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Utilizing Automated Imaging and Advanced 3D Cell Culture Techniques to Quantify Apoptosis Activity下載
Related Products: Cytation 1自動化影像系統暨多功能光學檢測儀 , Cytation 5 自動化影像系統暨多功能光學檢測儀
April 05, 2016
Authors: Brad Larson, BioTek Instruments, Inc., Winooski, VT USA; Youko Ejiri and Andrea Alms, Kuraray Co. Ltd., Tokyo, Japan
Apoptosis, or programmed cell death, is essential to normal development and homeostasis of all multicellular organisms, and is, in fact, a key research tool in the fight against cancer. Yet a challenge remains when culturing cell models, including those of human origin, for use in apoptosis studies. Traditional two-dimensional (2D) culture methods lack a biomimetic environment, and can result in a loss of differentiated cellular function and metabolic capacity. This may, in turn, suggest that 2D cultured tumor cells do not respond to cancer therapeutics/compounds in the same fashion as they would in vivo. Newer three-dimensional (3D) methods encourage cell-cell and cellmatrix interactions, and allow cell morphology and behavior to more closely mimic that found in the body. These 3D cell culture models are particularly beneficial for investigating mechanistic processes and drug resistance in tumor cells.
Here, we demonstrate the utility of a novel 3D spheroid cell culture model, Elplasia®, used to elucidate the apoptotic potential of two compounds in two different cell lines. The cells were populated onto the non-adherent micropatterned plates; thus, allowing cell spheroids to form and self-assemble per microwell. The microwell geometry aids spheroid formation in the center of each well, while the optically clear round bottom allows cellular imaging and the opaque body prevents cross-talk. Spheroid proliferation was initially validated visually, and induced apoptosis levels within the spheroids were then quantified, using a cell imaging multi-mode reader.
Materials and Methods
HT-1080 fibrosarcoma cells (Catalog No. CCL- 121) and HCT116 colorectal carcinoma cells (Catalog No. CCL-247) were obtained from ATCC (Manassas, VA).
Elplasia® 3D Discovery Tools
Elplasia 384-well black, clear-bottom microplates (Catalog No. SQ 200 100 NA 384) were donated by Kuraray Co. Ltd. (Tokyo, Japan).
Kinetic Apoptosis Kit (Catalog No. ab129817) was purchased from abcam® (Cambridge, MA). Doxorubicin HCl (Catalog No. BMLGR319- 0005) was donated by Enzo Life Sciences (Farmingdale, NY). Oridonin (Catalog No. O9639) and Hoechst 33342 (Catalog No. 14533) were purchased from Sigma-Aldrich (St. Louis, MO).
Cytation 5 is a modular multi-mode microplate reader combined with automated digital microscopy. Filter- and monochromatorbased 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, and is controlled by integrated Gen5™ Data Analysis Software. The instrument was used to image spheroids using brightfield and fluorescence microscopy, as well as individual differentiated cells plated in two dimensional format.
Cell Preparation and Spheroid Formation
HCT116 and HT 1080 cells were harvested, and each resuspended at a concentration of 2.25x105 cells/ mL. Next, 50 μL of suspended cells were added to separate test wells in the Elplasia 384-well microplate, for a total of approximately 50 cells per microspace. The plates were incubated at 37 °C/5% CO2 for approximately 48 hours to allow the cells to aggregate into spheroids within each micro-space.
Component Preparation and Addition
Doxorubicin was resuspended in 100% DMSO at a concentration of 10 mM, and oridonin was resuspended in 100% DMSO at a concentration of 20 mM. Serial titrations of both compounds were then created, ranging from 20-0 μM (2x), using 1:4 dilutions, in medium containing Hoechst 33342 and the Kinetic Apoptosis Reagent, pSIVA-IANDB, contained within the Kinetic Apoptosis Kit. After spheroid creation, 25 μL of medium was removed from each well, and replaced with an equal amount of either the doxorubicin or oridonin compound titration.
Spheroid Apoptosis Analysis
The plates were placed into Cytation™ 5, previously set to to 37 °C/5% CO2, where kinetic imaging was performed every four hours over a 48-hour period. A 4x objective was used to image the entire well using the brightfield imaging channel, with a 2x2 image montage incorporated to visualize the entire well. The same objective was used, along with DAPI and GFP imaging channels, to image all spheroids, and apoptotic spheroids, respectively.
Results and Discussion
Image-Based Spheroid Monitoring
HCT116 spheroid proliferation and location within the micro-space was confirmed using Cytation 5 and Gen5™ Data Analysis Software. Using brightfield imaging, four images were captured in 2x2 configuration to cover the well. The images were stitched together, using Gen5 software, to create a final, single image of all the micro-spaces in a well (Figure 1A), while the cell permeable fluorescent stain, Hoechst 33342 allowed identification of spheroid location by staining all nuclei blue (Figure 1B) using the DAPI channel.
Figure 1. Micro-space imaging at 4x magnification. (A) Stitched 2x2 montage images of HCT116 spheroids in a well micro-space. (B) DAPI channel imaging of spheroid location.
