实验概要

Directed  differentiation of specific lineages has been a focal point in the  field of human embryonic stem cell (hESC) research. Cell replacement  therapy using hESCs have the potential for treating Parkinson’s disease  and other neurodegenerative disorders. This chapter describes the  procedure for the derivation of dopaminergic (DA) neurons from hESCs.

主要试剂

Dulbecco’s Phosphate-Buffered Saline (D-PBS) without Ca² and Mg²

D-MEM/F-12 with GlutaMAX™-I

Neurobasal® Medium

Knockout™ Serum Replacement

10% Bovine Serum Albumin (BSA)

Fetal Bovine Serum (FBS)

Dulbecco’s Modified Eagle Medium (D-MEM)

Non-essential Amino Acids Solution (NEAA)

B-27® Supplement without Vitamin A

N-2 supplement

β-Mercaptoethanol

Attachment Factor

Natural Mouse Laminin

StemPro® Accutase® Cell Dissociation Reagent

Recombinant Human FGF Basic (bFGF)

FGF-8b Recombinant Human

B-DNF Recombinant Human

G-DNF Recombinant Human

Trypan Blue Stain

Distilled water

Poly-L-Ornithine

Heparin

Ascorbic Acid

Dibutyryl cyclic-AMP (dcAMP)

Recombinant human sonic hedgehog (SHH)

主要设备

StemPro^® EZPassage™ Disposable Stem Cell Passaging Tool

Cell scraper

实验材料

GIBCO^® Mouse Embryonic Fibroblasts (MEF), irradiated

Human embryonic stem cells (hESC)

实验步骤

 1. Preparing MEF Culture Vessels

1) Thawing MEFs

       a. Wearing  eye protection and ultra low-temperature cryo-gloves, remove the vials  of irradiated MEF from the liquid nitrogen storage tank using metal  forceps. Note: Transfer the vials into a container with a small amount  of liquid nitrogen if the vials are exposed to ambient temperature for  more than 15 seconds between removal and step 3.

        b. Briefly roll the vials containing MEF between your hands for about  10–15 seconds to remove frost and swirl them gently in a 37°C water  bath. Do not submerge the vials completely.

        c. When only a small amount of ice remains in the vials, remove them  from the water bath. Spray the outside of the vials with 70% ethanol  before placing them in the cell culture hood.

       d. Pipet the thawed cells gently into a 15-mL conical tube using a 1-mL pipette.

        e. Rinse the cryovial with 1 mL of pre-warmed MEF medium. Transfer the  medium to the same 15-mL tube containing the cells.

        f. Add 4 mL of pre-warmed MEF medium dropwise to the cells. Gently mix  by pipetting up and down. Note: Adding the medium slowly helps cells to  avoid osmotic shock.

      g. Centrifuge the cells at 200 × g for 5 minutes.

      h. Aspirate the supernatant and resuspend the cell pellet in 5 mL of pre-warmed MEF medium.

       i. Remove 10 μL of cell suspension and determine the viable cell count using your method of choice.

2) Plating MEFs

       a. Centrifuge the MEFs at 200 × g for 5 minutes and aspirate the supernatant.

       b. Resuspend the cell pellet in MEF medium to a concentration of 2.5 × 10⁶ cells/mL.

       c. Aspirate the Attachment Factor solution from the coated culture vessels and wash the plates once with D-PBS.

        d. Add the appropriate amount of MEF medium into each culture vessel  (2.5 mL into each well of 6-well plate, 5 mL into each 60-mm dish, or 10  mL into each 100-mm dish).

        e. Into each of these culture vessels, add the appropriate amount of  MEF suspension (0.1 mL into each well of 6-well plate, 0.2 mL into each  60-mm dish, or 0.6 mL into each 100-mm dish). The recommended plating  density for GIBCO® Mouse Embryonic Fibroblasts (Irradiated) is 2.5 × 10⁴ cells/cm².

        f. Move the culture vessels in several quick back-and-forth and  side-to-side motions to disperse cells across the surface of the wells  and dishes. After plating the cells, place the vessels in a 37°C  incubator with a humidified atmosphere of 5% CO₂. Use the MEF plates and dishes within 3–4 days of plating.

