Abstract
Human induced pluripotent stem cells (hiPSCs) are invaluable to study developmental processes and disease mechanisms particularly in the brain. hiPSCs can be differentiated into mature and functional dopaminergic (DA) neurons. Having robust protocols for the generation of differentiated DA neurons from pluripotent cells is a prerequisite for the use of hiPSCs to study disease mechanisms, for drug discovery, and eventually for cell replacement therapy. Here, we describe a protocol for generating and expanding large numbers of homogeneous midbrain floor plate progenitors (mFPPs) that retain efficient DA neurogenic potential over multiple passages and can be cryobanked. We demonstrate that expanded mFPPs have increased DA neuron potential and differentiate more efficiently and rapidly than progenitors generated by standard protocols. In addition, this novel method results in increased numbers of DA neurons that in vitro show characteristic electrophysiological properties of nigrostriatal DA neurons, produce high levels of dopamine, and integrate into host mice when grafted in vivo. Thus, we describe a robust method for producing human mesencephalic DA neurons from hiPSCs.
Similar content being viewed by others
Introduction
Human pluripotent stem cells, including embryonic stem cells and hiPSCs, can be expanded in vitro and retain their capacity to differentiate into any cell type of the three germ layers1, 2. Hypothetically, they represent an unlimited source of cells for several applications including drug screening and cell replacement therapy for treatment of neurological disorders. Parkinson´s disease (PD), the second most common neurodegenerative disorder, is characterized by the selective loss of DA neurons of the substantia nigra of the midbrain3, 4. Although recent advances have been made in our understanding of the pathogenesis of PD, at present there are no cures and the main treatment for patients are DA analogues and receptor agonists to counteract the reductions in DA5,6,7. Numerous protocols have been developed to generate human DA neurons in vitro from pluripotent cells8,9,10,11,12,13,14. These methods rely on the directed differentiation of pluripotent cells using small molecules and growth factors either through an embryoid body or neurosphere step or in adherent culture8,9,10,11,12,13,14,15,16,17,18. These procedures are often laborious, long and highly variable resulting in heterogeneous differentiation with relatively low numbers of midbrain DA neurons. In order to use hiPSC-derived DA neurons for addressing gene function, for drug screening or eventual cell replacement therapy, a homogeneous, robust and rapid method would be a significant advantage19. Here we describe a robust and reproducible method that takes advantage of the mFPP-based differentiation strategy to generate cultures of ~100% LMX1A+FOXA2+ mFPP cells that can be expanded and maintained as a pure population11. This method takes advantage of the molecular pathways that guide DA neuron formation in vivo and can be used to generate a large number of mFPPs that can be passaged more than 6 times in vitro while retaining DA neuron differentiation potential. We also show that expanded mFPPs can be frozen and thawed and that they generate mature DA neurons in vitro with higher efficiency than those generated by standard protocols. Therefore, this protocol allows for expansion and banking of expanded mFPP for large-scale generation of mature and functional DA neurons in vitro and in vivo and circumvents some of the variability often seen with protocols that require differentiation from pluripotent cells without the possibility of progenitor expansion. The generation of expandable mFPPs on a large scale also makes this protocol advantageous for understanding cellular and molecular mechanisms of early human DA neuron development, generating large numbers of mFPPs or DA neurons for drug screening, and transplantation.
Results
Human iPSC-derived mFPPs can be expanded in vitro
Many DA neuron differentiation methods have been developed using human pluripotent stem cells as a cell of origin. Some protocols require the differentiation of cells via a embryoid body, 3D culture or neurosphere step14, 20 or induction of a pan-neural progenitor cell state21,22,23 for the formation of primitive neuroepithelia and neuronal rosette-like structures followed by ventralization to a mesencephalic fate. However, a mixture of dorsal and ventral neural subtypes are usually generated in these cultures including DA neurons, motor neurons, astrocytes and oligodendrocytes21, 24, 25. mFPP-based differentiation strategies were described in which sequentially factor application to the iPSCs results in directed ventralization and the generation of mFPPs10, 11, 26,27,28. The mFPPs are committed precursors which generate mesencephalic DA neurons in vivo. None of these methods take advantage of a DA neuron-specified progenitor cell population.
