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Long-Term Hepatotoxicity Studies using Cultured Human iPSC-Derived HepatocytesDescargar
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August 15, 2017
Quantitative microscopy was employed to determine the effect of drugs on human iPSC derived hepatocytes aggregated into spheroids. Three phenotypes of toxicity were measured using fluorescent probes: reactive oxygen species generation, mitochondrial membrane potential decline and plasma membrane rupture. Results were compared to hepatocytes cultured in flat bottom microplates. Spheroid formation enabled much longer kinetic studies, extending out to 14 days. This capability allowed for measurement of full pharmacology and phenotype.
Drug-induced liver injury (DILI), or damage to the liver caused by prescription or nonprescription medications, continues to be a growing public health problem and a challenge for drug development. Effects can be acute or chronic and are compounded by the growing market for dietary supplements and herbal or non-traditional remedies. Most DILI is the result of unexpected responses to a particular medication, or long-term chronic damage that was unseen during standard hepatotoxicity testing.
To test new drug entities for potential DILI, in vivo models remain the gold standard. However, these studies are costly, time-consuming, and more importantly, rather poor predictors of human toxicity due to the incorporation of mainly murine hepatocytes. Consequently, in vitro screens using primary hepatocytes are less costly, reduce animal exposure, and are more amenable to higherthroughput platforms. However, limitations such as high inter-individual variability, finite batch sizes and changes in cell morphology, as well as liver-specific functions during long-term culture are challenging this model. Human induced pluripotent stem cell (iPSC)-derived hepatocytes, by comparison, are a promising in vitro alternative because they demonstrate primary tissuelike phenotype, high levels of consistency and unlimited availability.
When performing toxicity studies, hepatocytes are repeatedly dosed with varying concentrations of a potential drug over multiple days to assess any cumulative effects. This poses particular challenges when incorporating two-dimensional (2D) cell culture of primary hepatocytes due to the fact that the cells rapidly dedifferentiate and lose metabolic activity when cultured in this manner. Three-dimensional (3D) cell culture models exist that allow cells to aggregate and retain the functionality and communication networks found in vivo. The favorable environment created by the 3D culture model then allows long-term dosing experiments to be performed that more accurately assess the cumulative effects of a drug.
Here we demonstrate the suitability of 3D cultured human iPSC-derived hepatocytes for use in hepatotoxicity studies. Hepatocyte spheroids were exposed to multiple concentrations of three drugs with the DILI category I or III: tolcapone, acetaminophen, and mitomycin C. Direct imagebased assessment of hepatocyte health based on three phenotypes, after short-term and longterm exposure to the drugs was performed. These phenotypes included generation of reactive oxygen species (ROS) which is indicative of oxidative stress; mitochondrial membrane potential (MMP) decline, which is an early trigger of the apoptotic cascade; and plasma membrane (PM) rupture, which is a sign of necrotic cell death. Comparisons were also made to iPSC-derived hepatocytes cultured in 2D.
Materials and Methods
iCell Hepatocytes 2.0 (Catalog No. PHC-100-020-001) were donated by Cellular Dynamics International (Madison, WI). These cells are human iPSC-derived hepatocytes that exhibit typical hepatic functionality and phenotypic stability. Due to their human origin, native cell-like behavior, and ease of use, iCell Hepatocytes 2.0 represent an optimal test system for basic hepatic biology in all areas of drug development, disease modeling, and toxicology.
Assay and Experimental Components
BioCoat™ Collagen I-coated 24- (Catalog No. 354408) and 384-well plates (Catalog No. 354667) were donated by Corning Life Sciences (Corning, NY). GravityTRAP™ ULA 96-well plates (Catalog No. ISP-09-001) were purchased from PerkinElmer (Waltham, MA). Acetaminophen (Catalog No. 1706), Mitomycin C (Catalog No. 3258) and Tolcapone (Catalog No. 5864) were purchased from R&D Systems (Minneapolis, MN). ROS-ID® Total ROS/ Superoxide Detection Kit (Catalog No. ENZ-51010), MITO-ID® Membrane Potential Detection Kit (Catalog No. ENZ-51018) and NUCLEAR-ID® Blue/Red Cell Viability Reagent (GFP CERTIFIED®) (Catalog No. ENZ-53005) were donated by Enzo Life Sciences (Farmingdale, NY).
