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3D Spheroid-Based Tumor Invasion Assay下載
Related Products: BioSpa 8 自動化細胞培養箱, BioSpa 活細胞分析系統 , Cytation 5 自動化影像系統暨多功能光學檢測儀, MultiFlo FX 多功能微量盤分注儀
July 16, 2018
Authors: Brad Larson, Principal Scientist, BioTek Instruments, Inc., Winooski, VT USA; Jan Seldin, Greiner Bio-One, Inc., Monroe, NC USA
Establishment of in vitro models that mimic tumor invasion as part of the metastatic process, are a critical part of oncology research. The need to incorporate multiple cell types, long-term kinetic analysis, methods to allow 3D invasion into the surrounding matrix, and appropriate detection and analysis, has made it difficult to create new models. The procedure described here meets these needs through inclusion of advanced imaging capabilities allowing for capture of multiple images throughout a range of z-heights, using brightfield and fluorescence channels in a kinetic fashion. Final processed images, following stitching and z-projection, enable accurate cellular analysis to discern the invasive capabilities of 3D cellular structures over time.
Oncology drug discovery has been met with multiple challenges over the years. As cancers develop multiple mutations during carcinogenesis, targeted approaches to individual gene mutations common to many drug discovery campaigns have mostly limited efficacy. Conversely, the advancement of novel methods that focus on the inhibition of the invasive phenotype of metastasis offers greater potential for meaningful intervention, particularly due to the fact that most cancer patients die only after metastasis has occurred. For this approach to work, in vitro cell models used in early drug discovery should mimic as close as possible the complex metastatic process. Tumors in vivo exist as a three-dimensional (3D) mass of multiple cell types, including cancer and stromal cells. Therefore, incorporating a 3D spheroidtype cellular structure that includes co-cultured cell types forming a tumoroid, provides a more predictive model than the use of individual cancer cells seeded in microplates. A further constraint is the need for long term kinetic experiments to capture the invasion process which typically require multiple days. Thus environment control of the assay is needed such that the cell viability of the spheroid is maintained over this long period and putative drug effects properly assessed. Finally, the only suitable readout for monitoring tumor invasion is microscopy due to the small size of the spheroid. To be effective in drug discovery, the microscope must have automated image capture, processing and analysis to be able to cope with the multiple assay conditions, compounds tested and kinetic images taken. This work will demonstrate a procedure for the generation of 3D spheroidal tumoroid structures, creation of a suitable invasion matrix, automated kinetic imagebased monitoring, and cellular analysis of captured z-stacked images of tumor invasion.
U-87 and LN-229 glioblastoma multiforme (GBM) cell lines were used in this study as they have demonstrated phenotypic differences and metastatic ability1. Notably, the growth suppressing PTEN gene is mutated in U-87 cells, yet functions normally in LN-229 cells. Additionally, the human cytomegalovirus phosphotransferase protein UL-97 inhibits DNA elongation and replication; and is absent from U-87 cells, but present in LN-229 cells2. This supports a more aggressive growth and invasion pattern for U-87 cells. Both cell types were co-cultured with fibroblasts to create 3D tumoroids more closely representing in vivo tumor conditions and allowed to invade through a protein matrix. 17-allylamino- 17-demethoxygeldanamycin (17-AAG), known to inhibit the function of heat shock protein 90 (Hsp90), a chaperone protein that stabilizes proteins required for tumor growth, was used here to inhibit potential tumor invasion3. Quantification of kinetic captured images was used to characterize the invading potential of inhibited and uninhibited tumoroid cultures.
Materials and Methods
U-87 GBM cells expressing GFP were generously donated by Dr. Sachin Katyal (University of Manitoba, Winnipeg, Manitoba, Canada). LN-229 GBM cells (Catalog No. CRL-2611) were obtained from ATCC (Manassas, VA). Human neonatal dermal fibroblasts expressing RFP (Catalog No. cAP-0008RFP) were purchased from Angio-Proteomie (Boston, MA).
Matrigel® Basement Membrane Matrix, Phenol Red-Free (Catalog No. 356237) was purchased from Corning Life Sciences (Corning, NY). The selective Hsp90 inhibitor 17-AAG (Catalog No. 1515) was sourced from Tocris Bioscience (Avonmouth, Bristol, UK). CellTracker™ Deep Red dye (Catalog No. C34565) was purchased from ThermoFisher Scientific (Waltham, MA). 96- well, cell-repellent, polystyrene, round bottom, clear, sterile, microplates with lid (Catalog No. 650979) were generously donated by Greiner Bio-One.
