Differentiation of human Dopamine Neurons (DaNs) from induced pluripotent stem cells (iPSCs)

Day -2: Preparing plates for replating

Two days before intending on starting the differentiation (Day -2), add 1 mL/well in a 6-well plate of Geltrex one day prior to replating the iPSCs to begin the differentiation.

Day -1: Replating iPSCs for differentiation

Replating iPSCs for differentiation is identical to described in Protocol: Expansion and maintenance of human induced pluripotent stem cells (iPSCs), however, includes a cell counting step.

Prepare for splitting

Follow steps described in steps 6 and 7 of Protocol: Expansion and maintenance of human induced pluripotent stem cells (iPSCs). Protocol: Expansion and maintenance of human induced pluripotent stem cells (iPSCs).

Prepare for cell counting

2.2.1. Add 49 μL of Phosphate Buffered Saline (PBS) to one Eppendorf per cell line for cell dilution.

2.2.2. Add 1 μL of Solution 18 to a separate Eppendorf for counting.

Replate iPSCs

As described in step 7 of Protocol: Expansion and maintenance of human induced pluripotent stem cells (iPSCs), pausing when cell pellet is suspended in 1 mL of mTesR media (i.e. mTesR plus their accompanying Supplement and 1% Penicilline/Streptomycin) + ROCKi (1:1000) to count cells.

Count cells (automatically using cell counter)

2.4.1. Dilute cells by adding 1 μL of cell suspension to 49 μL of previously prepared PBS in an Eppendorf.

2.4.2. Mix thoroughly.

2.4.3. Take 19 μL of diluted cell mixture and add to Eppendorf containing 1 μL of Solution 18.

2.4.4. Mix thoroughly and count cells.

2.4.5. Calculate and plate cells based on the following optimal density for Day -1 plating: 1.425 million cells / well of 6-well plate (150 000/ cm²).

2.4.6. Transfer cells to a 6-well plate after aspirating the Matrigel, and top up with mTesR media to have 2 mL media total.

Before starting, check the confluency. The iPSCs should be at least >80% confluent to start, otherwise feed the cells and wait another day. If in doubt, more confluent is better.

Thaw growth factors at room temperature and make every media fresh daily and filter immediately before use.

Days 0 through 20 of the protocol contain no antibiotics and therefore, it is extra pertinent to use the most aseptic technique.

If at any point Day 1 through Day 10 the cells peel, they can be replated by collecting the media and, if any cells remain adhered, using Accutase as described in step 4.3.

Day prior to preparing differentiation medias

3.1.1. Thaw supplements (KSR, B27 and N2) (ideally in fridge overnight).

3.1.2. Prepare KO DMEM KSR base media and NNB base media (see Materials ).

Day 8: Half media change

50% KO DMEM KSR base media

50% NNB base media

1:10 000 LDN

1:3333 CHIR

Day 9: Full media change

25% KO DMEM KSR base media

75% NNB base media

1:10 000 LDN

1:3333 CHIR

Day 10: Full media change (D10 media)

25% KO DMEM KSR base media

75% NNB base media

1:10 000 LDN

1:3333 CHIR

Day 0: Full media change

1. Add to KO DMEM KSR base media:

1:10 000 LDN

1:1000 SB

Day 1 : Full media change

1. Add to KO DMEM KSR base media:

1:10 000 LDN

1:1000 SB

1:1000 SHH

1:5000 FGF8a

1:5000 Puro

Day 2: Half media change

1. Add to KO DMEM KSR base media:

1:10 000 LDN

1:1000 SB

1:1000 SHH

1:5000 FGF8a

1:5000 Puro

Day 3: Full media change

1. Add to KO DMEM KSR base media:

1:10 000 LDN

1:1000 SB

1:1000 SHH

1:5000 FGF8a

1:5000 Puro

Day 4: Half media change

1. Add to KO DMEM KSR base media:

1:10 000 LDN

1:1000 SB

1:1000 SHH

1:5000 FGF8a

1:5000 Puro

1:3333 CHIR

Day 5 : Full media change

75% KO DMEM KSR base media

25% NNB base media

1:10 000 LDN

1:1000 SHH

1:5000 FGF8a

1:5000 Puro

1:3333 CHIR

Day 6: Half media change

75% KO DMEM KSR base media

25% NNB base media

1:10 000 LDN

1:1000 SHH

1:5000 FGF8a

1:5000 Puro

1:3333 CHIR

Day 7: Full media change

50% KO DMEM KSR base media

50% NNB base media

1:10 000 LDN

1:3333 CHIR

This section is optional. If not desired, continue on to Section: Patterning NPCs into dopaminergic neurons Day 11 to 22+ .

Expansion allows for the freezing and thawing of progenitors midway through the protocol, as well as evidence suggests the final neurons may be more mature ([Fedele. S. et al., 2017](http://(https://www.nature.com/articles/s41598-017-05633-1) et al ., 2017). It consists of maintaining progenitors cells on Day 10 media (D10; step 3.12 ) for 1 to 21 days with splits throughout. Therefore, time points are labelled (D10^+exp), for instance, cells in Day 10 media for 4 days are labelled D10^+4exp.

Day 10: Preparation on day prior to first expansion split

Geltrex 6-well plates as described in step 1.

Day 10+1: Preparation on the day of the first expansion split. ⁺¹: Preparation on the day of the first expansion split.

4.2.1. Pre-warm spinning falcons containing 9mL of KO DMEM base media.

4.2.2. Prepare D10 media ( step 3.12 ) + ROCKi (1:1000).

4.2.3. Allow an aliquot of desired volume (1mL per well of a 6-well plate) to reach room temperature.

Day 10+1: Splitting Day 10 NPCs ⁺¹: Splitting Day 10 NPCs

Some lines may survive 1:2, but it is advisable to split cells 2:3, as there will be quite some cell death and the cells need to be fairly confluent to maintain viability and cell identity. If split too harshly, they may differentiate into other cell types.