Cytation 5 from BioTek Instruments is a modular multimode microplate reader combined with automated digital microscopy. Filter- and monochromator-based microplate reading are available, and the microscopy module provides up to 60x magnification in fluorescence, brightfield, color brightfield and phase contrast. The instrument can perform fluorescence imaging in up to four channels in a single step. With special emphasis on live-cell assays, Cytation 5 features temperature control to 65 °C, CO2/O2 gas control and dual injectors for kinetic assays. Z-stacking and projection can also be performed to support 3D cell biology. The integrated Gen5™ Microplate Reader and Imager Software was used to control the imager and for automated dual-masking analysis.
Cell Culture Preparation
iCell Hepatocytes 2.0 were thawed and cultured according to the manufacturer’s protocol. See CDI User's Guide for more details and media information. Cells intended for 3D spheroid formation were first seeded into 24-well collagen coated plates at a concentration of 600,000 cells/well. Cells kept for 2D cell culture were added to 384- well collagen-coated plates at a concentration of 30,000 cells/well. All plates were incubated at 37 ºC/5% CO2, and media was exchanged every twenty-four hours. After five days, cells in the 24-well plates were dissociated and seeded into GravityTRAP plates at a concentration of 2000 cells/well to allow for spheroid formation (typically complete after 48 hours). Media in the 384-well plates continued to be changed daily until compounds were added on Day 7 post-thaw.
Hepatotoxicity Assay Procedure
Following spheroid formation, 10-point titrations of the known hepatotoxins acetaminophen (5000-0 μM), mitomycin C (10-0 μM), and tolcapone (200-0 μM) were prepared using 1:2 serial dilutions. These concentration ranges are reflective of common dosages used for treatment. Spent media was removed from all test plate wells and replaced with fresh media and compound titrations. Wells were re-dosed with fresh compound every forty-eight hours.
Timepoints for assaying the health of the cells were 1 and 7 days for 2D plated hepatocytes and 1, 7, and 14 days for 3D spheroids. Assay measurements included:
- Reactive oxygen species (ROS) generation using ROS-ID Total ROS/Superoxide detection kit, which includes two fluorescent dyes as major components: Oxidative Stress Detection Reagent (Green) for total ROS detection reagent and Superoxide Detection Reagent (Orange).
- Mitochondrial membrane potential (MMP) decline using MITO-ID, a cationic dye that fluoresces either green or orange depending upon membrane potential status. A reduction of orange fluorescence associated with MMP decline indicates early stages of apoptosis.
- Plasma membrane (PM) rupture using NUCLEAR-ID, a mixture of a blue fluorescent cell-permeable nucleic acid dye for live cell imaging and a red fluorescent cellimpermeable nucleic acid dye that is suited for staining dead nuclei.
The assay workflow began with media removal followed by media replacement containing probes from either the multiplexed ROS-ID and NUCLEAR-ID, or MITO-ID and NUCLEAR-ID fluorescent microscopy kits, and incubated for 5 hours at 37 ºC/5% CO2. Wells were then washed with PBS to remove unincorporated probes, followed by image-based detection, also in PBS, using the Cytation 5. A 10x objective was used for 2D cellular imaging and a 4x objective for 3D cellular imaging.
The signal from all multiplexed fluorescent probes was captured in a single imaging step using the following imaging channels:
ROS-ID/NUCLEAR-ID multiplex assay – DAPI channel: NUCLEAR-ID live cell probe; Texas Red channel: NUCLEAR-ID dead cell probe; RFP channel: ROS-ID superoxide probe.
MITO-ID/NUCLEAR-ID multiplex assay – DAPI channel: NUCLEAR-ID live cell probe; Texas Red channel: NUCLEARID dead cell probe; GFP channel: MITO-ID membrane potential probe cytosolic monomers; RFP channel: MITO-ID mitochondrial aggregates.
Results and Discussion
2D Hepatotoxicity Testing
When assessing the potential of a drug or its metabolites to cause DILI, it is common not only to examine the ability to induce overt cell death, but also to determine the cause of the observed hepatotoxicity. Two commonly measured mechanisms include induction of oxidative stress and ROS generation, in addition to loss of mitochondrial membrane potential (MMP) as an early indicator of apoptotic activity. The capacity of acetaminophen, mitomycin C and tolcapone to induce oxidative stress and apoptosis, leading to downstream necrosis, following short-term and long-term treatment of 2D plated iCell Hepatocytes was determined using fluorescence microscopy-based probes (Figure 1).
