Characterization of the Effects of Migrastatic Inhibitors on 3D Tumor Spheroid Invasion by High-resolution Confocal Microscopy

Podsumowanie

The effects of migrastatic inhibitors on glioma cancer cell migration in three-dimensional (3D) invasion assays using a histone deacetylase (HDAC) inhibitor are characterized by high-resolution confocal microscopy.

Streszczenie

Drug discovery and development in cancer research is increasingly being based on drug screens in a 3D format. Novel inhibitors targeting the migratory and invasive potential of cancer cells, and consequently the metastatic spread of disease, are being discovered and considered as complementary treatments in highly invasive cancers such as gliomas. Thus, generating data enabling the detailed analyses of cells in a 3D environment following the addition of a drug is required. The methodology described here, combining spheroid invasion assays with high-resolution image capture and data analysis by confocal laser scanning microscopy (CLSM), enabled detailed characterization of the effects of the potential anti-migratory inhibitor MI-192 on glioma cells. Spheroids were generated from cell lines for invasion assays in low adherent 96-well plates and then prepared for CLSM analysis. The described workflow was preferred over other commonly used spheroid-generating techniques due to both ease and reproducibility. This, combined with the enhanced image resolution attained by confocal microscopy compared to conventional wide-field approaches, allowed the identification and analysis of distinct morphological changes in migratory cells in a 3D environment following treatment with the migrastatic drug MI-192.

Wprowadzenie

Three dimensional spheroid technologies for preclinical drug discovery and the development of potential cancer drugs are increasingly being favored over conventional drug screens; thus, there is more development of migrastatic — migration and invasion preventing — drugs. The rationale behind these developments in cancer treatment are clear: 3D spheroid assays represent a more realistic approach for screening potential anti-cancer drugs as they mimic 3D tumor architecture more faithfully than cell monolayer cultures, recapitulate drug-tumor interactions (kinetics) more accurately, and allow the characterization of drug activity in a tumor-related setting. In addition, the rise of resistance to chemotoxic drugs in many cancer types and high death rates among cancer patients due to metastasis potentiated by the ability of cancer cells to migrate to distant tumor sites supports the inclusion of chemotherapeutic agents targeting the migratory potential of cancer cells as adjuvant treatment in future clinical cancer trials¹. This is particularly the case in highly invasive cancers, such as high-grade glioblastomas (GBM). GBM management includes surgery, radiotherapy, and chemotherapy. However, even with combination treatment, most patients relapse within 1 year of initial diagnosis with a median survival of 11-15 months^2,3. Huge advances in the field of 3D technology have been made over the last few years: rotative systems, microfabricated structures and 3D scaffolds, and other individual assays are being continually improved to allow routine testing on a large scale^4,5,6,7. However, results obtained from these assays must be analyzed in a meaningful manner because data interpretation is often hindered by attempts to analyze 3D-generated data with 2D image analysis systems.

Despite being preferable in terms of image acquisition speed and reduced photo-toxicity, most wide-field systems remain limited by resolution⁸. Thus, apart from data read-outs relating to drug efficacy, detailed effects of drug action on 3D cellular structures of migrating cells are inevitably lost if imaged using a wide-field system. Conversely, confocal laser scanning microscopy (CLSM) captures high quality, optically sectioned images that can be reconstructed and rendered in 3D post-acquisition using computer software. Thus, CLSM is readily applicable to imaging complex 3D cellular structures, thereby enabling interrogation of the effects of anti-migrastatic inhibitors on 3D structures and in-depth analyses of cell migration mechanisms. This will undoubtedly guide future migrastatic drug development. Here, a combined workflow of spheroid generation, drug treatment, staining protocol, and characterization by high-resolution confocal microscopy is described.