We developed a robust method for long-term expansion of a pure population of hiPSCs-derived mFPPs maintained in feeder-free and adherent conditions to be used as a potential source of enriched DA neuron cultures. To circumvent the heterogeneity often associated with embryoid body and neurosphere-based differentiation protocols we took advantage of the accessibility of 2D cultures to manipulate signaling pathways and bioactive molecules and factors in chemically defined serum-free media. hiPSCs were cultured on Matrigel under defined conditions in mTeSR-1 medium (see Methods). Subconfluent hiPSCs were passaged onto fresh Matrigel coated plates and cultured for 24 hours in iPSC medium to 90–100% confluency. Once confluent, the medium was changed to floor plate induction medium (n.1) and cultured for 2 days, replacing the medium every day (Fig. 1a,b). At day 3 after starting the floor plate induction with FGF8, SHH, and Purmorphamin, WNT signaling was activated by addition of the GSK3-β inhibitor CHIR-99021 to the n.1 medium. On day 5, the medium was gradually switched to floor plate expansion medium (n.2) and SB-431542 was omitted from the culture (Fig. 1a,b). By day 11 the cells were growing in an n.1/n.2 medium ratio of 1:3. At this point, cells were passaged and replated onto fresh Matrigel coated plates in n.2 medium at a density of 75 × 103 cells/cm2. Cells were maintained in n.2 medium until 90–95% confluency (4–5 days) exchanging the medium every 2nd day (Fig. 1a,b). Once the mFPPs had reached 90–95% confluency, they were passaged and replated onto fresh Matrigel coated plates at a density of 75 × 103 cells/cm2 and cultured further in n.2 medium. We passaged and replated the mFPPs every 4–5 days for at least 6 passages and cells were cryobanked at each passage (see Methods).
At day 11 of floor plate induction, 90–95% of the cells expressed the mFPPs markers LMX1A and FOXA2 and very few PAX6+ dorsal progenitor cells were present in the cultures, demonstrating the efficient and homogeneous mFPP induction11 (Fig. S1a). We examined whether the expanded mFFPs retained their characteristics with extended culture. The cells retained their morphology, forming a compact monolayer of cells that gradually became confluent (Fig. 2a). They also remained homogeneous in expression of the LMX1A and FOXA2 while PAX6+ cells were not detected (Figs 2b and S1b).
On average, 1.25 × 106 ± 0.38 × 106 mFPPs were generated at day 11 of the floor plate induction culture from 5 × 105 hiPSCs. The mFPPs were dissociated and replated for >6 passages (4 weeks on average). Upon reaching confluency at the end of passage 6, 8.9 × 108 ± 1 × 108 hiPSC-derived mFPPs had been generated from the initial 5 × 105 hiPSCs (Fig. 2c). Hence, we achieved a 720-fold increase in the number of mFPPs compared to the number at day 11 and a 1780-fold increase over the initial number of hiPSCs plated.
Expanded mFPPs give rise to higher numbers of DA neurons at the early stage of differentiation
We examined whether expanded mFPPs maintain their DA neuron differentiation potential compared to progenitors generated using a standard differentiation procedure. DA neuron differentiation was induced when the expanded mFPPs reached 90–100% confluency by switching the cultures to differentiation medium containing BDNF, GDNF, ascorbic acid, cAMP, β-TGF3 and DAPT (Fig. 1 and see Methods). After one week of induction (early phase of DA neuron differentiation), the expanded mFPPs cultures produced Tyrosine Hydroxylase positive (TH+) and βIII-Tubulin positive (βIII-Tub+) neurons (Fig. 3a). Quantification of differentiation by fluorescent assisted cell sorting (FACS) or microscopic analysis showed that although the proportion of βIII-Tub+ neurons was comparable to the standard procedure, the number of TH+ neurons was increased 6.8–7.4-fold (Fig. 3a–c). Hence, mFPP expansion did not interfere with general neuronal fate induction, resulting in an increase in TH+ neurons by day 20 (Figs 3 and S2).
mFPP expansion increases the potential to generate mature and functional DA neurons in the late stage of differentiation
We passaged the induced and differentiating mFPP cells on day 20, after expansion on Matrigel coated dishes, to Laminin/Fibronectin-coated plates (standard method: day 20; expansion method: day 20+exp) (Fig. 1). The cells from the expanded mFPP cultures and the standard cultures plated equally well. Morphologically, the mFPP cells already took on a more differentiated phenotype after one day (day 21) on Laminin/Fibronectin compared to cells cultured under standard conditions, the latter mostly had a flattened progenitor-like morphology (Figs 4 and S3). Three days after plating onto Laminin/Fibronectin-coated plates and induction of differentiation, the expanded mFPPs had generated neuron-like cells that extended processes throughout the culture dish (Figs 4 and S3). Many of the expanded mFPP progenitors condensed to form brain nucleus-like structures from which cells and processes radiated. This nucleation of the cells was less evident in the standard cultures of the same age (Figs 4 and S3). The condensation of the cells and the enhanced morphological changes were conserved over 6 passages (Fig. S3b). The differentiating neurons were maintained differentiation medium for up to 80 days in order to complete DA neuron maturation (late phase of DA neuron differentiation) (Fig. 1).
