Özet

Human Neural Organoids for Studying Brain Cancer and Neurodegenerative Diseases

Published: June 28, 2019
doi:

Özet

This study introduces and describes protocols to derive two specific human neural organoids as a relevant and accurate model for studying 1) human glioblastoma development within human neural organoids exclusively in humans and 2) neuron dopaminergic differentiation generating a three-dimensional organoid.

Abstract

The lack of relevant in vitro neural models is an important obstacle on medical progress for neuropathologies. Establishment of relevant cellular models is crucial both to better understand the pathological mechanisms of these diseases and identify new therapeutic targets and strategies. To be pertinent, an in vitro model must reproduce the pathological features of a human disease. However, in the context of neurodegenerative disease, a relevant in vitro model should provide neural cell replacement as a valuable therapeutic opportunity.

Such a model would not only allow screening of therapeutic molecules but also can be used to optimize neural protocol differentiation [for example, in the context of transplantation in Parkinson’s disease (PD)]. This study describes two in vitro protocols of 1) human glioblastoma development within a human neural organoids (NO) and 2) neuron dopaminergic (DA) differentiation generating a three-dimensional (3D) organoid. For this purpose, a well-standardized protocol was established that allows the production of size-calibrated neurospheres derived from human embryonic stem cell (hESC) differentiation. The first model can be used to reveal molecular and cellular events occurring during in glioblastoma development within the neural organoid, while the DA organoid not only represents a suitable source of DA neurons for cell therapy in Parkinson’s disease but also can be used for drug testing.

Introduction

The World Health Organization (WHO) classifies astrocytomas as low grade (grade I to II) or high grade (grade III and IV). Glioblastoma multiforme (GBM) is an astrocytoma grade IV, the most lethal of primary brain tumors, that is resistant to all current forms of treatments1. Despite standard-of-care therapy including neurosurgery, chemotherapy, and radiotherapy, GBM remains fatal and the 15-month overall survival rate has not dramatically changed over the past 15 years2. To make significant progress in understanding GBM pathogenesis, the use of relevant models is key. So far, the study of GBM has relied on cell lines, rodent organotypic slices, and xenotransplantation of patient-derived cells into mice or transgenic mice developing spontaneous tumors3,4. Although these models have been useful to study brain metastasis and tumor aggressiveness, they are restricted by differences among species, and resulting conclusions may be incorrectly translated to human tissues. Moreover, existing models with human cells are also limited by the absence of host tissue/tumor interactions3,4. Experimental models are critical for the translation from basic science to therapeutic targets. Therefore, describing a protocol to produce in vitro human neural organoids co-cultured with GBM-initiating cells (GICs) can provide a relevant system that mimics morphological and functional features of GBM development. This system reproduces some in vivo features of GBM developmentsuch as diffuse migration of invading cells and necrosis areas, and it highlights gene expression relevant to tumor biology. As previously revealed, some critical microRNAs are induced during GIC development within 3D nervous tissue5,6.

PD is a major neurodegenerative disorder and associated with the degeneration of multiple neuronal subtypes7. Even if a progressive onset of symptoms (e.g., bradykinesia, asymmetric rest tremor, rigidity and posture instability) characterizes the disease, its exact etiology is not clearly established. Indeed, many studies have highlighted evidence that major risk factors can result from a combination of genetic and environmental factors. Parkinsonian symptoms are associated with the bilateral degeneration of dopaminergic neurons in the substancia nigra (SN), leading to the disappearance of dopaminergic (DA) axons projecting to the striatum8,9. Therefore, the reduction of striatal dopamine levels is correlated with progression of motor dysfunction in PD patients. Dopaminergic neurons contain tyrosine hydroxylase (TH), a key enzyme in the synthesis of catecholaminergic neurotransmitters that converts the amino acid L-tyrosine to L-3,4-dihydroxyphenylalanine (L-DOPA, a dopamine precursor) to dopamine10. Early loss of TH activity followed by a decline in TH protein expression is a hallmark of PD.

