In vitro Cell Migration and Invasion Assays

Podsumowanie

Commonly used, highly accessible methods for examining cell migration and invasion in vitro are described. The first method is the cell wound closure assay that measures cell motility. The second method is the transwell migration and invasion assay that assesses the chemotactic and invasive capacity of cells.

Streszczenie

Migration is a key property of live cells and critical for normal development, immune response, and disease processes such as cancer metastasis and inflammation. Methods to examine cell migration are very useful and important for a wide range of biomedical research such as cancer biology, immunology, vascular biology, cell biology and developmental biology. Here we use tumor cell migration and invasion as an example and describe two related assays to illustrate the commonly used, easily accessible methods to measure these processes. The first method is the cell culture wound closure assay in which a scratch is generated on a confluent cell monolayer. The speed of wound closure and cell migration can be quantified by taking snapshot pictures with a regular inverted microscope at several time intervals. More detailed cell migratory behavior can be documented using the time-lapse microscopy system. The second method described in this paper is the transwell cell migration and invasion assay that measures the capacity of cell motility and invasiveness toward a chemo-attractant gradient. It is our goal to describe these methods in a highly accessible manner so that the procedures can be successfully performed in research laboratories even just with basic cell biology setup.

Wprowadzenie

Motility is an essential feature of live cells. Cell migration is involved in the conception of life, embryonic development, immune response, and many pathological processes such as cancer metastasis and inflammation^1-9. Therefore, methods to study cell migratory behavior are very useful research tools for a wide range of disciplines in biomedical sciences, biology, bioengineering, and related fields.

The study of cell migration in cancer research is of particular interest as the main cause of death in cancer patients is related to metastatic progression. In order for cancer to spread and disseminate throughout the body, cancer cells must migrate and invade through extracellular matrix (ECM), intravasate into blood circulation, attach to a distant site, and finally extravasate to form distant foci^1,10-12. Various biological methods may be employed to study these events in detail. The cell culture wound-closure and the transwell migration and invasion assays are widely used in the scientific community^1,10. These tests can provide the necessary data that may allow for an understanding of how well a particular cell type can spontaneously migrate or respond to a chemo-attractant and directionally migrate toward it. Several migratory phenotypes have been described. Cells may migrate in a single cell form such as seen in mesenchymal or amoeboid-like movement or by multicellular movement labeled collective migration or cell streaming¹³. The method of movement used in motile cells can be readily observed using the cell culture wound closure assay.

Among the numerous ways to study cell migration, the cell wound closure assay is one of the simplest. This method is useful to determine the migration ability of whole cell masses. When taken a step further it can be used to observe individual cell’s morphological characteristics during migration¹⁴. Following the analysis of the wound closure many phenotypes may be revealed. Measuring the closed distance over time when comparing to a control may reveal specific migration changes or an impaired migratory phenotype that was unknown previously. Furthermore, single cell lamellipodium formation, tail retraction, and directional movement may give clues for what may be impaired or enhanced in the cells of interest¹⁴.

The transwell migration and invasion assays may be used to analyze the ability of single cells to directionally respond to various chemo-attractants whether they are chemokines, growth factors, lipids, or nucleotides^4,5,8,15,16. It may also assess differential migratory ability due to the over-expression of a receptor^1,14. These assays can also be used to identify and characterize the key regulators of cell migration such as the Rho family of small GTPases². Following these short and easily accessible tests, the mode of cell migration and the ability of a cell to invade into a 3-D matrix may also be determined.