We analyzed the expression of DA neuron markers by immunostaining and RT-PCR during the course of the maturation procedure and compared the standard culture-derived and expanded mFPP-derived cells (Fig. 5a,b). From day 30 of maturation, some FOXA2+ cells expressed the DA neuron marker TH (Fig. 5a). In addition, TH+ DA neurons also expressed the transcription factor NURR1 (Fig. 5a). At late stages of the differentiation procedure, the TH+ DA neurons expressed markers of terminal differentiation including the vesicular monoamine transporter VMAT2 and G protein-activated inward rectifier potassium channel GIRK2 (Fig. 5a). Expression of additional markers of DA neuron differentiation including the Dopamine active transporter 1 DAT and the transcription factor Pituitary homeobox 3 PITX3 was detectable in the mFPP-derived neuron cultures by RT-PCR (Figs 5b and S4). Quantitative RT-PCR revealed that the expression of mature DA neuronal markers by neurons generated from expanded mFPPs was comparable to that of DA neurons generated by the standard procedure (Fig. 5c). However, expression of DAT was higher by DA neurons derived from expanded mFPPs than those derived by the standard method (Fig. 5c). In addition, with increasing passage number the mFPPs-derived neurons expressed higher levels of DAT suggesting that they either differentiate further or quicker than neurons generated by the standard procedure. These data suggest that expansion of mFPPs has a positive effect on the differentiation and maturation of DA neurons.
An important measure of DA neuron maturation and function is their functional release of dopamine29. We measured the levels of dopamine in the medium of DA neurons generated either by expanded mFPPs or via the standard protocol at the same day of differentiation. Liquid chromotography-mass spectrometric (LC-MS) analysis revealed consistently higher dopamine concentrations in the medium of expanded mFPP-derived DA neurons. This increase in dopamine levels in the medium of expanded mFPP-derived neurons started at day 40 of differentiation and became most prominent at day 60 (180.6 ± 13.2 nM versus 28.0 ± 11.5 nM) (Fig. 5d,e). The 6.5-fold increase in dopamine release by expanded mFPP-derived DA neurons supports an increased activity and quicker maturation.
To further assess functional maturation of DA neurons, we performed electrophysiological recordings at day 50 of differentiation (Fig. 5f–i). Individual neurons were recorded in whole-cell voltage-clamp and current-clamp configuration in order to detect hyperpolarization-activated cyclic-nucleotide-gated channel (HCN) activity, which is a typical characteristic of mature mesencephalic DA neurons. For voltage-clamp recordings the resting membrane potential was set to −60 mV. Simultaneously, the patched neurons were filled with biocytin for subsequent morphological analysis and TH immunostaining. 31.3% of the patched neurons (5 out of 16) displayed HCN-mediated currents (Fig. 5g), important for the typical voltage sag response of DA neurons upon hyperpolarizing current injections (Fig. 5f). In those cells, the HCN-current amplitude (at −120 mV) was on average 159 ± 41.2 pA (n = 5) compared to 0.39 ± 1.10 pA measured in non-HCN neurons (n = 11) (Figs 5h and S4). HCN-current positive neurons also showed a lower input resistance (average 0.26 ± 0.06 GΩ; n = 5) compared to HCN-negative neurons (average 2.81 ± 0.55 GΩ; n = 11) (Fig. 5i). All neurons with HCN current and sag response showed TH immunoreactivity confirming their DA neuron identity (Fig. 5j). These data indicate that DA neurons generated from expanded mFPPs reached a relatively advanced level of maturity in vitro and showed typical expression and electrophysiological characteristics of mesencephalic DA neurons comparable to neurons isolated from the brains of mice.