This study describes two protocols using human neural organoids, with one specifically oriented towards a midbrain-like phenotype enriched with TH-positive cells.

Protocol

This protocol follows the guidelines of University of Geneva's human research ethics committee.

1. Maintenance and culture of undifferentiated human embryonic stem cells (hESCs)

  1. Perform maintenance and expansion of hSECs on feeder-free conditions by pre-coating dishes with a specific extracellular matrix.
    1. Thaw 300 µL of extracellular matrix at 4 °C (typical range concentration 18-22 mg/mL, keep on ice) and gently mix with 15 mL of cold DMEM medium to avoid a premature gelation of the extracellular matrix. Add 7.5 mL of the extracellular matric to both T150 flasks.
    2. Incubate the dishes coated with extracellular matrix at 37 °C for at least 1 h (maximum overnight).
    3. Remove the medium and seed hESCs to a density of 6.5 x 104 cell/cm2.
  2. Maintain H1 (hESC cell line) in hESC medium and 1% penicillin/streptomycin.
  3. Pass the cells with enzymatic procedure: add 7.5 mL of enzymatic solution to a T75 cm2 flask over a period of 1-2 min at 37 °C. Once cells are completely detached, add 7.5 mL of DMEM-F12 then centrifuge for 5 min at 300 x g. To allow for better survival, re-plate cells at the desired density onto extracellular matrix-coated dishes, in the same medium containing Rho-associated protein kinase (ROCK) inhibitor (10 µM) for 24 h.