4.3.1. Aspirate media and wash each well with 1mL of PBS.

4.3.2. Immediately aspirate PBS and add 1mL of Accutase.

4.3.3. Incubate at 37⁰C for 5 minutes.

4.3.4. Gently collect cells using a 1000 μL pipette and place in pre-warmed spinning falcon.

4.3.5. Spin cells for 5 minutes at 350g.

4.3.6. While cells are spinning, aspirate Geltrex and replace with 3mL of pre-warmed D10 media ( step 3.12 )+ ROCKi (1:1000).

4.3.7. Aspirate media from pelleted cells, re-suspend pellet in 1mL of D10 media ( step 3.12 ) + ROCKi and add dropwise to well of 6-well plate.

4.3.8. Gently swirl to distribute cells evenly around dish.

Day 10+2: Maintaining NPCs in Day 10 Expansion Media ⁺²: Maintaining NPCs in Day 10 Expansion Media 4.2.1. Day following expansion split, full feed cells with D10 media step 3.12 2).

4.2.2. Subsequently feed neurons daily with D10 media (also named as D10 expansion media), alternating between half and full feeds.

4.2.3. Passage cells when confluent, generally success is found with a 1:2 split on Day 10⁺⁸, Day 10⁺¹⁵ and Day 10⁺²⁰.

Freezing Day 10+expNPCs ^+expNPCs

4.5.1. Passage cells as described in step 4.3.

4.5.2. Resuspend pellet in freezing media containing 90% D10 media ( step 3.12 ) and 10% DMSO.

4.5.3. Store in liquid nitrogen.

Day 11: Full media change

1. Add to NB base media:

1:3333 CHIR

1:5000 BDNF

1:5000 GDNF

1:10 000 TGFβ3

1:10 000 DAPT

1:1000 Ascorbic Acid

1:200 dCAMP

Day 12: Half media change

1. Add to NB base media:

1:3333 CHIR

1:5000 BDNF

1:5000 GDNF

1:10 000 TGFβ3

1:10 000 DAPT

1:1000 Ascorbic Acid

1:200 dCAMP

Day 13 - Day 19: Daily media changes

Alternate half and full feeds with Final Maturation Media (see Materials ).

Replate the dopamine neurons into final desired dish on Day 20±1 of the protocol (this has been tested to be equally successful on Day 19 and 21). Replating neurons at later stages of their maturation is not recommended and will decrease viability.

One to two days prior to final replating: Dish coating

Choice of coating will affect cell distribution and likelihood of peeling. Geltrex and PLO/Biolaminin are both suitable for replating the neurons. PLO/Biolaminin is thought to reduce peeling and provide a more distributed layer of neurons advantageous for imaging.

If using Geltrex:

1 day prior to Day 20 replating:

• Coat dishes with Geltrex prepared in neurobasal media

If using PLO/Biolaminin:

2 days prior to Day 20 replating:

• Coat plates with undiluted PLO

1 day prior to Day 20 replating:

• Wash 3x with PBS without letting plates dry.
• Dilute Biolaminin 1:10 in cold, sterile PBS.
• Aspirate and add Biolaminin at same volume as PLO.

Replating of Day 20 Dopamine Neurons

8.2.1. Wash cells 1x with 1mL PBS and replace with 1 mL Accutase, incubate at 37⁰C for 5 minutes.

8.2.2. Gently collect cells into a pre-warmed spinning falcon.

8.2.3. Spin at 350g for 5 minutes.

8.2.4. Resuspend pellet in 1 mL of pre-warmed Final Maturation Media (see Materials ) and count cells using Solution 18.

8.2.5. Replate at final desired concentrations ( Table 1 ).

A	B	C	D
Plate Type	Surface Area (cm2)	Useful for	Ideal density
12 well	3.8	Protein & RNA collections	1 x106/ well
24 well	1.9	Protein & RNA collections	5 x 105/ well
24 well + 10 mm coverslip	0.78	Electrophysiology	1 x 105/ well
96 well half area	0.15	Imaging	3-5 x 104/ well

Table 1: Recommended densities for various types of experiments.

It is normal to produce a small number of non-neuronal cells throughout this protocol, but ideally these should be at a minimum. We try to reduce the amount remaining in our culture following the final replating of post-mitotic dopamine neurons (previous section) by treating the cells with Mitomycin C on Day 22.

Day 22: Prepare medias

9.1.1. Prepare MitoC media (see Materials ), Neurobasal (wash media) and Final Maturation Media (see Materials ).

9.1.2. Pre-warm and filter all three medias.

Day 22: Mitomycin C treatment

9.2.1. Aspirate Final Maturation Media from DaNs.

9.2.2. Add pre-warmed and filtered MitoC media from step 9.1.1.

9.2.3. Incubate at 37⁰C for 1 hour.

9.2.4. Aspirate Mitomycin C and wash 1x with pre-warmed Neurobasal media.

9.2.5. Aspirate Neurobasal media and replace with Final Maturation Media.

Dopaminergic neurons can be kept in culture for multiple months before obvious demise. The length of survival will depend on feeding schedule, density and various other factors.

Day 24 - Day 25: Full media change

First feed immediately following Mitomycin C treatment should be a full feed with Final Maturation Media (see Materials ).

Day 25+: Biweekly Half media changes ⁺: Biweekly Half media changes

10.2.1. From Day 25 onwards, half feed neurons with Final Maturation Media (see Materials ) two to three times a week.

10.2.2. Monitor cells regularly using a brightfield microscope for cell health and contamination.