Expanded mFPPs give rise to DA neurons in vivo
We examined whether expanded mFPPs retain DA neuron differentiation potential in vivo by grafting cells at the progenitor stage and before differentiation into the ventral mesencephalon of recipient mouse embryos in utero using real-time ultrasound guided microcopy (Fig. 6a). The grafted human cells were detected in the mouse brain by their expression of the human nuclear antigen (HNA) or STEM121 to detect their cellular processes (Fig. 6b–d). Upon grafting into the mesencephalon of mouse embryos at embryonic day 11.5 (E11.5), and analysis at E18.5, expanded human mFPPs that had been passaged multiple times survived, integrated into the host and generated TH+ DA neurons in the graft area and in the region of the substantia nigra, adjacent to the endogenous DA neurons of the host (Fig. 6b). Graft-derived cells and processes were not detected in the striatum of host mice at this stage (data not shown). By postnatal day 10 (P10), human DA TH+STEM121+ neurons were still present at the original site of the graft and some TH+STEM121+ neurons were found integrated into the substantia nigra of the host (Fig. 6c). Moreover, grafted TH+STEM121+ human neurons in the brains of P10 hosts showed neuronal processes projecting to the striatum and arborizations within the striatum (Fig. 6d). We never observed overgrowth of the grafted cells nor tumor formation suggesting the expanded mFPPs have an additional advantage over the risk of grafting undifferentiated hiPSCs which could form teratomas.
Discussion
Here we describe and validate an important adaptation of the mFPP differentiation protocol for generating mesencephalic DA neurons. This protocol presents a number of advantages over previous protocols for generating and studying human DA neurons in culture. The mFPP protocol described previously takes advantage of the signaling networks which control midbrain formation and DA neuron differentiation10, 11, 27, 30, 31. Both genetic data in the mouse and in vitro differentiation experiments indicate that WNT signaling is important in roof plate function and mesencephalic DA neuron production in vivo 32, 33. Although mesencephalic DA neurons are generated from a ventral progenitor pool and roof plate cells are the most dorsal cells in the neural tube, both DA neurons and roof plate share expression of LMX1A34,35,36. In addition, WNT signaling has been shown to activate LMX1A expression by neural progenitors37. During brain development, Wnt1 is expressed by neural progenitors at the mid-hindbrain boundary (Isthmus) and expression extends anteriorly along the dorsal midline38. Wnt1 is an integral component of the Isthmus, controlling posterior midbrain and anterior hindbrain identity and development. DA neurons are born from mFPPs just anterior to the Isthmus39. The mFPP protocol also includes FGF8 in the initial induction steps. FGF8 is also a critical component of the Isthmus and an initiator of the organizer identity40, 41. SHH is well known for its ventralizing activity during development of the central nervous system42,43,44. SHH is initially expressed from the axial mesoderm and induces its own expression in floor plate cells. Hence, SHH contributes to the ventral mesencephalic fate of the neural progenitors. In addition, activation of the SHH pathway in combination with WNT promotes FOXA2/LMX1A double positive mFFPs with prominent DA neuron potential37. mFPP-derived DA neurons have been shown previously to be functional, and can rescue rodent and primate models of DA neuron degeneration upon grafting10, 11. However, one of the main challenges of the mFPP differentiation procedure has been to scale-up the production of neurons and establish reproducibility between human pluripotent cell lines. The direct differentiation of DA neurons from mFPPs is highly dependent upon the characteristics of the pluripotent cells and the efficiency of the initial floor plate determination step. Hence, we developed the culture conditions further to interrupt differentiation at the mFPP step and to expand these cells as a homogeneous population. The mFPPs continued to proliferate showing little spontaneously differentiation thus allowing for an increased period of expansion. We found that removing the activin-like receptor 5, 4 and 7 inhibitor SB-431542 and culturing the cells in n.2 medium in the presence of CHIR-99021 enhanced the expansion the maintenance of mFPPs. In contrast, presence of the activin-like receptor 2 and 3 inhibitor LDN-193189 was important for maintaining mFPPs. Addition of SHH and FGF8 did not increase mFPP expansion in n.2 medium (not shown). Previous studies have shown that the BMP4 inhibitor LDN-193189 is necessary to maintain/restrict human iPSCs to the neuroectodermal fate. On the other hand, the GSK3-β inhibitor CHIR99021 enhances survival of the FPPs at low cell density similar to its effects on embryonic stem cells to block differentiation and maintain self-renewal45. In addition, the Rock inhibitor Y-27632 was added to the expansion medium and promoted proliferation and maintained the morphology of FPPs in combination with CHIR99021. Y-27632 has been shown previously to enhance the survival and proliferation of dissociated human neural progenitor cells46, 47.
