Key words silybin -
Silybum marianum
- CYP2B6 - inhibition - Liver microsomes - Interaction
Introduction
Silybin is a primary component of the silymarin complex extracted from the milk thistle
(Silybum marianum [L.] Gaertn. [Asteraceae]) [1 ], a commonly used
herb to treat a range of liver diseases, including hepatitis and cirrhosis, and to
protect the liver against poisoning from chemical and environmental toxins [2 ].
The structure is shown in [Fig. 1 ]. Silybin has recently received attention because of its other beneficial activities,
such as anticancer, hypocholesterolemic,
and neuroprotective properties [3 ], [4 ]. Silybin has been widely used in clinical settings in combination with a variety
of other drugs
that are the substrates of human cytochrome P450 enzymes. It has been reported that
silybin can inhibit the transcription factor NF-κ B, which regulates and coordinates the expression of
numerous genes involved in the drug metabolism enzymes and transporters. According
to research, silybin had little effect on CYP3A4 in vitro and inhibited the drug transporters
P-glycoprotein and breast cancer resistance protein [5 ], [6 ], [7 ]. CYP2B6, a human cytochrome P450 enzyme
with broad substrate specificity, is primarily expressed in the liver and is involved
in xenobiotic metabolism. According to current reports, CYP2B6 accounts for 2%~10%
of total hepatic CYP
content and is involved in the metabolism of a significant number of drugs, accounting
for approximately 8% of all commercially available drugs [8 ]. The discovery
of multiple important CYP2B6 substrates has increased interest in the xenobiotic factor
that contributes to the expression and function of the enzyme. The substrates of CYP2B6
include several
clinically utilized, such as central-nervous-system-acting drugs (bupropion, methadone,
and mephenytoin), anticancer agents (cyclophosphamide and ifosfamide), and antiretroviral
drugs
(efavirenz) [9 ].
Fig. 1 The chemical structure of silybin.
Silybin is used to treat chronic hepatitis as a component of traditional Chinese medicine
and is often used in combination with other modern medicine in medical therapy [10 ]. Drug interactions can result from variations in CYP2B6 activity that impact the
plasma level of its substrates. The inactivation of human CYPs may result in
clinically significant drug–drug interactions. Currently, the inhibition potency of
silybin on CYP2B6 and related molecular mechanisms has not been reported. Deciphering
the inhibitory
mechanism and testing the potential inhibition of silybin against CYP2B6 are therefore
essential.
We chose bupropion, a CYP2B6-sensitive probe substrate [11 ], to examine the CYP2B6 activity in vitro . The objective of this study was to determine how much
silybin inhibits CYP2B6 activity and protein expression in an in vitro study. For these purposes, a series of enzyme kinetic tests were carried out in human/rat
liver microsomes to
determine the inhibition assay of silybin against the CYP2B6 enzyme. A molecular docking
study was carried out to investigate the binding site of silybin on the CYP2B6 isoform
further. The
effect of silybin on CYP2B6 mRNA and protein expression in HepaRG cells was investigated
using RT-qPCR and Western blot analysis. We investigated the effect of silybin on
CYP2B6 enzyme
activity and expression, as well as the inhibitory type and potential mechanism of
silybin on the CYP2B6 enzyme. All the findings presented in this paper are critical
for understanding the
interactions between silybin and CYP2B6 substrates, which will be useful in clinical
applications of silybin.
Results and Discussion
The inhibitory effect of silybin on the activities of CYP2B6 in HLMs and CYP2B1 in
RLMs was shown in [Fig. 2 ]. The inhibition degree of positive control,
ticlopidine (10 µM), was 97.7% in HLMs and 90.9% in RLMs compared with the control
group. In HLMs, the activity of the enzyme compared with the control was 36.6%, 46.6%,
50.4%, and 56.6% when
the concentration of silybin was 100 µM, 20 µM, 10 µM, and 1 µM, respectively, and
in RLMs, the activity was 15.5%, 44.6%, 59.5%, and 86.6%, respectively, at the same
concentration of silybin
compared with the control group.