2. Thawing and Plating hESCs

1)  Wearing eye protection and ultra low-temperature cryo-gloves, remove a  vial of hESCs from the liquid nitrogen storage tank using metal forceps.

2) Immerse the vial in a 37°C water bath without submerging the cap. Swirl the vial gently.

3) When  only a small amount of ice remains in the vial, remove it from the  water bath. Spray the outside of the vial with 70% ethanol before  placing it in the cell culture hood.

4) Transfer  the cells gently into a sterile 15-mL conical tube using a 1-mL  pipette. Rinse the vial with 1 mL of pre-warmed hESC medium to collect  the remaining cells in the vial and add them dropwise to the cells in  the 15-mL conical tube. Note: Adding the medium slowly helps cells to  avoid osmotic shock.

5) Add  4 mL of pre-warmed hESC medium dropwise to the cells in the 15-mL  conical tube. While adding the medium, gently move the tube back and  forth to mix hESCs.

6) Centrifuge the cells for 5 minutes at 200 × g.

7) Aspirate the supernatant and resuspend the cell pellet in 5 mL of pre-warmed hESC medium.

8) Label  the culture vessel containing inactivated MEFs with the passage number  of the hESCs from the vial, the date and your initials.

9) Aspirate the MEF medium from the culture vessel containing the MEFs and gently add the resuspended hESCs into the vessel.

10) Move  the culture vessel in several quick back-and-forth and side-to-side  motions to disperse the cells across the surface of the vessel. Place  the vessel gently into a 37°C incubator with a humidified atmosphere of  5% CO₂.

11)  Replace the spent medium and examine the cells under a microscope  daily. If feeding cells in more than one vessel, use a different pipette  for each vessel to reduce the risk of contamination. Note:  hESC  colonies may not be visible in the first several days.

12) Observe  the hESCs every day and passage the cells whenever the colonies are too  big or too crowded. The ratio of splitting depends on the total number  of hESC in the culture vessel (approximately 1:2 to 1:4 for hESCs at the  first time of recovery).

3. Passaging hESCs

1) Two days prior to passaging your hESC culture, prepare fresh MEF culture vessels.

2)  Remove the culture vessel containing hESCs from the incubator. Mark  differentiated colonies under a microscope using a microscopy marker and  remove them by aspirating with a Pasteur pipette in the culture hood.

3)  Add an appropriate amount of pre-warmed hESC medium into each culture  vessel (2 mL for each 60-mm dish or 4 mL for each 100-mm dish).

4) Roll  the StemPro® EZPassage™ Disposable Stem Cell Passaging Tool across the  entire vessel in one direction (left to right). Rotate the culture  vessel 90 degrees and roll the tool across the entire dish again.

5) Using  a cell scraper, gently detach the cells off the surface of the culture  vessel. Gently transfer the cell clumps into a 15- or 50-mL conical tube  using a 5-mL pipette.

6) Rinse  the culture vessel with an appropriate amount of pre-warmed hESC medium  (1 mL for each 60-mm dish or 2 mL for each 100-mm dish) to collect  remaining cells.

7) If  some cell clumps are too big, pipet the cell solution up and down  several times using a 5-mL pipette to break the cell clumps into smaller  pieces.

8) Aspirate  the MEF medium from each MEF culture vessel and replace it with an  appropriate amount of pre-warmed hESC medium (5 mL for each 60-mm dish  or 10 mL for each 100-mm dish).

9) Gently  shake the conical tube containing the hESCs to distribute the cell  clumps evenly and add an appropriate amount of hESC suspension into each  MEF culture vessel. Note: The volume of hESC suspension added into each  dish depends on the ratio of splitting (see General Guidelines, above).

10) Move  the culture vessels in several quick back-and-forth and side-to-side  motions to disperse the hESCs across the surface of the vessels. Place  the culture vessels gently in a 37°C incubator with a humidified  atmosphere of 5% CO₂.