Cytation 5 is a modular multi-mode microplate reader combined with an automated digital microscope. 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 shaking, temperature control to 65 ºC, CO2/O2 gas control and dual injectors for kinetic assays and is controlled by integrated Gen5™ Microplate Reader and Imager Software, which also automates image capture, analysis and processing. The instrument was used to kinetically monitor 3D tumoroid activity over the incubation period.
The BioSpa 8 Automated Incubator links BioTek readers or imagers together with washers and dispensers for full workflow automation of up to eight microplates. Temperature, CO2/O2 and humidity levels are controlled and monitored through the BioSpa software to maintain an ideal environment for cell cultures during all experimental stages. Test plates were incubated in the BioSpa to maintain proper atmospheric conditions for a period of seven days and automatically transferred to the Cytation 5 every twelve hours for brightfield and fluorescence imaging.
The MultiFlo FX is a modular, upgradable reagent dispenser that can have as many as two peri-pump (8 tube dispensers), two syringe pump dispensers and a strip washer. The syringe and washer manifolds can be configured for plate densities from 6- to 384-well.
Cell Preparation and Tumoroid Formation
Prepared U-87 and fibroblast cells were each harvested and combined in a final concentration of 2.5x104 cells/mL for each cell type in complete medium. After dispensing 100 μL of cell suspension into appropriate microplate wells, the microplate was incubated at 37 ºC/5% CO2 for forty-eight hours to allow cells to aggregate into tumoroids. This process was repeated using LN-229 cells stained with CellTracker Deep Red dye and fibroblast cells at the same concentrations and volumes.
Invasion Matrix Preparation
Upon completion of tumoroid formation, 70 μL of complete medium was robotically removed from each well, and the tumoroid plate placed on ice in a refrigerator for five minutes to cool the cells. Matrigel matrix was then thawed on ice. 17-AAG was diluted to a 2x concentration of 20,000 nM in invasion media and used to create an eight-point titration from 20,000 nM to 0 nM using serial 1:4 dilutions. The inhibitor titrations were further diluted to a 1x concentration by combining with either invasion media or Matrigel matrix. With the plate still on ice, 70 μL of Matrigel matrix plus titrated compound were added to each well containing tumoroids, then overlaid with 100 μL invasion media containing titrated compound. The microplate was centrifuged at 300 × g for five minutes in a swinging bucket centrifuge that was previously set to 4 ºC for tumoroid positioning, then transferred to a 37 ºC/5% CO2 incubator for one hour to initiate gel formation.
Tumor Invasion Assay Performance
After gel formation was complete, the microplate was transferred to BioSpa 8, where the software was programmed such that the microplate was automatically transferred to Cytation 5 for brightfield and fluorescent imaging of the wells every twelve hours over the sevenday incubation period. Table 1 lists the settings used to perform automated image capture of each sample well.
Table 1. Automated 3D tumoroid invasion imaging parameters.
Individual image tiles from each z-plane captured using the three by two montage were then stitched together (Table 2).
Table 2. Image stitching parameters.
A single image projection was then created from the 20 slice stitched z-stack (Table 3). The focus stacking method was chosen, which automatically selects the most in focus pixel from each image in the stack for inclusion in the final projection. This allows for the most accurate analysis to be carried out on each invading tumoroid at each timepoint.
Table 3. Image Z-projection parameters.
Tumoroid Invasion Analysis
Primary mask cellular analysis criteria (Table 4) were applied using the brightfield channel to automatically place object masks around the entire invading structure in each final image. Secondary mask cellular analysis criteria (Table 5) were also applied to place an additional mask around non-invasive cells remaining within the original spherical tumoroid structure.
Table 4. Primary mask analysis parameters.
Table 5. Secondary mask analysis parameters.
Results and Discussion
Raw Image Processing Prior to Cellular Analysis
During the seven-day incubation period, uninhibited U-87/fibroblast tumoroids continued to increase in size, as well as invade into the protein matrix. To ensure that the entire invading structure, including invadopodia, was captured in the x- and y-axes, regardless of size, multiple images were taken on a single z-plane in a montage format (Table 1). Figure 1 illustrates four of the six images that were captured containing portions of the invading structure.