Fig. 2 The inhibitory effect of silybin on enzyme activity. Metabolites were generated by
60 min incubation of 100 µM bupropion with 0.25 mg/mL HLMs, 0.5 mg/mL RLMs. HLMs:
human
liver microsomes; RLMs: rat liver microsomes. T: ticlopidine. Error bars represent
the mean ± SD, n = 3 (*: p < 0.05; ***: p < 0.001 compared with the control group)
The relationship between bupropion concentration and the rate (V) of hydroxy-bupropion
(HBUP) formation incubated with HLMs and RLMs are shown in [Fig. 3 a, b. ]
The same data are presented as the Lineweaver–Burk plot in [Fig. 3 c, d ]. The parameters of enzyme kinetics are summarized in [Table
1 ]. The Vmax in HLMs was 3.339 nmol/h/mg protein (control group) and 1.293 nmol/h/mg protein (silybin
group) with respective 95% confidence intervals of 3.061 to
3.688 nmol/h/mg protein and 1.062 to 1.7 nmol/h/mg protein. Compared with the control
group, the value of Km was significantly increased (122.7 µM vs. 329.9 µM) in HLMs
(p < 0.01). Incubated with RLMs, the value of Vmax was significantly decreased (0.3217 nmol/h/mg
protein vs. 0.072 nmol/h/mg protein) (p < 0.01). There was no significant difference
in
the value of Km observed in RLMs. Lineweaver–Burk plots ([Fig. 3 c, d ]) showed that the inhibition type of silybin on CYP2B6 was a noncompetitive
inhibition model, and the type of CYP2B1 was mixed.
Fig. 3 The curve of Michaelis–Menten (a, b ) and the Lineweaver–Burk plots (c, d ) of the effect of silybin on CYP2B6 in HLMs (a, c ) and CYP2B1 in RLMs (b,
d ). Data are obtained from 60 min incubation with bupropion (5 – 300 µM) in the absence
or presence of silybin (20 µM). Error bars represent the mean ± SD, n = 3.
Table 1 The enzyme kinetics parameters.
Control
Silybin
Parameters
Vmax (nmol/h/mg protein)
Km (µM)
Vmax (nmol/h/mg protein)
Km (µM)
a 95% confidence interval; ** P < 0.01 compared with the control group
HLM
3.339 (3.061 – 3.688)a
122.7 (98.15 – 155.3)
1.293** (1.062 – 1.7)
329.9** (232.7 – 505.4)
RLM
0.3217 (0.2988 – 0.3494)
84.42 (67.43 – 106.8)
0.072** (0.0645 – 0.0818)
67.49 (46.91 – 98.32)
The inhibitory effects of silybin against CYP2B6 in HLMs and CYP2B1 in RLMs were investigated
at different concentrations of silybin to explore the value of IC50 , as depicted in
[Fig. 4 ]. Silybin concentration-dependently inhibited the catalytic activities of CYP2B6
and CYP2B1 with IC50 values of 13.9 µM and 32.1 µM,
respectively. The Ki values for CYP2B6 and CYP2B1 were determined to be 38.4 µM and 58.4 µM, respectively.
Fig. 4 The inhibition curve of silybin on CYP2B6 (HLMs, a ) and CYP2B1 (RLMs, b ) and the Dixon plots for CYP2B6 (HLMs, c ), CYP2B1 (RLMs, d ). The activity
of CYP2B6 and CYP2B1 were tested using probe substrate in HLMs and RLMs. Error bars
represent the mean ± SD, n = 3.
To ascertain if silybinʼs inhibition of CYP2B6/CYP2B1 was time dependent and that
its action was NADPH dependent, an NADPH-dependent inhibition experiment was carried
out. The time-dependent
inhibition (TDI) refers to a change in CYP inhibitor potency that occurs during an
in vitro incubation. Experimentally, the inhibitory effects of various pathways could be compared
between those obtained in the presence and absence of NADPH during a preincubation
period [12 ]. As shown in [Fig. 5 ], compared with
the control group, the inhibitory effect of silybin on CYP2B6 was gradually enhanced
with the prolongation of co-incubation time ([Fig. 5 a ]), and there was no
difference between with the NADPH group and without the NADPH group (p > 0.05). This
finding demonstrated that TDI is mostly treated by its spontaneous oxidative products
and does not
require NADPH. The inhibitory effect of silybin on CYP2B1 was gradually increased
with increasing co-incubation time in the NADPH group ([Fig. 5 b ]), and there
were significant differences between with the NADPH group and without the NADHP group
(p < 0.05).