Interestingly, during extended expansion of the mFPPs, cytoplasmic expression of FOXA2 became apparent in addition to the nuclear localization. These findings support previous results indicating that Foxa2 is rapidly inactivated in vivo in mouse midbrain progenitors, and is necessary but not sufficient for specification of DA neurons in human pluripotent cells48, 49. Hence, we think that the increase in cytoplasmic expression and reduction of FOXA2 staining in the nucleus of mFPPs does not affect the DA neuron fate commitment and differentiation efficiency in vitro. It is likely that as in the mouse in vivo, FOXA2 in DA progenitors is critical for fate specification rather than DA neuron maintenance. Moreover, we propose that FOXA2 alone is not essential to enrich for DA neurons, but other proteins such as LMX1A are likely more critical for DA neuron enrichment and differentiation.
This expansion procedure presents a number of advantages over the protocol for direct and continuous differentiation from pluripotent cells. (1) Expanding mFPPs can be passaged several times and they retain their identity thereby enabling further amplification and increasing the number of DA neurons that can be generated. (2) Expanded mFPPs can be cryopreserved at each passage to generate a biobank of homogenous cells that can be thawed as a starting material for continued differentiation. (3) Finally, the mFPP expansion procedure is robust as similar results were obtained with three independent iPSC lines, NAS2 (all of the data shown here), Invitrogen iPSC (Episomal Human iPSC Line, Life Technologies, Cat. no. A13777) and a control line F3 (Collo et al. in preparation) (data not shown).
In previous descriptions of DA neuron differentiation using the mFPP protocol, the number of neurons generated seemed higher than in our experiments11, 27, 28. These differences between the studies could be due to differences in the quantification methods or differences in the differentiation potential of the pluripotent cells used. Therefore, we made direct comparisons of the standard and mFPP expansion methods using the same iPSCs (NAS2) and quantification procedures (microscopy and FACS). To this end, we performed direct back-to-back comparisons with sister cultures differentiated via the standard direct mFPP protocol11. We felt it was important to test and compare the DA neurons generated from expanded mFPPs with those produced by the standard protocol not only at the transcriptome and protein level but also at the functional level. We found that the expansion period had significant beneficial effects on the degree and rate of differentiation of DA neurons in the cultures. Not only did the proportion of DA neurons increase approximately 7-fold, but the neurons also showed increased functional maturity as assessed by electrophysiology and release of dopamine. Whether this increased differentiation potential is an indication of additional selection during the expansion period or whether exposure of the cells to an extended period of mFPP induction was the major benefit remains to be established. However, the expanded mFPPs retained the ability to differentiate into DA neurons in animal models and did not show signs of transformation. Thus, taking advantage of the endogenous signaling pathways that mediate mesencephalic DA neuron differentiation, the resulting human mFPPs retain the ability to respond to endogenous cues in the midbrain tissue of host mouse embryos and to generate neurons that integrate in the host substantia nigra and project to the striatum, their correct target region in the brain. Future analysis will be required to assess their integration into the nigro-striatal circuitry and to be able to functionally rescue animal modes of DA neuron degeneration. However, based on our analyses and the similarities between the DA neurons generated by expanded mFPPs and the standard direct mFPP-derived DA neurons described previously, they most likely will also have the potential to rescue symptoms in disease models11, 28.
In summary, we describe and validate a protocol for the long-term expansion and propagation of mFPPs that circumvents some of the challenges faced with other, none mFPP procedures, and that provides a robust means to bank highly homogeneous cultures of DA progenitors for gene function analysis and potential drug screening. This procedure may provide a convenient and scalable source of cells for eventual cell replacement therapy.
Methods
Animals and husbandry
C57/BL6 mice were kept on a 12-hour day/night cycle with food and water ad libitum under specified pathogen free conditions in accordance with Swiss federal and Swiss veterinary office regulations. All experimental protocols were approved by the ethics commission of BaselStadt, Basel, Switzerland. All experimental procedures were carried out in accordance with Swiss Federal and Swiss veterinary office regulations under license numbers 2537 and 2538.
Human iPSC culture and DA neuron differentiation
Human induced pluripotent stem cell (hiPSCs) lines NAS2, Invitrogen hiPSC and F3 (Dr. Ginetta Collo, manuscript submitted), were maintained on Matrigel in mTeSR-1 medium and passaged enzymatically with Accutase every 4–5 days (see online methods for details). DA neuron differentiation was induced using modifications to the FPP method11. Detailed description of the protocol can be found on the online version of the Methods.