Figure 1. Images of 2D plated iCell Hepatocytes 2.0 expressing phenotypes of cellular distress after treatment with acetaminophen. Images captured using a 10x objective. Top row: ROS generation detected as an increase in orange puncta using the ROS-ID probe, whereas NUCLEAR-ID stained live cells blue or dead cells pink/red. (A) Low; and (B) intermediate ROS generation after one day of acetaminophen exposure; and (C) high ROS levels following seven days of acetaminophen treatment (625 μM). Middle row: MMP decline visualized as a loss of orange aggregates and a simultaneous increase in smaller, rounded-up green stained cells due to compromised MMP as detected by the MITO-ID reagent. Cells were also stained with NUCLEAR-ID probes to stain live cells blue and dead cells pink/red. (D) Control cell population exhibiting stable mitochondrial membrane potentials. (E) Partial and (F) complete loss of orange mitochondrial aggregates indicative of all cells having compromised MMP following one and seven days of acetaminophen exposure (625 μM). Bottom row: PM rupture indicated by a loss of green cytosolic staining using the green-fluorescent MITO-ID probe along with an increase in pink/ red stained dead cells versus blue live cells via NUCLEAR-ID. (G) Low amount of PM rupture following one-day exposure versus (H) high amount of cells with PM rupture following seven days of acetaminophen exposure (625 μM). (I) Loss of cell attachment after seven days of treatment with 5 mM acetaminophen.
Consistent with previously reported mechanisms of acetaminophen toxicity1, these multiplexed fluorescent assays enabled detection of drug induced hepatotoxicity effects following exposure to high doses of acetaminophen. Increasing acetaminophen concentrations and repetitive dosing resulted in detection of ROS formation (Figures 1A-C), loss of mitochondrial membrane potential associated with apoptosis (Figures 1D-F), and eventual loss of cell membrane integrity and necrotic cell death (Figures 1G-I).
2D Hepatocyte Quantitative Image Analysis
Quantification of superoxide expression, induction of apoptosis, and induction of necrotic activity, was performed for all compound treatments and incubation periods using the cellular analysis features of Gen5™ and the parameters found in Tables 1-3.
Table 1. 2D Superoxide Expression Cellular Analysis Parameters.
Table 2. 2D Apoptotic Activity Cellular Analysis Parameters.
Table 3. 2D Necrotic Activity Cellular Analysis Parameters.
For superoxide expression and apoptotic activity, primary masks were placed around Hoechst 33342 stained nuclei (A). Secondary masks were then placed around areas of the target probe exceeding set threshold values (Figure 2B).
For necrotic activity, primary masks again were placed around nuclei stained with the live cell probe from the NUCLEAR- ID Blue/Red Cell Viability Reagent (Figure 2C). As both the live and dead cell probes were localized to the nucleus, the fluorescence from the dead cell probe was also analyzed within the primary mask (Figure 2D).
Figure 2. 2D hepatotoxicity primary and secondary object mask placement. Untreated hepatocytes following addition of MITO-ID superoxide probe showing (A) Primary nuclear object mask and (B) secondary object masks around target probe signal. Hepatocytes following seven day acetaminophen exposure (625 μM) showing (C) primary mask placement using signal from NUCLEAR-ID live cell probe, and (D) dead cell probe signal within primary masks.
Finally, subpopulation criteria were set to identify cells statistically responding to compound treatments (positive responder cells). Table 4 describes the specific calculated cellular analysis metric and subpopulation criteria used to identify the cells exhibiting the three different phenotypic effects from the compound treatment. The fraction of responding to total cells, expressed as a percentage, indicated the effect each compound treatment had on the hepatocytes in the well (Figure 3).
Table 4. 2D Positive Responder Cell Criteria.
Figure 3. 2D hepatotoxicity results. (A) Compound dose response curves, and (B) calculated EC50 values.
The over-the-counter pain reliever acetaminophen and the Parkinson’s disease drug tolcapone demonstrated the phenotypes of ROS generation and MMP decline after only 24 hours treatment in a similar fashion. The expression of these phenotypes was increased and evident at lower doses after 7 days treatment. PM rupture, however, was only significantly evident after 7 days treatment. The chemotherapeutic agent mitomycin C demonstrated relatively muted phenotypic responses compared to the other drugs, especially after only one day of treatment. However, still induces a long-term toxic response on the 2D plated hepatocytes.