Fig. 5 NADPH-dependent inhibition of CYP2B6 by silybin (HLMs, a ) and CYP2B1 (RLMs, b ). Error bars represent the mean ± SD, n = 3.
Molecular docking analysis of the interaction between silybin and CYP2B6 was performed
to confirm the inhibitory mechanism at the molecular level. As shown in [Fig. 6 ], silybin could be tightly docked into the catalytic cavity of the CYP2B6 protein.
For identifying and quantifying activity pockets in the CYP2B6 protein structure,
the
DoGSiteScore server was used. The DoGSiteScore server is a grid-based function prediction
method to identify potential pockets on the protein surface. The binding energy of
the lowest energy
conformation was predicted as − 8.0 kcal/mol. In addition, the critical interaction
between silybin and CYP2B6 was also investigated. As depicted in [Fig. 6 ],
GLN-458 and THR-483 were involved in forming hydrogen bonds (the yellow lines on the
right of [Fig. 6 ]) with the CYP2B6 protein structure, which may include the
primary inhibitory mechanism of silybin.
Fig. 6 The binding pose of silybin in the active pocket of CYP2B6. Silybin is shown as blue
sticks, the heme of CYP2B6 show as green sticks, the substrate of CYP2B6 show as yellow
sticks in left (a ). The detailed part of the interaction is shown as the right side (b ).
The result of the MTT viability assay in the HepaRG cell is shown in [Fig. 7 ], and the IC50 value of silybin against HepaRG cells is 142.2 µM (Fig.
S2 , Supporting Information). The gene expression of CYP2B6 and the reference gene, GAPDH,
were determined by RT-qPCR; the results are shown in [Fig. 8 a, c ].
Compared with the control group, the expression of CYP2B6 mRNA was of no significant
difference in the low-dose group (p > 0.05). In contrast, CYP2B6 mRNA expression in
the medium (50 µM)
and high (100 µM) dose groups showed an apparent downward trend, with reductions of
47.6% and 56.5%, respectively (p < 0.05). HepaRG cells were treated with 100 µM silybin
at different
times, and there was a significant decrease after being treated 24 h (p < 0.05).
Fig. 7 The MTT curve of HepaRG cells.
Fig. 8 The effect of silybin on CYP2B6 mRNA and protein expression. The expression of CYP2B6
mRNA in HepaRG cells (a, c ); the expression of CYP2B6 protein expression in
HepaRG cells (b, d ); the protein blots of HepaRG cells treated with silybin (e ). The data are presented as a fold change in the silybin-treated group relative to
the control
group. Error bars represent the mean ± SD, n = 3.
Western blotting was performed to quantify CYP2B6 protein expression in the HepaRG
cells treated with silybin. CYP2B6 and the GAPDH protein were detected as a band of
about 60 kDa and 35 kDa
among the proteins extracted from the HepaRG cells. Each protein band was normalized
to the band of reference protein, GAPDH. The results are shown in [Fig. 8 b, d, e ]. The data showed that there was no significant difference in CYP2B6 protein expression
in HepaRG cells when treated with 10 µM silybin for 24 h; CYP2B6 protein
expression was significantly decreased while the concentration of silybin was 50 µM
and 100 µM (p < 0.05). In HepaRG cells treated with 100 µM silybin after 6, 12, and
24 h, CYP2B6 protein
expression all decreased significantly (p < 0.05).
There is growing evidence that CYP2B6 is more important to human drug metabolism.