Protokół

1. Generation of Cell Spheroids

Day 1

1. Prepare the standard culture medium as required by the cell line under investigation.
2. Carry out all tissue culture-associated steps in a tissue culture hood using sterile handling techniques.
3. Trypsinize and count cancer cells. Use 20 mL of cell suspension per plate. Keep the cell suspensions in clearly labeled sterile universal tubes.
4. Add a predetermined number of cells to each well. Both the initial number of cells and ultimate spheroid size required depends upon the proliferation rate of the cell line being investigated.
   NOTE: For established glioma cell lines such as U251 and KNS42^9,10, 5 x 10³ cells/mL will produce a microscopically visible spheroid (200 or 800 µm) after 4 days of incubation.
5. Resuspend the cells in universal tubes by gentle inversion to avoid cell clumping. Pipette 200 µL of the cell suspension into each well of a 96-well plate. If all wells are not required, it is advisable to add 200 µL of 1x PBS to each empty well to avoid evaporation.
6. Incubate the cells in an incubator as normal at 37 °C.
   NOTE: Cell lines such as glioma cancer cell lines will form spheroids within 24 h. Allow 3D cellular architecture to form by incubating the spheroid for 72 h.

Day 2

7. Check cells by bright-field microscopy after 24 h. Depending upon the cell line, cells may have formed a spheroid detectable in the bottom of the well.
   NOTE: Established glioma cancer cell lines readily form spheroids within 24 h. Patient-derived glioma cancer cell lines may take up to 1-2 weeks.

2. Collagen Invasion Assay

Day 3

1. Place collagen, 5x culture medium, 1 M NaOH, and one 20 mL tube on ice.
2. Carefully and slowly add 10.4 mL of cold collagen into a chilled culture tube. Avoid bubbles. This quantity of collagen is enough for one 96-well plate. Upscaling is possible, but it is recommended that one 20 mL tube per plate is prepared at a time.
3. Gently add 1.52 mL of cold sterile 5x culture medium. Avoid bubbles.
4. Just before use, gently add 72 μL of cold sterile 1 M NaOH. Keep solution on ice.
5. Mix gently by pipetting. Avoid bubbles. Efficient mixing leads to a color change (from red to orange-red (pH 7.4) in the medium. Leave the mixture on ice until use.
6. Crucial step: Remove 190 μL of supernatant from the 96-well plate prepared on day 1. Be very careful not to disturb the spheroids that formed in the bottom of the well. Use the pipette at an angle towards the side, not the center, of the well.
7. Gently add 100 μL of the collagen mix to each well. To prevent any spheroid disturbance, pipette the mix down the side of the well. Avoid bubbles. Keep any remaining collagen mix in the 20 mL tube at room temperature to assess polymerization.
8. Incubate plate in the incubator for at least 10 min to allow the collagen to polymerize. As a guideline, if the leftover collagen has set, becoming semisolid and sponge-like, the spheroids are ready to be treated with inhibitor.
9. Add the drugs or inhibitors at 2x concentration to the culture medium. Add the medium gently to each well (100 µL per well). Again, pipette the medium down the side of the well to avoid spheroid disturbance.
10. Observe and image each spheroid by bright-field microscopy at times T = 0 h, 24 h, 48 h, and 72 h to assess drug activity. Then return the plate to the incubator.
    NOTE: Depending on the invasive behavior of the cell line, migration away from the original spheroid core may be observed from 24 h onwards.

