a rapid high content cytochrome p450 (cyp) mrna ...figure 1. workflow for cyp induction screening...
TRANSCRIPT
Figure 1. Workflow for CYP induction screening studies
Introduction
Cytochrome P450 (CYP) enzymes play an important role in the oxidative metabolism of many drugs. Consequently, inhibition or induction of these enzymes by perpetrator drugs can result in alterations in the clearance of a victim drug that is metabolized by CYP pathways (i.e. drug-drug interactions; DDIs) [1]. The induction of CYP enzymes, which results in elevated CYP expression levels, can lead to an increase in the clearance of a victim drug resulting in potential loss of drug efficacy [2]. Thus, characterizing a new drug’s CYP induction potential early in drug development can lead to better and safer drug design. In the present study, we developed a rapid CYP induction screen evaluating up to 10 compounds in one assay (at three concentrations, with an additional positive control) with the fold change of CYP3A4 mRNA expression levels measured as an endpoint.
Chemicals and test systemsAll chemicals used for treatments were purchased from Sigma-Aldrich (St.Louis, MO) or Toronto Research Chemicals (Toronto, ON, Canada) and wereof analytical grade. The sources of all other reagents have been described previously [3]. Cryopreserved human hepatocytes (HC5-27) from a single donor were prepared from a non-transplantable liver and characterized at XenoTech, LLC (Lenexa, KS) as described previously [4, 5].
In vitro CYP induction screenThe typical workflow for the CYP induction screen is shown in Figure 1.
Treatments: Cryopreserved human hepatocytes from a non-transplantable single human liver donor were seeded and cultured in a collagen-Matrigel sand-wich on 96-well plates at 37 ± 1°C (with 95 ± 5 % humidity and 5 ± 1 % CO2). Cells were allowed to adapt in culture for 24 hours or 48 hours after seeding and overlay, followed by a single treatment for 24 hours, in triplicate, with carba-mazepine (1, 10, 100 µM), clobazam (1, 10, 50 µM), flumazenil (1, 10, 25 µM, non-inducer), nifedipine (1, 10, 100 µM), omeprazole (1, 10, 50 µM), phenytoin (1, 10, 40 µM), pioglitazone (1, 10, 50 µM), pleconaril (1, 10, 50 µM), rifampin (1, 5, 10, 20 µM), ritonavir (1, 10, 20 µM), rosiglitazone (1, 10, 50 µM), DMSO (0.1 % v/v; vehicle), or rifampin (up to 20 µM; positive control) in supplemented Modified Chee’s Medium (MCM+). This was repeated up to n = 4.
RNA isolation and qPCR: Twenty-four hours after treatment, cells were har-vested with Buffer RLT (Qiagen) with β-mercaptoethanol for isolation on the KingFisher Flex (KFF; Thermo Scientific) with the MagMAX-96 for Microarrays kit (Ambion). RNA was quantified with the NanoDrop 8000 UV-Vis Spectropho-tometer (Thermo Scientific). Reverse transcription was performed with the High
Data were collected from two culture conditions; either with a 24-hour or a 48-hour adaptation period after hepatocytes were initially seeded, overlaid and treated with various compounds for 24 hours. The results (shown in Figure 2 and 3) demonstrated robust concentration-dependent CYP3A4 mRNA induction. The highest level of induction for each compound was observed at the highest concentration tested (with the exception of nifedipine and ritonavir which plateaued at ≤ 10 µM). As expected, the non-inducer, flumazenil showed little to no induction and served as a negative control. CYP3A4 mRNA fold changes for each compound were substantially greater after a 24-hour adaptation period (Figure 2) compared to plates with a 48-hour adaptation period (Figure 3). This is likely due to cellular normalization of CYP transcript levels over time. However with both adaptation periods, concentration-dependent induction of all prototypical inducers was observed, indicating that an additional 24-hour culture adaptation period (i.e. 48-hour adaptation) is not required to identify potential CYP3A4 inducers.
A DIVISION OF
A Rapid High Content Cytochrome P450 (CYP) mRNA Induction Screen for Early Drug DevelopmentCatherine Wiegand, Bradley Klaus, Rebecca R. Campbell, Michelle McBride,Krystal M. Green, Donald Miller, Robert T. Grbac, and Faraz KazmiXenoTech, LLC, 16825 W 116th St, Lenexa, KS 66219 USA
Materials & Methods
1 Parkinson A, et al. (2013) Biotransformation of Xenobiotics, in: Casarett & Doull's Toxicology: The Basic Science of Poisons (Klaassen CD ed). McGraw-Hill, Inc., New York City, NY: pp 185-367.
2 Lin J (2006) CYP induction-mediated drug interactions: in vitro assessment and clinical implications. Pharmaceutical Research 23(6): 1089-1116.
3 Paris BL, et al. (2009) In vitro inhibition and induction of human liver cyto-chrome P450 enzymes by milnacipran. Drug Metab Dispos 37(10): 2045-2054.
4 Pearce RE, et al. (1996) Identification of the human P450 enzymes involved in lansoprazole metabolism. J Pharmacol Exp Ther 277(2): 805-16.
5 Parkinson A, et al. (2004) The effects of gender, age, ethnicity, and liver cirrhosis on cytochrome P450 enzyme activity in human liver microsomes and inducibility in cultured human hepatocytes. Toxicol Appl Pharmacol 199(3): 193-209.