Since silybin is frequently used to treat hepatic disease, it is important to be aware
of the possible risks
of drug–drug interactions. Inhibition of cytochrome P450 enzymes is a central mechanism,
resulting in clinically significant drug–drug interactions [13 ]. Silybin
could affect the activity or expression of drug-metabolizing enzymes that are responsible
for the elimination of co-administrated therapeutic agents. Unfortunately, little
research has been
done so far on how silybin and the CYP2B6 enzyme interact. Thus, in this study, we
used a combination of in vitro and molecular docking studies to examine the effect of silybin on the
CYP2B6 enzyme and the molecular mechanism.
In this study, we first demonstrated that silybin is an inhibitor of the CYP2B6 enzyme.
Rat CYP2B1 and human CYP2B6 share approximately 80% nucleotide sequence identity [14 ], and rats are often used as rodent species in an investigation of the metabolism
rates and routes. Silybin is the primary active constituent of silymarin, and it
has been used as a therapeutic agent in many liver diseases in clinical practice [15 ]. As silybin possesses numerous pharmacological activities, it is essential to
determine the effects of silybin on the CYP2B6 enzyme. In this study, silybin was
revealed to be a noncompetitive inhibitor of CYP2B6 with an IC50 value of 13.9 µM and a
Ki value of 38.4 µM. In addition, silybin was a mixed inhibitor of CYP2B1 in RLM with
an IC50 value of 32.1 µM and a Ki value of 58.4 µM. Based on these
results, silybin showed a more substantial inhibitory effect on CYP2B6 in HLM than
CYP2B1 in RLM. The reason for the difference between the two types of inhibition is
most likely due to
species differences; this hypothesis needs to be explored after perfecting the crystal
structure of the CYP2B1 protein in the future. To further understand the interaction
of silybin and
CYP2B6, molecular docking analysis was performed to confirm the drug binding conformation.
According to our molecular docking study, silybin, when it is co-administrated with
other substrates
of CYP2B6 enzyme, may decrease the activity of CYP2B6 enzyme by forming hydrogen bonds
with GLN-458 and THR-483, which could cause suppressing or reducing hepatic clearance
of substrates.
Our results of this study also indicate that silybin can down-regulate the expression
of the CYP2B6 enzyme in HepaRG cells. This down-regulation effect is reflected in
the mRNA and protein
levels of CYP2B6. HepaRG cells, a human-origin cell line, have been proven to be a
classical model to investigate the expression level of mRNA and protein of CYP450
enzyme in the human liver
[16 ]. Studies have shown that the pregnant X receptor (PXR) is one of the major transcriptional
regulators of CYP2B6 [8 ], and silybin
is a stronger inhibitor of PXR [17 ]. Thus, silybin may down-regulate CYP2B6 protein expression by inhibiting the PXR.
Regarding the substrates of CYP2B6, it should be noted that inhibition of the CYP2B6
enzyme is a double-edged sword, which may bring beneficial effects or side effects
on human health.
Efavirenz and cyclophosphamide are two of the better-studied drugs concerning CYP2B6
metabolism. These widely used drugs have very narrow therapeutic indices, and variations
in CYP2B6
expression and activity lead to significantly altered drug plasm concentrations [18 ]. Cyclophosphamide is a prodrug. Increased expression and activity of CYP2B6
may result in an increase in the circulating concentration of active moiety, which
is a beneficial effect [19 ]. On the contrary, in the case of efavirenz,
increased CYP2B6 enzyme metabolism may lead to an insufficient plasma concentration
and to not achieving anti-viral therapy [20 ]. According to our results, silybin
can inhibit the activity and down-regulate protein expression of the CYP2B6 enzyme,
and it is easily conceivable that silybin may be beneficial for decreasing the toxicity
of cyclophosphamide
when co-administered. Unfortunately, inhibiting activity and expression can also significantly
increase the drug plasm concentration of efavirenz, which could increase the neurotoxicity
of
efavirenz.
It is well-known that in vitro data is essential for understanding potential enzyme inhibition and drug–drug interaction
in vivo. However, many factors might influence drug
interactions mediated by CYP450 inhibition, including the extent of drug absorption,
the bioavailability, and the total clearance of the affected drug. Therefore, further
in vivo
studies are needed to identify the interactions of silybin and the substrates of the
CYP2B6 enzyme, which can provide more guidance for the clinical use of silybin.