Protokół

1. Cell Culture Wound Closure Assay

1. Detach cells from the tissue culture plate using 0.25% Trypsin-EDTA solution. Pellet cells in a 15 ml conical tube by centrifugation, aspirate the supernatant, and re-suspend cells in culture media. Plate the appropriate number of cells in a 6-well plate for 100% confluence in 24 hours.
   Note: Tests may be needed to determine the time and number of cells to achieve 100% confluence due to the cell type and the size of the well being used (for example, 1 x 10⁶ B16F10 melanoma cells are seeded in a well of a 6-well plate 24 hours prior to the wound generation). Alternatively, 12-well or 24-well plates may be used.
   Note: If available, cells can be seeded into a Culture-Insert (from ibidi LLC) on a treated tissue culture plate making the wound pre-casted. A Culture-Insert can protect the surface of the tissue culture plate from damage by the pipette tip. If a Culture-Insert is used omit step 1.2.
2. In a sterile environment (typically a biosafety hood) use a 200 μl pipette tip to press firmly against the top of the tissue culture plate and swiftly make a vertical wound down through the cell monolayer. A different sized pipette tip may be used to make the wound size that is desired. Do not use excessive force against the tissue culture plate with the pipette tip as it may damage the surface. If the wound is pre-casted, this step may be omitted.
3. Carefully aspirate the media and cell debris. Slowly add enough culture media against the well wall to cover the bottom of the well and avoid detaching additional cells. Following the generation and inspection of the wound an initial picture should be taken. Place the tissue culture plate in an incubator set at the appropriate temperature and CO₂ concentration (typically 37 °C and 5% CO₂).
4. At several time points, e.g. every 3 hours, remove the plate from the incubator and place it under an inverted microscope to take a snapshot picture and to check for wound closure. If time-lapse microscopy is available, take a photo every X number of minutes (typically starting with every 5 minutes) for any time duration in a temperature and CO₂ controlled chamber. Depending on the cell type, wound closure time may vary.
5. To analyze the results of snapshot pictures, measure the distance of one side of the wound to the other using a scale bar. Analyze and clearly present wound closure over time using a scatter plot or bar graph, e.g. Figure 1.
6. To analyze the time-lapse pictures, import the pictures into the ImageJ software(freely available at http://rsb.info.nih.gov/ij/) to make a video. To do this open ImageJ, click File, Import, and Image Sequence. Find the file with pictures; click the first photo in the file. Save video by selecting File, Save as, and AVI. Single migrating cells may be observed to characterize directional movement. Furthermore, morphological characteristics such as lamellipodia formation and trailing edge retraction may be studied as well (Figure 2 and supplementary video).