3. Preparation of Collagen Embedded Spheroids and Migratory Cells for Confocal Microscopy

1. Place the plate in a tissue culture hood and gently remove the supernatant (200 µL). Again, take care not to disturb the spheroid and avoid touching the collagen, as this may interfere with the collagen plug.
2. Replace the supernatant with 100 µL of 1x PBS. Repeat this wash step 3x.
3. Remove the final wash and replace with 4% formaldehyde in 1x PBS (100 µL per well).
   CAUTION: Formaldehyde is a potential carcinogen. Handle with care in accordance with health and safety guidelines.
4. Place the 96-well plate on a lab bench, cover with foil, and leave for 24 h at room temperature.
5. Carefully remove the formaldehyde and replace with 1x PBS. Repeat this 1x PBS wash 3x.
6. Prepare 0.1% Triton X-100 in 1x PBS. Remove the 1x PBS wash and replace with 100 µL of the Triton X-100 solution. Incubate for 30 min at room temperature. In the meantime, prepare the blocking solution with 1x PBS and 0.05% skimmed milk powder and mix thoroughly.
7. Remove Triton X-100 and wash 3x with 1x PBS. Add 100 µL of blocking solution to each well and incubate for 15 min.
8. Dilute the required primary antibody in blocking buffer at the predetermined concentration. Here, use anti-mouse IgG acetylated tubulin antibody (1:100).
9. Centrifuge the primary antibody-blocking buffer mix for 5 min at 15,682 x g. Carefully remove the blocking solution and add the supernatant (25−50 µL) to each well. Incubate in the dark at room temperature for 1 h.
10. Remove the antibody solution and wash 3x with 1x PBS (100 µL per well).
11. Dilute the secondary antibody in the blocking buffer at the recommended or predetermined concentration in addition to any additional fluorescent stains. Here, use 1:500 anti-mouse fluorophore-488 conjugated antibody, phalloidin-594 (1:500) for actin staining, and the DNA stain (DAPI).
12. Again, centrifuge the secondary antibody solution for 5 min at 13,000 rpm.
13. Remove the blocking solution from each well and add 25−50 µL of the secondary antibody/phalloidin/DAPI mix. Incubate in the dark for 1.5 h at room temperature.
14. Remove secondary antibody-dye solution and wash 3x with 1x PBS (100 µL per well).
15. Carefully lift individual collagen plugs by suction with a plastic pipette (200 µL) onto the center of a high-quality plain glass slide.
16. Add one drop of a suitable mountant to the collagen plug, ensuring the plug is completely covered. Avoid bubbles.
17. Apply coverslip of the optimal thickness for the microscope objective that will be used for imaging and allow to set overnight. Store the slides at room temperature in the dark.

4. Fluorescence Microscopy

1. Capture fluorescent images using a suitable confocal microscope.

Wyniki

Three-dimensional spheroid technology is advancing the understanding of drug-tumor interactions because it is more representative of the cancer-specific environment. The generation of spheroids can be achieved in several ways; low adherence 96-well plates were used in this protocol. After testing several products from different manufacturers, the plates used here were chosen because they consistently performed best in terms of successful spheroid production and uniformity. The replacement...

Dyskusje

A novel way to create cancer cell spheroids for identification of migrastatic drug activity using high-resolution confocal microscopy is described. The use of low adherent plates over other techniques, such as hanging drops¹⁵, has facilitated a means of generating reproducible and uniform spheroids for use in the collagen migration and invasion assays. The critical points in this protocol are the removal of growth medium from the 96-well plate prior to the cell spheroid embedding in a collagen mat...