In conclusion, in this study, we systematically examined how silybin inhibits the
the activity and expression of the CYP2B6 enzyme. The results showed that silybin
could inhibit the activity
of the CYP2B6 enzyme in a noncompetitive manner in an HLMs assay, as well as down-regulate
the expression of the CYP2B6 protein in HepaRG cells. These findings suggested a possible
drug–drug
interaction between silybin and drugs metabolized by the CYP2B6 enzyme, which has
to be confirmed by further research.
Material and Methods
Materials
Bupropion (≥ 99% purity), carbamazepine (≥ 99% purity), silybin (≥ 99% purity), and
ticlopidine (≥ 96% purity) were obtained from Meilun Biotech Corporation. TRIzol was
obtained from
Tiangen Biotech Corporation. Hydroxybupropion (≥ 99.9% purity) was purchased from
Cerilliant Corporation. Antibodies against CYP2B6 were purchased from Abcam Corporation,
and an antibody
against GAPDH was purchased from Proteintech Corporation. Reduced nicotinamide adenine
dinucleotide phosphate (NADPH) was obtained from Meilun Biotech Corporation. Human
liver microsomes
(HLMs, 50-donor pooled) and rat liver microsomes (RLMs, 10 mg) were purchased from
Bioreclamation-IVT Corporation. Methanol, acetonitrile (liquid chromatography-mass
spectrometry grade), and
formic acid (≥ 96% purity) were purchased from Meilun Biotech Corporation.
Methods
Determination of CYP450 enzymatic activity
Bupropion (100 µM) was used as selective probe substrates for CYP2B6 in human liver
microsomes (HLMs) and CYP2B1 in rat liver microsomes (RLMs). The reaction mixture
consisted of
0.25 mg/mL HLMs protein or 0.5 mg/mL RLMs protein, bupropion, and an NADPH regenerating
system (1.3 mM NADP, 3.3 mM glucose-6-phosphate, 3.3 mM MgCl2 , 1 U/mL glucose-6-phosphate
dehydrogenase) in 100 µL 50 mM KPI buffer solution (9.74 g K2 HPO4 ⋅3H2 O, 0.398 g Na2 HPO4 , and 0.280 g ethylenediaminetetraacetic acid
was dissolved in 500 mL ultrapure water), performed in 96-well plates. The silybin
was dissolved in dimethylsulfoxide, and the solvent volume did not exceed 1% (vol/vol)
compared to the
total incubation system volume. The ticlopidine (10 µM) was selected as the control
of the CYP2B6 inhibitor [21 ]. The concentration of silybin was 1, 10, 20,
and 100 µM in the incubation system. The reaction was initiated by adding NADPH and
then incubated at 37 °C for 60 min. The reaction was terminated with an equal volume
of ice-cold
acetonitrile. After the end of the reaction, 100 µL of the reaction solution was taken
out and added to 20 µL internal standard solution (carbamazepine, 612.4 ng/mL), vortexed,
and
centrifuged at 15 294×g for 5 min, and the supernatant was injected for HPLC/MS-MS
analysis of hydroxybupropion. All incubation samples were conducted in triplicate.
Time-dependent inhibition tests
Time-dependent inhibition (TDI) tests were conducted according to the previous reported
[22 ]. The mixture containing KPI buffer, NADPH regenerating system
(1.3 mM NADP, 3.3 mM glucose-6-phosphate, 3.3 mM MgCl2 , 1 U/mL glucose-6-phosphate dehydrogenase), HLMs or RLMs, and silybin preincubation
at 37 °C for 0, 5, 15, 30, and 60 min,
and then, the reaction was initiated by adding bupropion. The reaction was performed
at 37 °C for an additional 60 min. The sample preparation was performed according
to the section
above.