2. Transwell Cell Migration and Invasion Assay

1. In a sterile environment (typically a biosafety hood) detach cells from the tissue culture plate using a non-enzymatic cell disassociation buffer or 0.25% Trypsin-EDTA solution, pellet cells by centrifugation, and aspirate the existing media leaving the pelleted cells. Re-suspend cells in serum free cell culture media containing 0.1% BSA (bovine serum albumin).
   Note: Depending on the cell line being investigated 0.25% Trypsin-EDTA may affect cell migration and invasion due to the cleavage of various receptors on the cell surface¹⁷.
   Note: The number of cells per ml depends on the size of the cells. Further tests may be needed to find a seeding density that provides the best results. Typically 1 x 10⁶ cells/ml is a good starting point for most cell types when using the 24-well transwell insert. There is a range of transwell insert sizes and the number of cells added should be adjusted for accordingly.
2. Plate 100 μl of cell solution on top of the filter membrane in a transwell insert and incubate for 10 minutes at 37 °C and 5% CO₂ to allow the cells to settle down.
   Note: The particular pore size of the transwell membrane used is dependent on the individual size of the cells in the sample. For example, if the cells are too small they may pass through the pores without the need to facilitate migration or if they are too large they may not fit through the pores. There are several transwell inserts with pore sizes that range from 3 µm, 5 µm, and 8 µm for cell migration assays. The transwell inserts are commercially available from companies such as Corning.
   Note: The transwell migration assay can be easily modified to perform the cell invasion assay. To do this, add extracellular matrix (ECM) materials on top of the transwell membrane and then add cells on top of the ECM. For example, Matrigel is thawed and liquefied on ice, and then 30-50 µl of Matrigel is added to a 24-well transwell insert and solidified in a 37 °C incubator for 15-30 minutes to form a thin gel layer. Cell solution is added on top of the Matrigel coating to simulate invasion through the extracellular matrix.
   Note: There are distinct differences between the transwell cell migration and the transwell cell invasion assays. The transwell cell migration assay measures the chemotactic capability of cells toward a chemo-attractant. The transwell cell invasion assay, however, measures both cell chemotaxis and the invasion of cells through extracellular matrix, a process that is commonly found in cancer metastasis or embryonic development.
3. Using a pipette, very carefully add 600 μl of the desired chemo-attractant into the bottom of the lower chamber in a 24-well plate. Add the chemo-attractant without moving the transwell insert and avoid generating bubbles. Make sure the chemo-attractant liquid in the bottom well makes contact with the membrane in the upper well to form a chemotactic gradient. Incubation time is dependent on cell type and the chemo-attractant being used.
   Note: Further tests may be needed to determine the incubation period.
   Note: For adherent cells, the migrated cells will attach to the other side of the membrane^1,8. The quantification of migrated cells can be performed following steps 2.4 to 2.8 (steps 2.4-2.8 do not need to be performed in a sterile environment). For non-adherent cells, the migrated cells will drop into the media in the lower chamber. The number of migrated cells can be counted by using hemocytometer or flow cytometer⁵.
4. Remove the transwell insert from the plate. Use a cotton-tipped applicator as many times as needed to carefully remove the media and remaining cells that have not migrated from the top of the membrane without damaging it.
5. Add 600-1,000 μl of 70% ethanol into a well of a 24-well plate. Place the transwell insert into the 70% ethanol for 10 minutes to allow cell fixation. Remove transwell insert from the 24-well plate and use a cotton-tipped applicator to remove the remaining ethanol from the top of the membrane. Allow the transwell membrane to dry (typically 10-15 minutes).
6. Add 600-1,000 μl of 0.2% crystal violet into a well of a 24-well plate and position the membrane into it for staining. Incubate at room temperature for 5-10 minutes.
7. Gently remove the crystal violet from the top of the membrane with a pipette tip or cotton tipped applicator. Very carefully, to avoid washing off fixed cells, dip the membrane into distilled water as many times as needed to remove the excess crystal violet. Allow the transwell membrane to dry.
8. View underneath an inverted microscope and count the number of cells in different fields of view to get an average sum of cells that have migrated through the membrane toward the chemo-attractant and attached on the underside of the membrane (Figure 3).

Wyniki

The wound closure assay and the transwell cell migration assay presented here were performed using mouse B16F10 melanoma cells as a model system. In the wound closure assay, B16F10 cells were seeded in a 6-well tissue culture plate and grown to 100% confluence in 24 hours. A wound of approximately 700 µm wide was generated using a pipette tip and the wound closure (cell migration) was recorded using the time-lapse microscopy. Alternatively, wound closure can also be studied by taking snapshot pictures at different t...

Dyskusje

Cell migration is an important aspect to study in cancer research and it can also be applied to developmental, immunological and wound healing studies. The cell culture wound closure assay and the transwell cell migration and invasion assays reveal detailed information of cell migratory behaviors and can be used to investigate the molecular mechanisms of cell migration^1,2,10,14. Our study used these cell motility assays to determine the migration velocity and invasion capabilities of a B16F10 melanoma cell lin...

Materiały

Name	Company	Catalog Number	Comments
Dulbecco’s modified Eagle medium (DMEM)	Gibco	11995-073
Fetal bovine serum (FBS)	Gemini	100106
Bovine serum albumin (BSA)	Sigma-Aldrich	A4503-50G
Trypsin EDTA 0.25%	Gibco	25200-056
Dulbecco’s phosphate buffered saline (DPBS)	Gibco	14190-250
Crystal violet	Sigma	C0775-100G	Dissolved in water at 0.2%
Cell disassociation buffer	Gibco	13151-014
Cell culture incubator	Thermo Fisher Scientific		Model # 3145
SterilGARD biosafety hood	The Baker Company, Inc.		Model # VBM-600
EVOS Fl inverted microscope	Thermo Fisher Scientific		Model # AMF-4302-US
Tissue culture plate	Becton Dickinson	353046	Catalog number varies depending on the type of culture plate
Corning Transwell insert	Fisher	07-200-150	Catalog number varies depending on the pore size of the membrane