2. hESC-derived neural organoids for GBM studies

  1. 24 h before starting the 3D culture, replace the hESC medium with a serum-free medium supplemented with 10 µM ROCK inhibitor (both components are necessary to support cell survival and spontaneous neurosphere formation during the aggregation phase in a microwell plate). The cells should be at 60% confluency. The next day (day 0), detach hESC colonies as single cells: remove the medium, then rinse with PBS without Ca2+/Mg2+, add 5 mL of enzymatic dissolution solution, and incubate at 37 °C for 1-2 min.
  2. Collect the cells in serum-free medium with 10 µM of ROCK inhibitor and centrifuge the cells at 300 x g for 5 min. Remove the supernatant and count the cells in 10 mL of serum-free medium supplemented with 10 µM of ROCK inhibitor.
  3. In parallel, rinse the microwell plate with 2 mL of serum-free medium per well and centrifuge the plate at 1200 x g for 5 min to remove all bubbles, which can prevent neurosphere formation.
  4. Prepare 28.2 x 106 of cells in 12.5 mL of serum-free medium supplemented with 10 µM ROCK inhibitor. Dispense 1000 cells/microwell. Centrifuge the cells at 300 x g for 5 min and place the plate in the incubator at 37 °C overnight (maximum 36 h). For example: to obtain 30 human neural organoids, use one T150 flask at 70%-80% of confluence (about 30 million cells).
  5. The next day (day 1), collect the spheres (with a P1000) and place them in a 6 well plate. In each well, add 2 mL of B27 medium and DMEM-F12 GlutaMAX and Neurobasal medium (mix at 1:1), supplemented with 1% B27 supplements and 1% non-essential amino acids (NEAA). To promote fast neural induction, supplement the medium with dual-SMAD inhibition cocktail, composed of 10 µM TGFβ/Activin/Nodal inhibitor and 0.5 µM bone morphogenic protein (BMP) inhibitor. From this step forward, the spheres are cultured in rotation (60 rpm, orbital shaker). The rotation is critical to prevent the spheres from sticking together or to the plate.
  6. Change the medium every 2-3 days: bend the plate and let the spheres fall down for 5 min, remove half of the medium (2 mL), and add 2 mL of fresh B27 medium supplemented with growth factors and inhibitors. Do not centrifuge the spheres.
  7. Perform neural induction according to the following time course:
    1. From days 1-4, culture the spheres in B27 medium supplemented with dual-SMAD. The dual-SMAD inhibition cocktail (10 µM TGFβ/Activin/Nodal inhibitor and 0.5 µM BMP inhibitor) promote the neural induction.
    2. From days 4-11, promote proliferation of hESC-derived neural rosettes (into the spheres), by adding 10 ng/mL epidermal growth factor (EGF) and 10 ng/mL basic fibroblast factor (bFGF) to the B27 medium supplemented with dual-SMAD cocktail.
      NOTE: On day 11, most of the cells should be positive for Nestin.
    3. From days 11-13, culture the spheres in B27 medium supplemented with 0.5 µM BMP inhibitor.
    4. From days 13-21, culture the spheres in B27 medium supplemented with 10 ng/mL glial derived neurotrophic factor (GDNF), 10 ng/mL brain derived neurotrophic factor (BDNF) and 1 µM of γ-secretase inhibitor. GDNF and BDNF promote neuronal and glial differentiation. The γ-secretase inhibitor allows for greater neural maturation.
    5. On day 21, plate the spheres (about 1,000 spheres) on a hydrophilic polytetrafluoroethylene (PTFE) membrane (6 mm diameter, 0.4 µm) deposited on a culture plate insert designed for 6 well plate. Stop any rotation from this step. The presence of rosettes, observed with a bright-field microscope, indicate the initiation of neural differentiation. The neural rosettes can be observed 2-3 days after plating spheres on the PTFE membrane.
    6. Add 1 mL of B27 medium supplemented with growth factors and inhibitors (as followed) to each well underneath the membrane insert, every 2-3 days (usually on Monday, Wednesday and Friday), for a following 3 weeks of differentiation.
    7. From days 21-25, cultivate human neural organoids in the same neural maturation medium (Cf. step 2.7.4).
    8. From days 25-28, only complement B27 medium with 1 µM γ-secretase inhibitor.
    9. From days 28-39, stop adding the γ-secretase inhibitor and continue human neural organoid culture in B27 medium only.
      NOTE: After 3 weeks, neural organoids are ready to use for GIC implantation. Along the neural maturation, a decrease of neural immature marker Nestin and increase of mature neural markers β3-tubulin and GFAP were observed.

3. Isolation and cultivation of glioblastoma-initiating cells (GICs)

  1. Isolate GICs by fragmenting a high grade human GBM biopsy. Transfer the piece of tumor in a beaker containing 0.25% trypsin in 0.1 mM EDTA (4:1) and slowly stir at 37 °C for 30-60 min (depending on tumor size).
  2. Plate the dissociated cells in 75 cm2 tissue culture flasks plated at 2,500-5,000 cells per cm2 in GIC medium: DMEM/F-12 medium (1:1) containing 1% N2, 1% B27, and 1% G5 supplements (to favor GIC survival), supplemented with bFGF and EGF (both at 10 ng/Ml, to promote stemness) and 1% of penicillin/streptomycin.
  3. Once the GIC is well-established and growing, remove the N2 and G5 supplements from the GIC medium.
  4. One day before adding the cells onto the organoid, dissociate the GICs and count them.
  5. Rinse the microwell plate with 2 mL of GIC medium and centrifuge the plate at the maximum speed to remove bubbles (1000 x g). Place the GICs at 1,000 cells to obtain one gliomasphere per microwell. Incubate overnight at 37 °C (Figure 1C). This step is key and allows for well-calibrated GICs (an example of necrotic and over-sized GICs is shown in Figure 2A,C).
  6. To initiate GBM invasion, add one gliomasphere on top of the neural tissue with a large bore pipet tip (Figure 1F). Carefully place the 6 well plate back in the incubator.