Kinetic analyses for inhibition
To determine the types of inhibition and the value of kinetic parameters, the final
substrate concentrations were from 5 µM to 300 µM (5 µM, 25 µM, 50 µM, 100 µM, 200 µM,
250 µM, 300 µM).
The incubation time was 60 min with HLMs (0.25 mg/mL) and RLMs (1 mg/mL) with or without
silybin (20 µM) preincubation. The sample preparation was performed according to the
section above.
The maximum reaction velocity (Vmax ) and the Michaelis constant of CYP450 substrate (Km ) values were calculated from nonlinear regression analysis of experimental
data according to the Michaelis–Menten equation. The Dixon and Lineweaver–Burk plots
were adapted to determine the inhibition type, and the second plot of slopes from
Lineweaver–Burk plot
versus the compoundsʼ concentrations was utilized to calculate the Ki value. All kinetic data were fitted by the following kinetic equations [23 ]:
Competitive: V= (V
max
S)/[Km (1 + I/Ki ) +S] (1)
Noncompetitive: V= (V
max
S)/[(Km + S)×(1 + I/Ki )] (2)
Mixed-inhibition: V= (V
max
S)/[(Km + S)×(1 + I/αKi )] (3)
V is the velocity of HBUP formation and Vmax is the maximum velocity. S and I are
substrate (bupropion) and inhibitor (silybin) concentrations. Ki is the inhibition constant of
the silybin against the target CYP2B6; Km is the Michaelis constant for HBUP formation
in HLM.
Next the silybin was incubated with HLMs (0.25 mg/mL) in different concentrations
(1, 10, 20, 30, 50, 60, 80 µM) and incubated with RLMs (0.5 mg/mL) in different concentrations
(0.05,
0.1, 0.5, 1, 10, 20, 30, 50, 60, 80, 100 µM) to explore the values of half inhibition
concentration (IC50 ).
Cell line and culture conditions
HepaRG cells were obtained from the National Collection Authenticated Cell Cultures,
Chinese Academy of Sciences. The procedures for induction and maintaining HepaRG cells
were carried
out as reported previously [24 ]. The HepaRG cells were maintained at 37 °C in humidified air incubator with 5% CO2 . HepaRG cells were detached by
gentle trypsinization containing ethylene diamine tetra-acetic acid (EDTA) and seeded
at a density of 2.6 × 104 cells in each well. They were first incubated in the DMEM
(Dulbeccoʼs modified Eagle medium) supplemented with 10% fetal bovine serum (FBS).
For differential HepaRG cells, they were first seeded in the growth medium composed
of DMEM with 10% FBS.
After 2 weeks, they were shifted to the same culture medium supplemented with 2% dimethyl
sulfoxide (differentiation medium) for 2 weeks. The medium was renewed every 1 to
2 days.
Dose-Response Curve based on MTT
HepaRG cells were seeded in a 96-well plate at a density of 2.6 × 104 cells in each well, incubated in DMEM medium at 37 °C for 24 h. Silybin (dissolved
in 0.2% DMSO) was
formulated in DMEM with 1% FBS in concentrations of 10, 30, 50, 80, 100, 150, 200,
and 300 µM, and six replicates were used for each concentration, with a final volume
of 100 µL. After
24 h, the medium was removed, and the cells were PBS washed. 0.5 mg/mL MTT (dissolved
in PBS) was added and incubated for 4 h at 37 °C. Following 4 h of treatment incubation,
the solution
was removed and 200 µL DMSO was added to each well, and then the absorbance was measured
at 490 nm.
Total RNA extraction, reverse transcription, and RT-qPCR analysis
Differentiated HepaRG cells were seeded in six-well plates and treated with different
concentrations of silybin (dissolved in 0.2% DMSO); 10, 50, and 100 µM were chosen,
as were different
incubation times. Using TRNsol (total RNA solution), total RNA was isolated from HepaRG
cells. The concentration of total RNA was quantified by NanoDrop 2002, and the total
RNA (500 ng/µL
– 600 ng/µL) was reverse transcribed using Strand cDNA Synthesis SuperMix for qPCR
kit. cDNA was then diluted five times with RNase-free distilled water, and RT-qPCR
was performed using a
qPCR SYBR mix kit. Primer sequences of related genes are shown in Table S1. RT-qPCR
conditions are as follows: 5 min at 95 °C, followed by 40 cycles of 10 s at 95 °C,
20 s at 60 °C, and
20 s at 72 °C. All data were normalized to the average of the housekeeping genes GAPDH.