References
Conclusions
Results
• A 24-hour culture adaptation period was sufficient to screen for a potential CYP3A4 mRNA inducer. Concentration-dependent induction was observed withall known CYP3A4 inducers, demonstrating successful assay performance.
• Overall, the results of the assay with the compounds tested were as expected, demonstrating the utility of this screen to rapidly and efficiently obtain CYP induction data early in the drug development process.
Overview
• The purpose of this study was to develop a high content method to rapidly screen compounds (10 compounds at three concentrations with an additional positive control) for CYP3A4 induction (can be used for other CYPs as well).
• A single donor of primary human hepatocytes was evaluated for CYP3A4 inducibility after a 24-hour and a 48-hour culture adaptation period.
• Automated RNA isolation and qPCR were used to determine CYP3A4 mRNA expression levels.
• Negative and positive controls for CYP induction, including prototypical CYP3A4 inducers, responded appropriately as either non-inducing or inducing, respectively, with a 24-hour culture adaptation period followed by a 24-hour treatment period.
• A 48-hour culture adaptation period was not required to determine which compounds caused CYP3A4 mRNA induction.
Capacity cDNA Reverse Transcription kit (Life Technologies) on the 7900HT Real-Time PCR System (AB7900; Applied Biosystems). qRT-PCR was per-formed in triplicate on the AB7900 and data were analyzed by the ΔΔCt method (Applied Biosystems User Bulletin #2). Relative quantification measured change relative to the DMSO and normalized to the endogenous control (GAPDH) for CYP3A4 mRNA expression. Data were reported through Galileo LIMS (Thermo Scientific) and Crystal reports 2013 (SAP Business Objects).
Figure 2. Mean fold induction of CYP3A4 mRNA by a panel of known inducers with a 24-hour culture adaptation period followed by a 24-hour treatment period
Figure 3. Mean fold induction of CYP3A4 mRNA by a panel of known inducers with a 48-hour culture adaptation period followed by a 24-hour treatment period
Cell Culture• Attaching hepatocytes
plated in a 96-well plate
• 24- and 48-hour adapt-ation period evaluated
Treatment• Controls: 0.1 % DMSO
and up to 20 µM rifampin• Test compounds: up to
10 compounds at three concentrations
• 24-hour treatment period
Harvest• Buffer RLT with
β-mercaptoethanol
• Triplicate cell culture wells pooled per treatment group
Isolation• KingFisher Flex
• MagMAX-96 for Microarrays Total RNA Isolation Kit
Quantification• NanoDrop 8000
Spectrophotometer
PCR• Reverse transcription
on the AB 7900HT
• qRT-PCR on the AB 7900HT
Analysis• Processed and reviewed
by experienced analysts and study director
• Clear results
0
10
20
30
40
50
60
0.1 %
DMS
O10
µM
Rifa
mpin
(PC)
1 µM
Carb
amaz
epine
10 µ
M Ca
rbam
azep
ine10
0 µM
Carb
amaz
epine
1 µM
Rifa
mpin
10 µ
M Ri
famp
in20
µM
Rifa
mpin
1 µM
Nife
dipine
10 µ
M Ni
fedip
ine10
0 µM
Nife
dipine
1 µM
Phen
ytoin
10 µ
M Ph
enyto
in40
µM
Phen
ytoin
1 µM
Rito
navir
10 µ
M Ri
tona
vir20
µM
Rito
navir
1 µM
Rosig
litazo
ne10
µM
Rosig
litazo
ne50
µM
Rosig
litazo
ne1 µ
M Pi
oglita
zone
10 µ
M Pi
oglita
zone
50 µ
M Pi
oglita
zone
1 µM
Clob
azam
10 µ
M Cl
obaz
am5 0
µM
Clob
azam
1 µM
Plec
onar
il10
µM
Plec
onar
il50
µM
Plec
onar
il1 µ
M Fl
umaz
enil
10 µ
M Fl
umaz
enil
25 µ
M Fl
umaz
enil
Fold
Cha
nge
Fold
Cha
nge
n = 1¤
0
20
40
60
80
100
120
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0.1 %
DMS
O10
µM
Rifa
mpin
(PC)
1 µM
Carb
amaz
epine
10 µ
M Ca
rbam
azep
ine10
0 µM
Carb
amaz
epine
1 µM
Rifa
mpin
10 µ
M Ri
famp
in20
µM
Rifa
mpin
1 µM
Nife
dipine
10 µ
M Ni
fedip
ine10
0 µM
Nife
dipine
1 µM
Phen
ytoin
10 µ
M Ph
enyto
in40
µM
Phen
ytoin
1 µM
Rito
navir
10 µ
M Ri
tona
vir20
µM
Rito
navir
1 µM
Rosig
litazo
ne10
µM
Rosig
litazo
ne50
µM
Rosig
litazo
ne1 µ
M Pi
oglita
zone
10 µ
M Pi
oglita
zone
50 µ
M Pi
oglita
zone
1 µM
Clob
azam
10 µ
M Cl
obaz
am50
µM
Clob
azam
1 µM
Omep
razo
le10
µM
Omep
razo
le50
µM
Omep
razo
le1 µ
M Pl
econ
aril
10 µ
M Pl
econ
aril
50 µ
M Pl
econ
aril
1 µM
Flum
azen
il10
µM
Flum
azen
il25
µM
Flum
azen
il
n = 2n = 1¤
All others n ≥ 3