4. hESC-derived dopaminergic organoids for PD studies

  1. Day 0: Amplify hESCs in 2D culture up to 60% confluency (day 0), then replace stem cell media used to maintain pluripotency features of hESCs with a serum-free medium. Start neural induction by supplementing culture medium with 0.5 µM BMP inhibitor and 10 µM TGFβ/Activin/Nodal inhibitor (dual-SMAD inhibition cocktail), then add 10 µM ROCK inhibitor for 24 h to increase the survival rate of cells during passage.
  2. Day 1: Prepare the microwell plate with 2.5 mL per well of serum-free medium supplemented with 0.5 µM BMP inhibitor, 10 µM TGFβ/Activin/Nodal inhibitor, and 10 µM ROCK inhibitor. To specify cells towards the ventral pattern of the neural tube, add 100 ng/mL Sonic Hedgehog (SHH), 100 ng/mL fibroblast growth factor 8 (FGF8), and 2 µM smoothened agonist. Centrifuge the plate (only with medium and without cells) at 1200 x g for 5 min to remove air bubbles from the microwells.
    1. After 1 day of neural induction in 2D, remove the medium and quickly wash with PBS without Ca2+/MgCl2+. Dissociate the colonies in single cells suspension by adding 7.5 mL of recombinant enzymatic solution in a T75 cm2 flask. Incubate for 2 min at 37 °C then complete with 7.5 mL of DMEM-F12.
    2. Collect the cell suspension and centrifuge at 300 x g for 5 min. Remove the supernatant and count the cells in the same medium used to prepare the microwell plate.
    3. Adjust the medium volume to obtain a cell suspension allowing to form neurospheres containing 1000 cells per microwell (for example, the microwell plate used here contains 4,700 microwells per well). So, prepare 4.7 million cells in 2.5 mL of medium and add it to the previous 2.5 mL of medium already placed in the plate.
    4. In order to correctly distribute the cells in each microwell, gently shake the plate, and centrifuge the microwell plate 300 x g for 5 min. Incubate the plate at 37 °C for 24 h to generate spheres.
  3. Day 2: Gently flush the microwells with the medium and collect then transfer the spheres in tissue-treated six-well plate. Replace medium with Neurobasal medium supplemented with 1% B27, 1x NEAA, 2 mM L-glutamine, and 1% of penicillin/ streptomycin. Additionally, add regionalization factors SHH, FGF8, smoothened agonist, and dual-SMAD inhibition small molecules.
    1. Place spheres in rotation at 37 °C (60 rpm, orbital shaker) and change half-medium freshly supplemented every 2-3 days.
  4. Day 3: To enhance neural induction and convert to neural progenitors with a midbrain identity, supplement the medium with 3 µM GSK-3β inhibitor, which activates the Wnt/β-catenin pathway. Maintain GSK-3β inhibitor in the medium up to day 13. Split into two new tissue-treated 6 well plates to reduce both sphere density per well and avoid sphere aggregation.
    NOTE: At Day 8, most of the cells should be positive for Nestin.
  5. Day 8: Start the neural maturation: replace regionalization factors SHH, FGF8, smoothened agonist, and dual-SMAD inhibition cocktail with 0.5 mM dibutyryl cAMP (to favor maturation), 20 nM inhibitor of histone deacetylase (for cell cycle exit), 1 µM γ-secretase inhibitor and growth factors, 10 ng/mL GDNF, 10 ng/mL BDNF, 1 ng/mL transforming growth factor β3 (TGFβ3), and 5 ng/mL FGF20 (both favor DA progenitor survival). Change the medium every 2-3 days.
  6. Day 21: Generate the neural organoid: seed around 100 neurospheres under air-liquid interface conditions on PTFE membrane (6 mm diameter). Transfer the membrane to a culture plate insert (0.4 mm) and add 1.2 mL of neural maturation medium used for neurosphere differentiation as previously described.
    1. Stop any rotation from this step. Change the medium every 2-3 days until the required differentiation time point is achieved.
      NOTE: Regarding neural maturation, a decrease of the neural immature marker Nestin and increase of mature neural markers β3-tubulin and GFAP were observed. High TH and NURR1 expressions were observed (Figure 3C) and confirm neural organoid maturity11.