RNA isolation and RT-PCR/qPCR analysis
For RNA isolation, cells were lysed directly in Trizol (Invitrogen) reagent. RNA was isolated according to the manufacturer’s instructions. 1 μg of total RNA was used for cDNA synthesis using oligo (dT) primers and Superscript III first strand kit (Invitrogen). For RT-PCR analysis, cDNA was amplified using 5x FIREPol Master Mix (Solis BioDyne, #04-11-00125). For RT-qPCR analysis, cDNA amplification was performed using SensiFast Sybr HiROX kit (Bioline, #Bio-92020). Primer information was provided in the Supplementary Table S2.
Fluorescence activated cell sorting for neuronal quantification
The protocol was adapted from Turac et al.50. After differentiation, cells were detached enzymatically with Accutase and a gentle resuspension was applied in order to obtain single cells. Primary antibodies used for flow cytometric analysis are shown in Supplementary Table S1. After primary antibody incubation, the cells were washed in PBS, centrifuged at 5000 rpm for 3 minutes and then resuspended in PBS and incubated with the appropriate secondary antibodies (Jackson Immunoresearch) for 30 minutes at room temperature on a shaker in the dark. Finally, cells were washed in PBS and centrifuged at least 3 times, resuspend in 2% FBS in PBS and filtered through a 40 μm cell sieve (Miltenyi Biotec). The cells were sorted on a fluorescence-activated cell sorter FACS Canto II (BD Biosciences) and analyzed using FACSDiva software (BD Biosciences). Data were additionally analyzed and presented using FlowJo software.
Quantification and statistical analysis
Stained coverslips or sections were analyzed with fixed photomultiplier settings on a Zeiss Observer with Apotome (Zeiss) or Zeiss LSM510 confocal microscope (Zeiss). Data are presented as averages of a minimum of three independent differentiation experiments. Statistical comparisons were determined by two-tailed unpaired Student’s t-test, Kruskal-Wallis with Dunn post-hoc test and two way ANOVA test for cross comparison of 3 and more data sets. Significance was established at * p < 0.05. In all graphs, deviance from mean was displayed as standard error of the mean, SEM.
References
Martin, G. R. Isolation of a pluripotent cell line from early mouse embryos cultured in medium conditioned by teratocarcinoma stem cells. Proc Natl Acad Sci USA 78, 7634–7638 (1981).
Thomson, J. A. et al. Embryonic stem cell lines derived from human blastocysts. Science 282, 1145–1147 (1998).
Dauer, W. & Przedborski, S. Parkinson’s disease: mechanisms and models. Neuron 39, 889–909 (2003).
Jankovic, J. Parkinson’s disease: clinical features and diagnosis. J Neurol Neurosurg Psychiatry 79, 368–376 (2008).
Fahn, S. et al. Levodopa and the progression of Parkinson’s disease. N Engl J Med 351, 2498–2508 (2004).
Lang, A. E. & Lozano, A. M. Parkinson’s disease. First of two parts. N Engl J Med 339, 1044–1053 (1998).
Olanow, C. W., Watts, R. L. & Koller, W. C. An algorithm (decision tree) for the management of Parkinson’s disease (2001): treatment guidelines. Neurology 56, S1–S88 (2001).
Cooper, O. et al. Differentiation of human ES and Parkinson’s disease iPS cells into ventral midbrain dopaminergic neurons requires a high activity form of SHH, FGF8a and specific regionalization by retinoic acid. Mol Cell Neurosci 45, 258–266 (2010).
Kawasaki, H. et al. Induction of midbrain dopaminergic neurons from ES cells by stromal cell-derived inducing activity. Neuron 28, 31–40 (2000).
Kirkeby, A. et al. Generation of regionally specified neural progenitors and functional neurons from human embryonic stem cells under defined conditions. Cell Rep 1, 703–714 (2012).
Kriks, S. et al. Dopamine neurons derived from human ES cells efficiently engraft in animal models of Parkinson’s disease. Nature 480, 547–551 (2011).
Perrier, A. L. et al. Derivation of midbrain dopamine neurons from human embryonic stem cells. Proc Natl Acad Sci USA 101, 12543–12548 (2004).
Theka, I. et al. Rapid generation of functional dopaminergic neurons from human induced pluripotent stem cells through a single-step procedure using cell lineage transcription factors. Stem Cells Transl Med 2, 473–479 (2013).