11) Replace the spent medium daily. hESCs need to be split every 4–10 days based upon their appearance.

4. Differentiating hESCs

1) Making Embryoid Bodies (EBs)

       a. Culture the hESCs on MEF feeder cells until they are 90–100% confluent.

        b. Roll the StemPro® EZPassage™ Disposable Stem Cell Passaging Tool  across the entire vessel in one direction (left to right). Rotate the  culture vessel 90 degrees and roll the tool across the entire dish  again.

        c. Using a cell scraper, gently detach the cells off the surface of the  culture vessel. Gently transfer the cell clumps into a 50-mL conical  tube using a 5-mL pipette. Note: Do not break the cells clumps into  smaller pieces.

        d. Add 1 mL of pre-warmed hESC EB medium into each well of 6-well  plate, 2 mL into each 60-mm dish, or 3 mL into each 100-mm dish to  collect remaining cells and add them to the 50-mL conical tube  containing the hESC.

       e. Centrifuge the cells for 5 minutes at 200 × g.

        f. Aspirate the supernatant from the hESC pellet. Gently re-suspend the  pellet with an appropriate amount of EB medium (15 mL for all the cells  from one 60-mm dish or 40 mL for all cells from one 100-mm dish).

        g. Transfer the cell clumps to an uncoated T-75 flask for a couple of  hours. This allows the fibroblasts to differentially attach to the  flask.

        h. After a few hours, set the T-75 flask down at a tilted angle to  allow the EBs to settle in one corner of the flask. Aspirate the EB  medium and replace it with 40 mL of fresh EB medium. Transfer the cell  clumps to a fresh T-75 flask and incubate them in a 37°C incubator with a  humidified atmosphere of 5% CO₂.

        i. Feed the EBs with EB medium every day for 4 days. When feeding, set  the flask down at a tilted angle so that the EBs settle in one corner of  the flask. Aspirate almost all spent EB medium, replace it with  pre-warmed EB medium, and return flask to the incubator. Note:   Due to  DNA release form dead cells, cell clumps may stick together. In this  case, gently pipet the EBs up and down 2–3 times using a 5-mL pipette.  This will help you clean the dead cells off the EB surface. If the EBs  attach to flask, use a 5-mL pipette to blow the attached EBs off the  bottom of the flask.

2) Differentiating EBs (Rosette Formation) and Midbrain Specification

       a. After  culturing the EBs in EB medium for 4 days, transfer the EBs from one  T-75 flask into a 50-mL centrifuge tube and centrifuge for 3 minutes at  200 × g.

       b. Aspirate the EB medium and resuspend the EBs in 10 mL of pre-warmed neural induction medium.

       c. Centrifuge the EBs for 3 minutes at 200 × g.

        d. Aspirate the supernatant and resuspend the EBs in 40 mL of  pre-warmed neural induction medium. Transfer the EBs into a fresh T-75  flask and incubate the EBs in neural induction medium for 2 days in a  37°C incubator with a humidified atmosphere of 5% CO₂. After  the EBs float in the neural induction medium for 2 days, they are ready  to be differentiated. Note: If the EB attach to the flask, use a 5-mL  pipette to blow the attached EBs off the bottom of the flask.

        e. Dilute laminin in D-PBS to 20 μg/mL and coat ten 100-mm culture  dishes using 2.5–3 mL of laminin for each dish. Incubate the  laminin-coated culture dishes in a 37°C incubator for several hours.  Note: Laminin may form a gel when thawed too rapidly. To avoid this,  thaw slowly in the cold (2°C–8°C). Once thawed, aliquot into  polypropylene tubes and store at –5°C to –20°C. Do not freeze and thaw  laminin repeatedly.

       f. After incubation, aspirate the laminin and add 10 mL of pre-warmed neural induction medium into each 100 mm dish.

      g. Transfer the EBs from the T-75 flask into a 50-mL tube and centrifuge for 3 minutes at 200 × g.