5. Quantification of TH and Nurr1 gene expression for validation of dopaminergic differentiation

  1. RNA extraction: On the indicated day of differentiation, lyse 40 neurospheres with 350 µL of RLT buffer (provided in RNA extraction kit) supplemented with 3.5 µL of 2-mercaptoethanol. Extract the RNA from the lysed neurospheres using an RNA extraction kit following the manufacturer's instructions.
  2. Quantify total RNA concentrations.
  3. Perform reverse transcription of 300 ng of the total RNA extraction using reverse transcription kit for quantitative real-time polymerase chain reaction (qPCR) and follow the manufacturer's instructions .
  4. Perform qPCR analysis on real-time PCR detection systems, based on asymmetrical cyanine dye detection. Normalize the data with housekeeping genes: glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and elongation factor 1-alpha (EF1). Sequences of primers are described in Table 1.

6. High pressure liquid chromatography (HPLC) detection

  1. Use high pressure liquid chromatography (HPLC) with electrochemical detection to detect the presence of dopamine. Dopamine was extracted by lysing neural organoids in 100 mL of 0.1 N perchloric acid (HClO4) for 15 min at 4 °C with a vigorous vortexing every 5 min. After centrifugation, collect and store the supernatant at -20 °C for dopamine dosage.
  2. Use a C-18 column (5 µm, 4.6 mm x 150 mm) to separate the analytes by reversed-phase HPLC in isocratic mode at a flow rate of 1 mL/minute. Detection of dopamine should be carried out using a coulometric detector with the conditioning cell set at a potential of +200 mV.

7. Raw data recording with microelectode array (MEA) platform

  1. Use a dissection microscope to transfer neurospheres to the center of a porous MEA device.
  2. Use an amplifier and data acquisition system for electrophysiological recordings. Measure the signal-to-noise ratio (SNR) as the standard deviation of the voltage during a 5 min recording, using the signal as the average peak-to-peak voltage of the spikes recorded in the same 5 min periods.

Representative Results

The critical steps of this protocol must be well-identified and handled properly. Therefore, a diagram of culture conditions indicating the time-lapse for each step as well as the compounds used for the differentiation protocol are illustrated in Figure 1A and Figure 3A for NO plus GBM and DA neural organoids, respectively. Figure 1B,C,D,E,F illustrates the cells, spheres, and NO and show the typical morphology for each step. Figure 1G,H,I illustrates immunofluorescence staining with some neural markers.

Figure 1
Figure 1: Human neural organoid (NO) differentiation protocol. (A) Standardized protocol for the generation of NO derived from human embryonic stem cells (hESC). (B) hESCs are maintained on extracellular matrix in hESC medium. (C) Microwell plates were used to generate calibrated neurospheres. At 2 weeks, neurospheres were plated onto the insert containing a PTFE membrane (scale bar = 50 µm). (D) Macroscopic view of NO into the insert in one well of a 6 well plate. During the first days, rosettes were observed (black arrow) (E). (F) Macroscopic view of a NO plus GIC sphere on the top. (GI) Immunofluorescence analysis of NO plus GIC sphere (EGFR-positive; scale bar = 50 µm) (G) and NO alone, which showed immune reactivity for the neuronal marker βIII-tubulin and slightly positive for nestin; however, synapsin 1 showed a weak signal (H,I) (scale bars = 100 µm and 50 µm, respectively). Please click here to view a larger version of this figure.

Figure 2
Figure 2: Illustration of necrotic spheres and immature NO. The neurospheres (A) and NO (B) can undergo necrosis when they are too numerous in the well or oversized (C) (scale bar = 10 µm). (D) One GIC infected with a tomato reporter help to track tumor cell invasion in NO, scale bar, 10 µm. Example of immature NO with neural tubes (E) and no neural tubes (F) (scale bar = 50 µm). Please click here to view a larger version of this figure.