Materiały

Name	Company	Catalog Number	Comments
Collagen I, rat tail, 100 mg	Corning	354236	for glioma invasion assay; this is offered by many distributors/manufacturers and will need to be determined for both the type of assay intended and cell lines used. For glioma cancer cell lines Collagen rat tail type 1 (e.g. Corning) is the preferred choice. Collagen should be stored at 4 °C, in the dark, until required. It is not advisable to mix collagen from different batches as this may affect the consistency of the polymerized collagen.
Coverslips	various	various	for microscopy imaging
DMEM powder	Sigma	D5648	needed at 5x concentration for collagen solution for glioma invasion assay;  this may be purchased in powdered form, made up in double distilled water and, depending upon final composition of the growth medium, completed with any additives required. The complete 5x solution should be filtered through a syringe filter system (0.22 μm) before use.
Foetal calf serum	Sigma	F7524-500ML	needed for cell culture of glioma cell lines
Glass slides	various	various	for microscopy imaging
High glucose DMEM	Gibco	41965062	needed for cell culture of glioma cell lines
Inhibitor	Tocris	various	various - according to experimental design; inhibitors can be purchased from manufacturers such as Selleckchem and Tocris. These manufacturers offer detailed description of inhibitor characteristics, links to associated references and suggestion of working concentrations. As with all inhibitors, they may be potentially toxic and should be handled according to health and safety guidelines. Inhibitors are prepared as stock solutions as recommended by the manufacturer. As an example we used the migrastatic inhibitor MI-192 to demonstrate the use of such inhibitors. We have tested a range of migrastatic inhibitors in this way with comparable results.
Mountant	various	various	for microscopic imaging
NaOH (1 M)	various	various	NaOH can be either purchased at the required molarity or prepared from solid form. The prepared solution should be filter sterilized using a syringe filter system. One M NaOH is corrosive and care should be taken during solution preparation.
Paraformaldehyde	various	various	for fixing spheroids and cells; make up at 4%, caution health hazard, ensure that health and safety regulations are adhered to for collagen solution for invasion assay
Pastettes (graduated pipette, 3 mL)	various	various	for invasion assay, solution removal
PBS, sterile for tissue culture	Sigma	D1408-500ML	needed for cell culture of glioma cell lines and washes for staining
Pen/strep (antibiotics)	Sigma	P4333	needed for cell culture of glioma cell lines
Primary antibody, secondary antibody, DAPI, Phalloidin	various	various	there are many manufacturers for these reagents, for secondary labelled antibodies we recommend Alexa Fluor (Molecular Probes). Here we used for primary antibodies mouse anti-acetylated tubulin antibody (1/100, Abcam). For secondary antibodies we used 1/500 anti-mouse Alexa Fluor 488 conjugated antibody, Molecular Probes. For nuclear stain we used DAPI (many manufacturers) and the actin stain Phalloidin (many manufacturers) both used at recommended dilution of 1/500.
Sodium bicarbonate	Sigma	S5761	needed for collagen solution for glioma invasion assay at 5x concentration
Sodium pyruvate	Sigma	P5280	needed for collagen solution for glioma invasion assay at 5x concentration
Trypsin	Sigma	T4049	for trypsinisation
Ultra low attachment plates	Sigma/Nunc	CLS7007-24EA	for glioma invasion assay; a low adherent plate is required, with 96-well plates preferred to allow for large-scale screening of compounds under investigation. There are several low adherence plates commercially available; it is advisable to test a variety of plates for optimum spheroid generation. In our experience Costar Ultra Low Cluster with lid, round bottom, works best for the generation of spheroids from glioma cancer cells in terms of 100% spheroid formation and reproducibility. These plates were also successfully used for the generation of glioma spheroids from patient-derived material, bladder and ovarian cancer cells in our laboratory. In addition, stem or progenitor neurospheres can be used in these plates to facilitate the generation of standardized neurosphere-spheroids
Stripettes (serological pipettes, sterile, 5 mL and 10 mL)	various e.g. Costar	CLS4488-50; CLS4487-50	for tissue culture and collagen preparation
Various multichannel (50 - 250 μL) and single channel pipettes (10 μL, 50 μL, 200 μL 1 mL)	various	various	for cell and spheroid handling
Widefield microscopy	various	various	for observation of spheroid generation and spheroid imaging; here wide-field fluorescence images were captured using an EVOS FL cell imaging system (Thermo Fisher Scientific)
Zeiss LSM 880 CLSM equipped with a Plan Apochromat 63x 1.4 NA oil objective	Zeiss	quote from manufacturer	Confocal images were captured using a Zeiss LSM 880 CLSM equipped with a Plan Apochromat 63x 1.4 NA oil objective. Diode 405nm, 458/488/514 nm argon multiline and HeNe 594nm lasers were used to excite Phalloidin 594, Alexa Fluor 488, and DAPI respectively. For each image a single representative optical section were captured, with all settings, both pre- and post-image capture, maintained for comparative purposes. All images were subsequently processed using the associated Zen imaging software and Adobe Photoshop.