      h. Aspirate the supernatant and resuspend the EBs in 10 mL of pre-warmed neural induction medium.

        i. Gently shake the 50-mL tube containing EBs to distribute the EBs  evenly and add 1 mL of EB suspension into each laminin-coated culture  dish.

        j. Move the culture dishes in several quick back-and-forth and  side-to-side motions to disperse the EBs across the surface of the  dishes. Place the dishes gently in a 37°C incubator with a humidified  atmosphere of 5% CO₂.

       k. Feed the EBs every other day with fresh pre-warmed neural induction  medium until early rosettes form (approximately 2–3 days).

        l. To direct the neural precursors to the midbrain fate, feed the  differentiating EBs every other day with neural induction medium  containing 100 ng/mL FGF-8b and 200 ng/mL sonic hedgehog (SHH) for 5–6  days. Note: Plate the EBs at a density of 200–250 per one 100-mm dish.  Generally, all EBs from hESCs cultured in one 100-mm dish can be plated  into eight to ten 100-mm dishes. The variation is from the confluence of  hESCs and efficacy of EB formation

3) Isolating DA Progenitors

       a. Label all differentiating colonies containing rosettes using a microscope marker.

       b. Using a 200-μL pipette tip pointing to the center of each marked colony, blow off the cells in rosettes.

        c. Use a 10-mL pipette to transfer the detached cell clumps into a  50-mL centrifuge tube. Note: You can combine the cell clumps from five  100-mm dishes into one 50-mL tube.

       d. Centrifuge the cells for 3 minutes at 200 × g.

        e. Aspirate the supernatant and resuspend the cell clumps in 40 mL of  neural expansion medium containing 100 ng/mL FGF-8b and 200 ng/mL SHH.

       f. Transfer the cell clumps to a T-75 flask and place the flask in a 37°C incubator with a humidified atmosphere of 5% CO₂. The rosettes will roll up to form neurospheres after about 1 day in the incubator.

       g. Replace half of the neural expansion medium containing 100 ng/mL  FGF-8b and 200 ng/mL SHH with fresh medium every other day.

4) DA Neuron Differentiation

         a. Coat the surface of the culture vessel (with or without cover slips)  with poly-L-ornithine working solution at 20 μg/mL in distilled water  (14 mL for T-75, 7 mL for T-25, 3.5 mL for 60-mm dish, 2 mL for 35-mm  dish) and incubate the vessel overnight at room temperature.

         b. Wash the poly-L-ornithine-coated vessel 4 times with distilled  water, and then coat it with laminin working solution at 10 μg/mL in  D-PBS without calcium or magnesium (14 mL for T-75, 7 mL for T-25, 3.5  mL for 60-mm dish, 2 mL for 35-mm dish). Incubate the culture vessel for  3 hours at 37°C.  Note: You may coat the culture vessels in advance,  replace the laminin solution with D-PBS without calcium or magnesium,  and store them wrapped tightly in Parafilm for up to 1 week. Make sure  that the culture vessels do not dry out.

         c. After the neurospheres float in neural expansion medium for 6–8  days, transfer them into a 15-mL tube and centrifuge for 5 minutes at  200 × g.

         d. Aspirate the supernatant and incubate the neurospheres in pre-warmed  StemPro® Accutase® Cell Dissociation Reagent for 10 minutes at 37°C.

        e. Gently pipet the cell clumps up and down to break the larger clumps into a single cell suspension.

        f. Centrifuge the cells for 5 minutes at 200 × g and aspirate the supernatant.

       g. Resuspend the cells in 10 mL of pre-warmed neural differentiation medium.

       h. Repeat steps 6 and 7.

       i. Aspirate the laminin from the coated culture vessels and plate the dissociated DA progenitors.

       j. Incubate the cells in a 37°C incubator with a humidified atmosphere of 5% CO₂ and replace the spent medium with fresh neural differentiation medium every other day.

      k. You can evaluate DA neuron differentiation 3–4 weeks after plating.