Tieng, V. et al. Engineering of midbrain organoids containing long-lived dopaminergic neurons. Stem Cells Dev 23, 1535–1547 (2014).
Baker, D. E. et al. Adaptation to culture of human embryonic stem cells and oncogenesis in vivo. Nat Biotechnol 25, 207–215 (2007).
Garitaonandia, I. et al. Increased risk of genetic and epigenetic instability in human embryonic stem cells associated with specific culture conditions. PLoS One 10, e0118307 (2015).
Li, J. Y., Christophersen, N. S., Hall, V., Soulet, D. & Brundin, P. Critical issues of clinical human embryonic stem cell therapy for brain repair. Trends Neurosci 31, 146–153 (2008).
Lund, R. J., Narva, E. & Lahesmaa, R. Genetic and epigenetic stability of human pluripotent stem cells. Nat Rev Genet 13, 732–744 (2012).
Serra, M., Brito, C., Correia, C. & Alves, P. M. Process engineering of human pluripotent stem cells for clinical application. Trends Biotechnol 30, 350–359 (2012).
Zhang, X. Q. & Zhang, S. C. Differentiation of neural precursors and dopaminergic neurons from human embryonic stem cells. Methods Mol Biol 584, 355–366 (2010).
Chambers, S. M. et al. Highly efficient neural conversion of human ES and iPS cells by dual inhibition of SMAD signaling. Nat Biotechnol 27, 275–280 (2009).
Hong, S., Kang, U. J., Isacson, O. & Kim, K. S. Neural precursors derived from human embryonic stem cells maintain long-term proliferation without losing the potential to differentiate into all three neural lineages, including dopaminergic neurons. J Neurochem 104, 316–324 (2008).
Li, W. et al. Rapid induction and long-term self-renewal of primitive neural precursors from human embryonic stem cells by small molecule inhibitors. Proc Natl Acad Sci USA 108, 8299–8304 (2011).
Belinsky, G. S. et al. Dopamine receptors in human embryonic stem cell neurodifferentiation. Stem Cells Dev 22, 1522–1540 (2013).
Hartfield, E. M. et al. Physiological characterisation of human iPS-derived dopaminergic neurons. PLoS One 9, e87388 (2014).
Fasano, C. A., Chambers, S. M., Lee, G., Tomishima, M. J. & Studer, L. Efficient derivation of functional floor plate tissue from human embryonic stem cells. Cell Stem Cell 6, 336–347 (2010).
Xi, J. et al. Specification of midbrain dopamine neurons from primate pluripotent stem cells. Stem Cells 30, 1655–1663 (2012).
Chen, Y. et al. Chemical Control of Grafted Human PSC-Derived Neurons in a Mouse Model of Parkinson’s Disease. Cell Stem Cell 18, 817–826 (2016).
Arias-Carrion, O. & Poppel, E. Dopamine, learning, and reward-seeking behavior. Acta Neurobiol Exp (Wars) 67, 481–488 (2007).
Denham, M. et al. Glycogen synthase kinase 3beta and activin/nodal inhibition in human embryonic stem cells induces a pre-neuroepithelial state that is required for specification to a floor plate cell lineage. Stem Cells 30, 2400–2411 (2012).
Doi, D. et al. Isolation of human induced pluripotent stem cell-derived dopaminergic progenitors by cell sorting for successful transplantation. Stem Cell Reports 2, 337–350 (2014).
Muroyama, Y., Fujihara, M., Ikeya, M., Kondoh, H. & Takada, S. Wnt signaling plays an essential role in neuronal specification of the dorsal spinal cord. Genes Dev 16, 548–553 (2002).
Joksimovic, M. et al. Wnt antagonism of Shh facilitates midbrain floor plate neurogenesis. Nat Neurosci 12, 125–131 (2009).
Andersson, E. et al. Identification of intrinsic determinants of midbrain dopamine neurons. Cell 124, 393–405 (2006).
Mishima, Y., Lindgren, A. G., Chizhikov, V. V., Johnson, R. L. & Millen, K. J. Overlapping function of Lmx1a and Lmx1b in anterior hindbrain roof plate formation and cerebellar growth. J Neurosci 29, 11377–11384 (2009).
Chizhikov, V. V. et al. Lmx1a regulates fates and location of cells originating from the cerebellar rhombic lip and telencephalic cortical hem. Proc Natl Acad Sci USA 107, 10725–10730 (2010).