Figure 1. U-87/fibroblast 4x brightfield imaging showing (A-D) four image tiles containing the invading tumoroid of interest.
As invasion proceeds, proteins and cells invade on multiple planes within the z-axis. Therefore, images were automatically taken across a range of z-heights so that all portions of the overall structure were in focus in the final z-projected images (Figure 2 A-D).
Figure 2. U-87/fibroblast 4x brightfield imaging showing (A-D) four of the twenty images captured at multiple z-planes as part of the z-stack and combined into the final z-projection.
Imaging of U-87/Fibroblast Individual Co-Cultured Cell Types
In addition to brightfield imaging, montage tiles and z-stacked layers were also captured using the GFP and RFP channels. Overlaying images tracks invasion of the entire structure (Figure 3).
Figure 3. Brightfield and fluorescent overlaid z-projected image of U-87/fibroblast co-cultured cell model.
By viewing the fluorescent signal emitted by each cocultured cell type, in comparison to the brightfield signal from the entire structure, individual cell migration can be observed. In the case of the U-87/fibroblast model, the brightfield image demonstrates extensive invadopodia extending out from the original propagating tumoroid (Figure 4A). From the GFP image in Figure 4B, it is evident that GFP-expressing U-87 cells follow invadopodia invasion into the matrix. This contrasts to the RFP image in Figure 4C confirming that RFP-expressing fibroblasts exhibit little to no migratory ability within this experimental model.
Figure 4. Confirmation of invasion by individual cell types. (A) total tumoroid invasion via overlaid GFP, RFP and brightfield channels. Individual cellular invasion by (B) GFP-expressing U-87 cells; or (C) RFP-expressing fibroblast cells. Digitally zoomed 4x images, 2x3 montage, 20-plane z-stack.
Kinetic Image Capture
Finally, z-projected images are captured kinetically every 12 hours to observe phenotypic changes in the U-87/ fibroblast co-cultured tumoroids following treatment with varying concentrations of 17-AAG. Uninhibited tumoroids, as expected, demonstrate a highly invasive nature4, exhibiting an increase in the size of the tumoroid body as well as a dramatic increase in invadopodia (Figure 5).
LN-229/Fibroblast Tumoroid Analysis
LN-229/fibroblast tumoroid imaging was also conducted in the same manner as that for the U-87/fibroblast tumoroids. This was done to compare differences in growth and invadopodia production between GBM cell types known to be highly invasive (U-87) and those with less invasive ability (LN-229)5. Changes in the complete 3D structure were observed using the overlaid brightfield and fluorescent images (Figure 6A), while individual LN-229 or fibroblast invasion were monitored by signal captured with the individual CY5 or RFP channels, respectively (Figure 6B and C).
Figure 6. Imaging of LN-229/fibroblast co-cultured cell model. (A) Total tumoroid invasion via overlaid CY5, RFP and brightfield channels. Individual cellular invasion by (B) CellTracker Deep Red stained LN- 229 cells; or (C) RFP-expressing fibroblast cells. Digitally zoomed 4x images, 2x3 montage, 20-plane z-stack.
When comparing kinetic brightfield images from the two co-cultured cell types, it is evident that LN-229/fibroblast tumoroids propagate over time, as seen by the increase in spheroid size (Figure 7), but do not exhibit the invasive properties clearly demonstrated by U-87/fibroblast tumoroids over the same incubation period (Figure 5).
Figure 7. LN-229/fibroblast tumoroid invasive potential over time, 4x brightfield images, 2x3 montage, 20-plane z-stack. (A) 0 hours; (B) 48 hours; (C) 120 hours; (D) 168 hours.
Gen5 Image+ Based Cellular Analysis of Tumoroid Invasion
In addition to qualitative assessments of tumoroid phenotypic changes, quantification of the extent of invasion was also carried out using the stitched, z-projected brightfield images. Two separate cellular analyses were performed following treatment with the 17-AAG titration. In the first, the primary cellular analysis capabilities available in Gen5 Image+, and the criteria listed in Table 4 used changes in brightfield signal within the image between cellular containing pixels and background to place detailed object masks around the complete invading 3D structure, despite the level of compound treatment (Figure 8).