Figure 3
Figure 3: Standardized protocol for generation of DA neural organoid and electrophysiological and morphological analysis. (A) Standardized protocol for the generation of DA neural organoids. (B) Immunofluorescence analysis of DA neural organoid; TH-immunoreactive cells co-expressing Nurr1, a midbrain specific marker (scale bar = 50 µm). Data are represented as mean ± SEM (n = 3). (C) Graphs represent kinetics of TH and Nurr1 gene expression evaluated by qRT-PCR. (D) Representative HPLC: dopamine peak (arrow) was detected by HPLC from DA neural organoid lysate. (E) Example of raw data recorded with MEA platform. Each spike is displayed by a vertical line (time stamps), whereas the remaining trace is noise. (F) Picture representing a neurosphere deposited on the MEA. (G) Superposition of typical spikes (blue and red curves) detected from the raw data. The black bold curve indicates the average of the corresponding red curves. (H) Raster plot showing the time stamps associated with each spike detected. The different colors highlight the different electrodes. Please click here to view a larger version of this figure.

Gene Foward Reverse
Nurr1 GGCTGAAGCCATGCCTTGT GTGAGGTCCATGCTAAACTTGACA
TH GCACCTTCGCGCAGTTCT CCCGAACTCCACCGTGAA
EEF1 AGCAAAAATGACCCACCAATG GCCTGGATGGTTCAGGATA
GAPDH GCACAAGAGGAAAGAGAGAGAACC AGGGGAGATTCAGTGTGGGT

Table 1: Primers used in this protocol.

Discussion

One of the most critical aspects of this protocol includes the maintenance of hESC pluripotency during cell culturing and close monitoring of the spheres and neural organoid morphology. hESCs are very sensitive, and every manipulation can lead to early uncontrolled differentiation as well as cell death. In order to increase experimental reproducibility and avoid the occurrence of abnormal karyotype events, it is advised to cryopreserve several batches of hESCs at the lowest passage after validation of their chromosome stability. Moreover, it is recommended to thaw a new vial for each experiment and check the behavior of the cells every day. If the spheres are less refractive with abnormal higher size, they will likely start to aggregate and die.

One improvement upon this system is either perfusion or implementing a vascularized system (by adding endothelial cells or within a 3D fluidic microchip)12,13. However, controlling the thickness of the neural organoid (≤300 µm) allows efficient passive perfusion of oxygen and nutriments and prevents necrosis. Another improvement is the introduction of immune cells (microglia). With these limitations in mind, neural organoids plus a GIC system may be a relevant tool for several reasons. First, this system allows drug screening to monitor how a therapeutic compound may affect an organoid or tumor cell. Second, cell-to-cell interactions can be studied, and micro-environmental determinants underlying individual and collective invasions can be visualized and explored5,6,13.

In the context of Parkinson's disease, a neural organoid enriched in DA neurons can represent a relevant and accurate 3D model to study disease development. In previous studies, Parkinson's patient-derived induced pluripotent stem cells differentiated towards DA neurons have been used to study the affected neuronal subtypes. Of note, some disease-related phenotypes such as the accumulation of α-synuclein and sensitivity to oxidative stress have been observed14,15. Moreover, the neural organoid may be used as a tool to screen therapeutic molecules. However, specific and relevant readouts should be set up to evaluate DA neuron survival and functionality, such as dopamine production and electrophysiological activity. Altogether, this protocol provides two standardized and accurate stem cell-based approaches to generate neural organoids.

Açıklamalar

The authors have nothing to disclose.