3D Hepatotoxicity Testing
The toxic effects of acetaminophen, mitomycin C and tolcapone were also examined in 3D cultured iCell Hepatocytes 2.0 spheroids (Figure 4). The same three phenotypes were assessed following 1, 7, and 14 day exposures to each compound.
Figure 4. Images of iCell Hepatocytes 2.0 spheroids expressing phenotypes of cellular distress after treatment with acetaminophen. Images captured using a 4x objective. Top panel: ROS generation was detected as an increase in orange signal within the spheroid using the ROS-ID probe. (A) Low; (B) intermediate; and (C) high ROS levels following fourteen days of acetaminophen treatment. Middle panel: MMP decline was visualized as a loss of orange signal within the spheroid while maintaining consistent green signal as detected by the MITO-ID reagent. (D) Control cell population exhibiting stable MMP. (E) Partial; and (F) complete loss of orange mitochondrial aggregates following fourteen days of acetaminophen treatment. Bottom panel: PM rupture was indicated by an increase in pink/red stained dead cells within the spheroid versus blue live cells via NUCLEAR-ID. (G) Untreated hepatocyte spheroid; (H) intermediate; (I) high amounts of PM rupture following fourteen-day acetaminophen treatment.
Similar to that seen with imaging of 2D plated hepatocytes, the signal from target probes was also detected from hepatocytes aggregated into 3D spheroids. By collecting images at multiple z-planes and then projecting a final image for each imaging channel containing the most in focus portions of the stack, accurate analysis of the impact of compound treatment was performed.
3D Hepatocyte Spheroid Z-Projected Image Analysis
Levels of ROS generation, MMP decline and PM rupture were calculated in a similar manner as with the 2D plated hepatocytes. For optimal calculations when using images of the 3D spheroids, Gen5™ cellular analysis parameters were adjusted appropriately (Tables 5-7).
Table 5. 3D Superoxide Expression Cellular Analysis Parameters.
Table 6. 3D Apoptotic Activity Cellular Analysis Parameters.
Table 7. 3D Necrotic Activity Cellular Analysis Parameters.
By adjusting primary analysis criteria, such as minimum and maximum object size, primary masks were placed around the entire spheroid as a single object (Figure 5A). Secondary masks were then placed around the target fluorescent probe signal emanating from all cells within the spheroid meeting threshold criteria indicative of responding cells to compound treatment (Figures 5B). The percentage of area covered by the secondary masks divided by the entire spheroid area represented the portion of responding cells (Figure 5C and D).
Figure 5. 3D hepatotoxicity results. Primary nuclear object masks, and secondary object masks around (A) low; and (B) high target probe signal. (C) Compound dose response curves. (D) Calculated EC50 values for 2D and 3D hepatocytes.
Analysis of the projected 3D images, dose-response curves, and generated EC50 values (Figures 5A-B, 5C, 5D, respectively) indicates that the hepatotoxins have a minimal short-term effect and right-shifted pharmacology in 3D compared to 2D plated hepatocytes. The images also demonstrate that induced necrosis in spheroidal hepatocytes does not cause large-scale cell loss. This feature of 3D cultures can allow long-term hepatotoxicity results to be generated with greater accuracy. Finally, the ability to perform extended compound treatments with the 3D hepatocyte cell model allow for the elucidation of potential mechanisms of action not possible in 2D. This is seen by the induced ROS generation following a prolonged fourteen day mitomycin C treatment (Figure 5C).
3D spheroid cultures of iPSC-derived human hepatocytes, such as iCell Hepatocytes 2.0, provide a relevant cell model to perform long-term in vitro hepatotoxicity testing, while incorporation of fluorescent probes allow quantification of cell toxicity phenotypes in 2D and 3D cell models. Additionally, the optimized capabilities of the Cytation™ 5 and Gen5™ Software provide automated, dependable imaging and analysis of incorporated cell models and fluorescent probes. The combination of appropriate cell models, assay methodology, and imaging and analysis create an optimal method to determine the potential chronic hepatotoxic effects of test molecules.
1. Hinson, J.A.; Roberts, D.W.; James, L.P. Mechanisms of Acetaminophen-Induced Liver Necrosis. Handb Exp Pharmacol. 2010, (196), 369-405.