Figure 8. Invading tumoroid object masking. Zoomed 4x brightfield images of U-87/fibroblast tumoroids, 2x3 montage, 20-plane z-stack. (A) 0 μM 17-AAG treatment; and (B) 10 μM 17-AAG treatment. Primary masks around cells and invadopodia.
The area covered by the entire tumoroid for each captured image over time was then calculated. Values from subsequent time points were then divided by the area value calculated at time 0 for the specific tumoroid to normalize results and account for variability in tumoroid size following cell dispensing and aggregation. Area ratios were then plotted (y-axis) with regards to time (x-axis) (Figure 9).
Figure 9. Kinetic total tumoroid area ratios. Area ratios plotted for (A) U-87/fibroblast tumoroids, or (B) LN-229/ fibroblast tumoroids following 0-7 day treatments with 17- AAG concentrations ranging from 10,000 to 0 nM. Area ratio calculated by the following formula: (AreaTime T/AreaTime 0).
From the results seen in Figure 9, it is apparent that both U-87/fibroblast and LN-229/fibroblast tumoroids propagate within the Matrigel matrix when unimpeded over the seven-day incubation period. It can also be seen that the compound 17-AAG is able to limit, or even completely stop, tumoroid growth in a dose dependent manner, as expected3. What is also clear from the total area ratio graphs is the increased rate of growth for the complete 3D structure exhibited by U-87/fibroblast tumoroids compared to those where LN-229 cells are cocultured with fibroblasts. Increases in the area covered by the entire tumoroid are approximately 2x over time for tumoroids cultured with U-87 cells (ratio: 4.4) compared to those cultured with LN-229 cells (ratio: 2.4).
Gen5 Image Prime Based Cellular Analysis of Tumoroid Invasion
A second cellular analysis was also performed using the primary and secondary cellular analysis capabilities available in Gen5 Image Prime, and the criteria listed in Table 5, to measure the area solely covered by noninvading cells within the tumoroid. In order to determine the metastatic ability of 3D in vitro models, both uninhibited or following treatment, it is important to be able to distinguish between area covered by cells within the original tumoroid and that covered by invadopodia. As the more densely packed non-invasive, propagating cells appear darker compared to invadopodia in a brightfield image (Figure 10A), this additional change in signal within the original mask allows placement of a secondary mask to exclude the invading areas of each tumoroid and separate the area covered by the two portions of the entire 3D structure (Figure 10).
Figure 10. Invading and main tumoroid area object masking. Zoomed 4x brightfield 2x3 montage, 20-plane z-stack images of (A) uninhibited U-87/fibroblast tumoroids; or (B) uninhibited LN-229/fibroblast tumoroids. Exterior primary masks around cells and invadopodia, and interior secondary masks around non-invading cellular structure only.
By applying the secondary mask around non-invading portions of the tumoroid, differences in the invasive qualities of the two GBM cell types then becomes clear.
Figure 11. Kinetic uninhibited U-87 and LN-229 co-cultured tumoroid kinetic invadopodia areas. Calculated invadopodia area over time for non-treated U-87/fibroblast and LN-229/ fibroblast tumoroids. Invadopodia area calculated by the following formula: (Total AreaTime T – Non-Invading AreaTime T).
The area covered by invadopodia for U-87/fibroblast tumoroids increases dramatically over the seven day incubation period. LN-229/fibroblast tumoroids, by comparison, show little increase in invadopodia over the same time (Figure 11). This dual analysis, therefore, has the potential to determine not only how rapidly tumoroid cells are propagating, but also the invasive nature of the cell model.
Application of advanced cellular imaging capabilities, such as taking multiple images on a single z-plane as well as in a z-stack, allows all portions of an invading 3D cellular tumoroid structure to be captured in focus. When stitched and projected to a final image, accurate analysis can then be performed. The ability to view entire tumoroids via brightfield imaging, as well as individual cell types through fluorescent imaging, also allows for determination of the invasive properties of each co-cultured cell type within the included cell model. Inclusion of label-free cellular analysis, carried out on brightfield images, can then quantify not only propagative qualities, but also the specific invasive nature of in vitro 3D cell models when uninhibited and in response to test molecules.
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