Phosphatidylserine is a cytosolic-facing cell membrane component, and its exposure on a cell’s extracellular surface, either persistently or transiently, is an indicator of early apoptosis. The cell membraneimpermeant fluorescent probe, pSIVA-IANDB binds to phosphatidylserine, creating a strong green fluorescent signal to allow apoptosis monitoring over time. Using this probe, HCT116 and HT 1080 spheroid apoptotic activity was tracked over the compound concentrations tested. As seen in the Figure 2 example, when imaging HT-1080 spheroid apoptotic activity treated with 400 nM doxorubicin, little to no signal is seen at 24 hours, but at 48 hours, high levels of green fluorescence are exhibited, indicating increased apoptosis levels.
Figure 2. Apoptotic activity in HT-1080 cells treated with 400 nM doxorubicin. 4x DAPI and GFP channel imaging (A) 24 hours post-treatment and (B) 48 hours post treatment.
Using the Primary Cellular Analysis parameters in Table 1, Gen5 automatically placed masks around the objects in the micro-space meeting the designated criteria (Figure 3A). Upon further analysis two phenomenon were identified. First, small variations can be seen in the size of aggregated spheroids in the well due to the number of cells settling into each micro-space. Second, emission signal from fluorescent probes can reflect off the plastic in the micro-spaces, causing these areas of the well to appear as spheroids. By using size and circularity sub-population criteria identified in Table 1, non-spheroidal objects, in addition to smaller spheroids not meeting minimal size criteria are eliminated from analysis. This serves to increase the accuracy of calculated results (Figure 3B). Finally, a second sub-population filter was applied to identify the number of apoptotic spheroids from the number of previously identified true spheroids (Figure 3C). Here the same two criteria were again used as with the first sub-population analysis, in addition to a minimal mean GFP setting to identify increases in signal above background levels. By incorporating the object masks and multiple sub-population criteria, only fluorescence emanating from actual spheroids is quantified, and any background noise is made insignificant, yielding apoptotic spheroid results with a high degree of accuracy and consistency. It is important to note that cellular analysis parameters may vary depending on cell type, so parameter optimization should always be performed when working with untested cell models.
Table 1. Gen5 fluorescent spheroid analysis primary, advanced, and sub-population parameters.
Figure 3. Cellular analysis procedure to determine apoptotic spheroid number per well. (A) Gen5 masks automatically drawn around objects meeting primary and advanced cellular analysis criteria using DAPI channel captured Hoechst 33342 signal; (B) red object masks indicating eliminated artifacts and spheroids not meeting minimal size and circularity sub-population requirements; and (C) purple object masks denoting objects not meeting initial sub-population criteria in addition to not meeting apoptotic spheroid criteria.
Spheroid Apoptosis Level Determination
Using the selected sub-population, Cytation™ 5 determined the apoptotic spheroid number per well over time using integrated Gen5™ Data Analysis Software. As seen in Figure 4, variations are seen between compound treatments and cell types, confirming that induction of apoptotic activity is due to the specific compound effect on the cells, and not due to spheroid incubation time in the micro-spaces. The Y-axis demonstrates the number of spheroids meeting the apoptotic spheroid sub-population criteria.
Figure 4. Apoptotic HCT116 and HT-1080 spheroid analysis over time after treatment with 10μM doxorubicin or oridonin.
Percent apoptotic spheroids per well was then calculated to normalize the results to account for varying numbers of spheroids being present in each well (Figure 5). The value was calculated by dividing apoptotic spheroid numbers by the total identified actual spheroids per well at each time point. The resulting percent apoptotic spheroid kinetic graphs can be used to ascertain differences between compound effects on 3D spheroids.
Figure 5. Kinetic graph showing percent apoptotic HCT116 or HT-1080 spheroids treated with a single 10 μM concentration of doxorubicin or oridonin.
Finally, end point analyses can be performed to compare apoptotic activity at specific compound concentrations and incubation times. Per Figure 6, the compounds exhibit a stronger apoptotic effect on HT1080 spheroids as witnessed by the rapid rise in apoptotic spheroid percentage at low compound concentrations. Apoptotic activity then decreases at compound concentrations above 1000 nM, most likely due to the cells within each spheroid becoming necrotic. HCT116 spheroids are more resistant to the compounds, as higher compound concentrations are needed to elicit an apoptotic response. The combined results illustrate that specific phenotypic apoptotic effects are able to be detected from individual cell-type (e.g., primary cell, stem cell, and cancer cell line) and drug combinations using cellular imaging and the Elplasia spheroid microplates.
Figure 6. Percent of apoptotic HCT116 and HT-1080 spheroids after 48-hour incubation with various concentrations of doxorubicin or oridonin.
Use of spheroids may provide increased biological relevancy versus 2D cultured cells in cancer studies. Spheroid proliferation, using the novel Elplasia 3D Discovery Tool microplates, represent a simple and viable cell model that is robust and reproducible. Spheroid apoptosis levels were rapidly and easily detected using the Kinetic Apoptosis Kit from Abcam. Finally, the Cytation™ 5 Cell Imaging Multi-Mode Reader is a sensitive, and flexible system when performing kinetic fluorescent and brightfield imaging of 3D spheroids using a wide magnification range. The combination together presents an accurate, easy-to-use method to assess target-based and phenotypic effects of anticancer drugs.