Changes in gene expression between control and silybin-treated liver tissue or HepaRG
cells were
calculated using the following formulation: ΔCt=Ct gene – Ct reference, and the fold
change in gene expression was calculated with the comparative Ct (2-ΔΔCt ) method [25 ].
Western blot analysis
The effect of silybin on the protein expression of CYP2B6 in HepaRG cells was determined
by Western blot analysis. Total protein was extracted from HepaRG cells using RIPA
cell-lysis
buffer containing protease inhibitor PMSF. After protein concentration had been measured
using the BCA assay, protein extracts were added to 5× loading buffer and denatured
by heating at
100 °C for 10 min. The same amount of proteins was loaded on and separated by 10%
SDS-PAGE, transferred to polyvinylidene fluoride (PVDF) membranes, and blocked with
5% skimmed milk for
2 h at 37 °C. The primary antibodies GAPDH (diluted in TBST 1 : 2000) and antibodies
CYP2B6 (diluted in TBST 1 : 2000) were incubated at 4 °C overnight. The horseradish
peroxidase
(HRP)-conjugated secondary antibody (goat anti-rabbit in TBST diluted 1 : 10 000)
was incubated at 37 °C for 1 h and enhanced chemiluminescence (ECL) substrate was
used for detection.
Image J analysis software was used for quantitative analysis of the blots.
Molecular Docking
The Protein Data Bank (PDB) database was used to retrieve the 3D structure of CYP2B6
with PDB ID:5WBG. The two-dimensional structure of the silybin was downloaded from
PubChem in SDF
format, Chem 3D was used to transform the dimension of silybin from 2D to 3D, and
conversion of file format to. pdb. Water molecules in crystal structures were eliminated
by PyMOL
software, and hydrogen atoms were added to the protein. A docking study was performed
using AutoDock Vina. AutoDock Vina takes the. pdbqt file format for receptor and ligand
as an input.
The size of the grid box in AutoDock Vina was kept as 23.25, 15.75, and 15 for x,
y, and z, respectively, and its grid centered at dimensions (x, y, and z): 55.099,
-1.739, and 25.688,
respectively. The binding affinity of a ligand is a negative score with Kcal/mol as
a unit. AutoDock Vina script can generate nine poses of a ligand with different binding
energy for each
ligand input. In all of these poses, the preferred conformations were the ones that
have the lowest binding energy with the active site.
HPLC-MS/MS analysis
HPLC separation was performed on a C18 column (CAPCELL PAK C18, 50 × 2.00 mm, 5 µM)
coupled with a Security Guard cartridge (C18, 4 × 3.00 mm i. d., Phenomenex). For
in vitro
metabolism analysis, the mobile phase consists of methanol (solvent A) and water (containing
5 mM ammonium formate, solvent B). Mass data were acquired in positive ion mode, and
for the
optimized parameters and conditions see the support information.
Statistical analysis
All statistical analyses were performed using SPSS 25.0 software (IBM, USA). The main
pharmacokinetic parameters were calculated using Phoenix WinNonlin 7.0 software (Certara,
USA) with a
noncompartmental model. AutoDock Vina 1.2.2 (Molecular Graphics Lab, USA) were used
for the docking study. The data are expressed as the means ± standard error of the
mean. Significant
differences between the control and experimental groups were determined by Studentʼs
t -test using SPSS. A two-tailed P value < 0.05 was considered statistically significant.
Contributorsʼ Statement
Ling Wang and Xuehua Jiang conceived the study; Wenwen Zhang and Yice Zhang performed
literature search; Wenwen Zhang wrote the initial draft; Wenwen Zhang, Chengmin Wen
and Ling Wang revised
the draft and prepared the final version of the manuscript.