Acknowledgements

The authors thank la Ligue Genevoise Contre le Cancer (Geneva, Switzerland), ISREC Foundation (Lausanne, Switzerland), and the Clayton Foundation for Research (Houston, TX, USA) for financial support. Moreover, the authors thank HES-HO and the Wyss Center for financial support. We thank the Krause's lab for helpful discussions and support and Dr. Halah Kutaish for proofreading.

Materials

6-well plate (6-well plate) Falcon / Corning 07-201-588
ABI Prism 7900 HT detection system  (Real-Time PCR detection systems) Applied Biosystems Discontinued
Aggrewell 400 (Microwell culture plates ) StemCell Technologies 34421
Amplifier (W2100-HS32)  (Amplifier) Multi Channel Systems
Anti-EGFR (phospho Y1101) antibody Abcam ab76195 1/100 dilution
Anti-GFAP Antibody Dako  Z334  1/1000 dilution
Anti-Nestin, Human Antibody Millipore  ABD69  1/400 dilution
Anti-Synapsin I Antibody Chemicon  AB1543P  1/500 dilution
B27 supplements (B27) Life Technologies / Invitrogen 1238 For both protocol, stock solution 100x, final solution 1x
Brain-derived neurotrophic factor  (BDNF) Cell Guidance GFH1-2 For both protocol,  stock solution 100 µg/mL in pure H2O, final solution 20 ng/mL
CHIR-99021 (GSK-3β inhibitor ) Axon Medchem ct99021 For Dopaminergic protocol,  stock solution 7.5 mM in DMSO, final solution 3 µM
Compound E a γ–secretase inhibitor (γ–secretase inhibitor) Calbiochem CAS 209986-17-4 For both protocol (gamma-secretase inhibitor XXI),  stock solution 5 mM in DMSO, final solution 1 µM
Coulochem III  (Coulometric detector parameters) Thermo scientific
Dibutyryl cyclic-AMP (Dibutyryl cAMP) Sigma D0627 For Dopaminergic protocol,  stock solution 0.5 M in DMSO, final solution 0.5 mM
Dimethyl Sulfoxide Pure (DMSO) Sigma-Aldrich C6164 Compounds solvent, ready to use
Dulbecco's Modified Eagle Medium (DMEM) Life Technologies 12491-015 For cell culture, ready to use
Dulbecco's Modified Eagle Medium Mixture F-12 (DMEM-F12) Gibco 11320033 For cell culture, ready to use
EDTA 0.1 mM (EDTA) Life Technologies AM9912 For cell culture, ready to use
Epidermal Growth Factor (EGF) Gibco PHG0313 For GIC culture,  stock solution 100 µg/mL in pure H2O, final solution 10 ng/mL
Fibroblast Growth Factor 20 (FGF20) Peprotech 100-41 For Dopaminergic protocol,  stock solution 100 µg/mL in pure H2O, final solution 5 ng/mL
fibroblast growth factor 8  (FGF8) Peprotech GFH176-5 For Dopaminergic protocol,  stock solution 100 µg/mL in pure H2O, final solution 100 ng/mL
Fibroblast growth factor-basic (bFGF) Gibco PHG0024 For GIC culture,  stock solution 100 µg/mL in pure H2O, final solution 10 ng/mL
G5 supplements (G5) Invitrogen 17503012 For GIC culture, stock solution 100x, final solution 1x
Glial cell-derived neurotrophic factor (GDNF) Cell Guidance GFH2-2 For both protocol,  stock solution 100 µg/mL in pure H2O, final solution 20 ng/mL
Hydrophilic polytetrafluoroethylene  membrane (PTFE membrane) BioCell-Interface Discontinued
LDN-193189 (BMP inhibitor) Axon Medchem /Stemgen 04-0072-02 /1509 Dual/Smad,  stock solution 5 mM in DMSO, final solution 0.5 µM
L-glutamine (L-glutamine) Gibco 25030081 L-Glutamine (200 mM), stock solution 200 mM, final solution 2 mM