Chung, S. et al. Wnt1-lmx1a forms a novel autoregulatory loop and controls midbrain dopaminergic differentiation synergistically with the SHH-FoxA2 pathway. Cell Stem Cell 5, 646–658 (2009).
Prakash, N. et al. A Wnt1-regulated genetic network controls the identity and fate of midbrain-dopaminergic progenitors in vivo. Development 133, 89–98 (2006).
Prakash, N. & Wurst, W. Specification of midbrain territory. Cell Tissue Res 318, 5–14 (2004).
Nakamura, H., Sato, T. & Suzuki-Hirano, A. Isthmus organizer for mesencephalon and metencephalon. Dev Growth Differ 50(Suppl 1), S113–118 (2008).
Partanen, J. FGF signalling pathways in development of the midbrain and anterior hindbrain. J Neurochem 101, 1185–1193 (2007).
Chiang, C. et al. Cyclopia and defective axial patterning in mice lacking Sonic hedgehog gene function. Nature 383, 407–413 (1996).
Fuccillo, M., Joyner, A. L. & Fishell, G. Morphogen to mitogen: the multiple roles of hedgehog signalling in vertebrate neural development. Nat Rev Neurosci 7, 772–783 (2006).
Fuccillo, M., Rallu, M., McMahon, A. P. & Fishell, G. Temporal requirement for hedgehog signaling in ventral telencephalic patterning. Development 131, 5031–5040 (2004).
Ying, Q. L. et al. The ground state of embryonic stem cell self-renewal. Nature 453, 519–523 (2008).
Rungsiwiwut, R. et al. The ROCK inhibitor Y-26732 enhances the survival and proliferation of human embryonic stem cell-derived neural progenitor cells upon dissociation. Cells Tissues Organs 198, 127–138 (2013).
Lamas, N. J. et al. Neurotrophic requirements of human motor neurons defined using amplified and purified stem cell-derived cultures. PLoS One 9, e110324 (2014).
Aguila, J. C. et al. Selection Based on FOXA2 Expression Is Not Sufficient to Enrich for Dopamine Neurons From Human Pluripotent Stem Cells. Stem Cells Transl Med 3, 1032–1042 (2014).
Ferri, A. L. et al. Foxa1 and Foxa2 regulate multiple phases of midbrain dopaminergic neuron development in a dosage-dependent manner. Development 134, 2761–2769 (2007).
Turac, G. et al. Combined flow cytometric analysis of surface and intracellular antigens reveals surface molecule markers of human neuropoiesis. PLoS One 8, e68519 (2013).
Acknowledgements
We are grateful to Monique Wittig Kieffer for the technical assistance. This work was supported by Hoffmann-La Roche and NeuroStemX of the SystemsX.ch project of the Swiss National Science foundation.
Author information
Authors and Affiliations
Contributions
S.F., G.C., and V.T. designed the protocol and the experiments; S.F. performed the experiments and analyzed the data; K.B. and J.B. performed the neuronal electrophysiology; T.K. provided NAS2 hiPSC line; S.M. analyzed the dopamine levels; K.C., R.J., A.L.G. and M.G. discussed the experiments, and hiPSC culture organization; S.F., G.C., A.L.G. and V.T. wrote the manuscript; G.C. and V.T. supervised the project.
Corresponding author
Ethics declarations
Competing Interests
The authors declare that they have no competing interests.
Additional information
Publisher's note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Electronic supplementary material
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Fedele, S., Collo, G., Behr, K. et al. Expansion of human midbrain floor plate progenitors from induced pluripotent stem cells increases dopaminergic neuron differentiation potential. Sci Rep 7, 6036 (2017). https://doi.org/10.1038/s41598-017-05633-1
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-017-05633-1
- Springer Nature Limited
This article is cited by
-
Early deficits in an in vitro striatal microcircuit model carrying the Parkinson’s GBA-N370S mutation
npj Parkinson's Disease (2024)
-
Unravelling the Parkinson’s puzzle, from medications and surgery to stem cells and genes: a comprehensive review of current and future management strategies
Experimental Brain Research (2024)
-
Challenges in the clinical advancement of cell therapies for Parkinson’s disease
Nature Biomedical Engineering (2023)
-
Pluripotent Stem Cell-derived Dopaminergic Neurons for Studying Developmental Neurotoxicity
Stem Cell Reviews and Reports (2023)
-
Targeting neuronal lysosomal dysfunction caused by β-glucocerebrosidase deficiency with an enzyme-based brain shuttle construct
Nature Communications (2023)