plots in presence of testosterone and TEB (Panel (a)) as well as testosterone and TRI (Panel (b)). Values were obtained from four samples.
TEB versus T
TRI versus T
3.2. Effects of Fungicides on 3α-HSD Activity
The conversion of dihydrotestosterone into DIOL is catalyzed by 3α-HSD, which requires NADPH as a cofactor; the apparent Km and apparent Vmax of 3α-HSD were 3.148 ± 0.197 μM (mean ± SE, n=4) and 66.69 ± 1.587 pmol DIOL/mg protein/min (mean ± SE, n=4), respectively (Table 1 and Figure 3(a)). TRI inhibited rat’s 3α-HSD to 32.95 ± 4.80% of the control value, while TEB and VCZ caused about 52.78 ± 8.278% and 52.65 ± 6.70% of the control value, respectively (Figure 3(b)). We further calculated the IC50 value of TRI, which was 26.493 ± 0.076 µM (Table 1 and Figure 3(c)). The mode of inhibition of TRI on 3α-HSD was found to be competitive against dihydrotestosterone (Figure 3(d)).
The kinetics of AKR1C14 and the inhibition of fungicides. Panel (a): kinetics of AKR1C14 with dihydrotestosterone (DHT) as the substrate. Panel (b): % inhibition by tebuconazole (TEB), triadimefon (TRI), and vinclozolin (VCZ) at 100 µM. Panel (c): IC50 value of TRI. Panel (d): the mode of inhibition of TRI versus DHT. Mean ± SEM; ∗∗∗ indicates a significant difference compared to the control (CON) at P<0.001.
3α-HSD
3α-HSD
3α-HSD:TRI
TRI versus DHT
3.3. Effects of Fungicides on RDH2 Activity
The conversion of DIOL into dihydrotestosterone is catalyzed by RDH2, which requires NAD+ as a cofactor; the apparent Km and apparent Vmax of RDH2 were 2.850 ± 0.037 μM (mean ± SE, n=4) and 529.5 ± 2.612 pmol dihydrotestosterone/mg protein/min (mean ± SE, n=4), respectively (Table 1 and Figure 4(a)). TRI and TEB only inhibited RDH2 to 65.79 ± 1.69% and 53.35 ± 5.03% of the control value, while VCZ did not inhibit the enzyme activity (85.51 ± 2.20% of the control value, Figure 4(b)).
The kinetics of RDH2 and the inhibition of fungicides. Panel (a): kinetics of RDH2 with androstanediol (DIOL) as the substrate. Panel (b): % inhibition by tebuconazole (TEB), triadimefon (TRI), and vinclozolin (VCZ) at 100 µM. Mean ± SEM; ∗∗∗ indicates a significant difference compared to the control at P<0.001.
RDH2
RDH2
3.4. Docking of Fungicides to 3α-HSD
Because among three enzymes only the crystal structure of rat’s 3α-HSD is available, we docked DIOL to 3α-HSD first. DIOL was found to bind to the dihydrotestosterone-binding pocket, with free energy of −7.73 Kcal. Further docking analysis for TEB (Figure 5(a)), TRI (Figure 5(b)), and VCZ (Figure 5(c)) showed that all these three chemicals bound to the steroid-binding pocket, with free energies of 7.28, −7.63, and −7.34. These data indicate that TRI has the highest binding affinity with 3α-HSD. TRI interacts with Try310, Trp227, His117, Tyr55, Leu54, Thr24, and Asn306 residues of 3α-HSD (Figure 6). The Tyr310 and Trp227 residues were believed to hold the steroid structure, and His117 and Tyr55 residues were believed to catalyze the 3α-position of the steroid [15].
Docking analysis for the binding to rat’s AKR1C14 (1AFS). Panel (a): tebuconazole; blue structure, NADPH; red structure, testosterone; sky-blue structure, tebuconazole. Panel (b): triadimefon; blue structure, NADPH; green structure, dihydrotestosterone; sky-blue structure, triadimefon. Panel (c): vinclozolin; blue structure, NADPH; red structure, testosterone; sky-blue structure, vinclozolin.
Docking analysis for the binding of triadimefon to rat’s AKR1C14 (1AFS). The residues of AKR1C14 interacting with triadimefon were listed.
4. Discussion
In the brain, the neurosteroidogenic enzymes 5α-Red1 [17], 3α-HSD [11, 17], and RDH2 [12] are involved in the biosynthesis and metabolism of neurosteroids. 5α-Red1 and 3α-HSD are responsible for the neurosteroid biosynthesis to form 3α-reduced neurosteroids, while RDH2 is responsible for the neurosteroid metabolism to remove the 3α-reduced neurosteroids. These neurosteroidogenic enzymes showed different sensitivity to some fungicides. Here, we demonstrated that TEB and TRI potently inhibited 5α-Red1, the irreversible step of neurosteroid biosynthesis. Furthermore, TRI also potently inhibited 3α-HSD, thus leading to the reduced level of neurosteroids. VCZ was the weakest fungicide to inhibit 5α-Red1 and 3α-HSD.