Matrigel (extracellular matrix) BD Biosciences 354277 hESC-qualified Matrix, stock solution 18-22 mg/mL, final solution 180-220 µg/mL
Millicell-CM Culture plate insert  (0.4 µm) (Culture plate insert) Millipore PICM03050
Monoclonal Anti-β-Tubulin III antibody Sigma  T8660  1/1000 dilution
MS Orbital Shaker, MS-NOR-30 (Orbital shaker) Major Science MS-NRC-30
N2 supplements (N2) Invitrogen 17502-048 For GIC culture, stock solution 100x, final solution 1x
Nanodrop (Nanodrop) Thermo Fisher Scientific Discontinued
Neurobasal (Neurobasal) Life Technologies / Gibco 21103049 Maintenance and maturation embryonic neuronal cell populations , ready to use
Non-Essential Amino Acids  (NEAA) Gibco 11140 Non-essential Amino Acids 100X, stock solution 100x, final solution 1x
Nurr1 Antibody (M-196) Santa Cruz Sc-5568 1/100 dilution
Nutristem  (hESC medium ) Biological Industries 05-100-1A Stem cell media, ready to use
Penicilin / Streptomycin  (Penicilin / Streptomycin ) Life Technologies / Gibco 15140122 For cell culture, stock solution 5 mg/mL, final solution 50 µg/mL 
Perchloric acid 0.1N (HCLO4) Merck 100519 For HPLC, ready to use
Phosphate Buffered Saline without Ca2+/Mg2+  (PBS without Ca2+/Mg2+ ) Life Technologies 14190250 For cell culture, ready to use
PrimeScript RT-PCR Kit (Reverse transcription kit) Takara RR014A
Purmorphamin (smoothened agonist) Calbiochem SML0868 For Dopaminergic protocol,  stock solution 10 mM in DMSO, final solution 2 µM
Rho-associated Kinase Y-27632 (ROCK) Abcam Biochemicals ab120129-1 Rock Inhibitor,  stock solution 50 mM in DMSO, final solution 10 µM
RNeasy mini kit (RNA extraction kit ) Qiagen 74104
SB-431542 (TGFβ/Activin/Nodal inhibitor ) Ascent Asc- 163 Dual-Smad,  stock solution 50 mM in DMSO, final solution 10 µM
Sonic Hedgehog (SHH) Cell Guidance GFH168-5 For Dopaminergic protocol,  stock solution 100 µg/mL in pure H2O, final solution 100 ng/mL
StemPro Accutase (hESC enzymatic solution) Gibco A11105-01 hESC enzymatic solution, ready to use
Symmetry C-18,5 mm (4.6 150mm2)  (Reversed-phase column) Waters Corporation
T150 flask (T150 flask) Falcon 08-772-1F
TH Antibody (F-11) Santa Cruz Sc-25269 1/200 dilution
Transforming Growth Factors beta 3 (TGFβ3) Cell Guidance GFH109-2 For Dopaminergic protocol,  stock solution 100 µg/mL in pure ethanol , final solution 1 ng/mL
Trichostatine A (inhibitor of histone deacetylase ) Sigma T8552 For Dopaminergic protocol,  stock solution 100 µM in DMSO, final solution 20 nM
TrypLE (recombinant enzymatic solution) Invitrogen 12604021 recombinant enzymatic solution, ready to use
Trypsin 0.25% (enzymatic solution) Life Technologies 15050065 enzymatic solution, ready to use
W2100, Multi Channel Systems (Data acquisition system ) WAT045905
X-vivo (serum free medium) Lonza BE04-743Q serum free medium, ready to use

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Cosset, E., Locatelli, M., Marteyn, A., Lescuyer, P., Dall Antonia, F., Mor, F. M., Preynat-Seauve, O., Stoppini, L., Tieng, V. Human Neural Organoids for Studying Brain Cancer and Neurodegenerative Diseases. J. Vis. Exp. (148), e59682, doi:10.3791/59682 (2019).

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