Interestingly, the enzyme 5α-Red1 is the most sensitive to the inhibition by TEB compared to 3α-HSD and RDH2. The IC50 values of TEB for 5α-Red1, 3α-HSD, and RDH2 were 8.67, ~100, and ~100 µM. 5α-Red1 and 3α-HSD share equal sensitivity to the inhibition by TRI compared to RDH2. The IC50 values of TRI for 5α-Red1, 3α-HSD, and RDH2 were 17.39, 26.49, and ~100 µM. The reason for this difference is still unclear. This is possibly due to the difference of these enzyme structures. 5α-Red1 is the rate-limiting irreversible step for the formation of many neurosteroids. Animal study suggests subsequent 3α-reduction of dihydroprogesterone and dihydrotestosterone by 3α-HSD into steroid metabolites which have neuroactive function via enhancing GABA suppression. These neuroactive steroids promote GABA effects by allosteric modulation at GABA-A receptors, thus exerting anticonvulsant, antidepressant, and anxiolytic effects [18]. In socially isolated mice, 5α-Red1 is downregulated in glutamatergic pyramidal neurons that converge on the amygdala from cortical and hippocampal regions possibly causing anxiety, aggression, and cognitive dysfunction [19, 20].
VCZ was the weakest inhibitor for 5α-Red1 and 3α-HSD, with IC50 about 100 µM. However, VCZ almost did not inhibit RDH2 when 100 µM was used. The reason why the potency of VCZ is different from those of TEB and TRI is unclear. This is possibly due to the different chemical structures, in which TEB and TRI contain one triazole and VCZ contains one imidazole in the chemical structure.
TEB and TRI competitively inhibited 5α-Red1 when testosterone was provided. TEB and TRI also competitively inhibited 3α-HSD. Docking study further confirmed that these three chemicals bound to the steroid-binding pocket of 3α-HSD. TRI interacts with Try310, Trp227, His117, Tyr55, Leu54, Thr24, and Asn306 residues in the steroid-binding pocket of 3α-HSD. The Tyr310 and Trp227 residues were believed to maintain stability of the steroid, and His117 and Tyr55 residues of 3α-HSD were believed to catalyze the 3α-position of the steroid [15]. The free energy calculation further showed the lowest binding energy for TRI, which was comparable to DIOL, indicating that TRI has high affinity for 3α-HSD.
The homeostasis of neurosteroids including ALLO and DIOL depends on the catalysis of their biosynthetic enzymes, 5α-Red1 and 3α-HSD, as well as the metabolizing enzyme RDH2. Since 5α-Red1 is the rate-limiting step for neurosteroid formation, this inhibition by TEB and TRI is critical for the production of neurosteroids. Indeed, evidence shows that these fungicides can affect brain function. Rats after exposure to triadimefon developed a deficit in spatial learning and reference memory [21]. Rats after perinatal exposure to tebuconazole produced neurobehavioral deficits and neuropathology [22]. Triadimefon also disrupted the transporter of extracellular dopamine, dihydroxyphenylacetic acid, homovanillic acid, and 5-hydroxyindoleacetic acid in adult rat’s striatum [23]. Goldfish after acute and chronic exposure to VCZ developed dysfunction of neuroendocrine regulation of reproduction [24]. Therefore, the disruption of neurosteroid biosynthesis by these fungicides could lead to neurological dysfunction.
In conclusion, TEB and TRI are inhibitors of 5α-Red1 and 3α-HSD. TEB inhibited 5α-Red1 activity more potently than the activities of 3α-HSD and RDH2. Their negative effects on the neurosteroid accumulation were worthy of further research.
Abbreviations3α-HSD:
3α-Hydroxysteroid dehydrogenase
ALLO:
Allopregnanolone
DHT:
Dihydrotestosterone
DIOL:
Androstanediol
IC50:
Half maximum inhibitory concentrations
RDH2:
Retinol dehydrogenase 2
5α-Red1:
5α-Reductase 1
TEB:
Tebuconazole
T:
Testosterone
TRI:
Triadimefon
VCZ:
Vinclozolin.
Disclosure
Ping Huang is a co-corresponding author.
Conflicts of Interest
The authors report no conflicts of interest.
Authors’ Contributions
Xiuwei Shen and Fan Chen equally contributed to this work.
Acknowledgments
The authors thank T. M. Penning (University of Pennsylvania, Philadelphia, Pennsylvania 19104, USA) for 3α-HSD vector. This research was supported by Health & Family Planning Commission of Zhejiang Province (11-CX29, 2014C37017, and 2017KY466).
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