Advances in mechanistic knowledge of human neurological disorders have been hindered by the lack of adequate human in vitro models. Three-dimensional (3D) cellular models displaying higher biological relevance are gaining momentum; however, their lack of robustness and scarcity of analytical tools adapted to three dimensions hampers their widespread implementation. Herein we show that human midbrain-derived neural progenitor cells, cultured as 3D neurospheres in stirred culture systems, reproducibly differentiate into complex tissue-like structures containing functional dopaminergic neurons, as well as astrocytes and oligodendrocytes. Moreover, an extensive toolbox of analytical methodologies has been adapted to 3D neural cell models, allowing molecular and phenotypic profiling and interrogation. The generated neurons underwent synaptogenesis and elicit spontaneous Ca2+ transients. Synaptic vesicle trafficking and release of dopamine in response to depolarizing stimuli was also observed. Under whole-cell current-and-voltage clamp, recordings showed polarized neurons (Vm=−70 mV) and voltage-dependent potassium currents, which included A-type-like currents. Glutamate-induced currents sensitive to α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid and N-methyl-D-aspartate antagonists revealed the existence of functional glutamate receptors. Molecular and phenotypic profiling showed recapitulation of midbrain patterning events, and remodeling toward increased similarity to human brain features, such as extracellular matrix composition and metabolic signature. We have developed a robust and reproducible human 3D neural cell model, which may be extended to patient-derived induced pluripotent stem cells, broadening the applicability of this model.
Get full access to this article
View all access options for this article.
References
1.
LinR.-Z., LinR.-Z., and ChangH.-Y.Recent advances in three-dimensional multicellular spheroid culture for biomedical research. Biotechnol J, 3, 1172, 2008.
2.
GriffithL.G., and SwartzM.A.Capturing complex 3D tissue physiology in vitro. Nat Rev Mol Cell Biol, 7, 211, 2006.
3.
MillerG.Is pharma running out of brainy ideas? Science, 329, 502, 2010.
4.
SchüleB., PeraR.A.R., and LangstonJ.W.Can cellular models revolutionize drug discovery in Parkinson's disease?. Biochim Biophys Acta, 1792, 1043, 2009.
5.
FennemaE., RivronN., RouwkemaJ., van BlitterswijkC., and de BoerJ.Spheroid culture as a tool for creating 3D complex tissues. Trends Biotechnol, 31, 108, 2013.
6.
PampaloniF., ReynaudE.G., and StelzerE.H.K.The third dimension bridges the gap between cell culture and live tissue. Nat Rev Mol Cell Biol, 8, 839, 2007.
7.
PotterW., KalilR.E., and KaoW.J.Biomimetic material systems for neural progenitor cell-based therapy. Front Biosci, 13, 806, 2008.
8.
BreslinS., and O'DriscollL.Three-dimensional cell culture: the missing link in drug discovery. Drug Discov Today, 18, 240, 2013.
9.
MoorsM., RockelT.D., AbelJ., ClineJ.E., GassmannK., SchreiberT., et al.Human neurospheres as three-dimensional cellular systems for developmental neurotoxicity testing. Environ Health Perspect, 117, 1131, 2009.
10.
BritoC., SimãoD., CostaI., MalpiqueR., PereiraC.I., FernandesP., et al.3D cultures of human neural progenitor cells: dopaminergic differentiation and genetic modification. Methods, 56, 452, 2012.
11.
StorchA., PaulG., CseteM., BoehmB.O., CarveyP.M., KupschA., et al.Long-term proliferation and dopaminergic differentiation of human mesencephalic neural precursor cells. Exp Neurol, 170, 317, 2001.
SerraM., CorreiaC., MalpiqueR., BritoC., JensenJ., BjorquistP., et al.Microencapsulation technology: a powerful tool for integrating expansion and cryopreservation of human embryonic stem cells. PLoS One, 6, e23212, 2011.
14.
DeerinckT.J., BushongE.A., ThorA., and EllismanM.H.NCMIR methods for 3D EM: a new protocol for preparation of biological specimens for serial block face scanning electron microscopy. Available from: http://ncmir.ucsd.edu/sbfsem-protocol.pdf, 2010 (Last accessed January19, 2014).
15.
DuarteT.M., CarinhasN., SilvaA.C., AlvesP.M., and TeixeiraA.P.1H-NMR protocol for exometabolome analysis of cultured mammalian cells. Methods Mol Biol, 1104, 237, 2014.
16.
LivakK.J., and SchmittgenT.D.Analysis of relative gene expression data using real-time quantitative PCR and the 2(−delta delta C(T)) method. Methods, 25, 402, 2001.
17.
SmythG.K.Limma: linear models for microarray data. In: GentlemanR., CareyV., HuberW., IrizarryR., and DudoitS., eds. Bioinformatics and Computational Biology Solutions Using R and Bioconductor. New York: Springer, 2005, pp. 397–420.
18.
MaereS., HeymansK., and KuiperM.BiNGO: a cytoscape plugin to assess overrepresentation of gene ontology categories in biological networks. Bioinformatics, 21, 3448, 2005.
19.
BenjaminiY., and HochbergY.Controlling the false discovery rate: a practical and powerful approach to multiple testing. J R Stat Soc Ser B, 57, 289, 1995.
20.
LakshmanaM.K., and RajuT.R.An isocratic assay for norepinephrine, dopamine, and 5-hydroxytryptamine using their native fluorescence by high-performance liquid chromatography with fluorescence detection in discrete brain areas of rat. Anal Biochem, 246, 166, 1997.
21.
CarinhasN., BernalV., MonteiroF., CarrondoM.J.T., OliveiraR., and AlvesP.M.Improving baculovirus production at high cell density through manipulation of energy metabolism. Metab Eng, 12, 39, 2010.
22.
LimaP.A., and MarrionN.V.Mechanisms underlying activation of the slow AHP in rat hippocampal neurons. Brain Res, 1150, 74, 2007.
23.
VicenteM.I., CostaP.F., and LimaP.A.Galantamine inhibits slowly inactivating K+ currents with a dual dose-response relationship in differentiated N1E-115 cells and in CA1 neurones. Eur J Pharmacol, 634, 16, 2010.
24.
NishioT., FurukawaS., AkiguchiI., and SunoharaN.Medial nigral dopamine neurons have rich neurotrophin support in humans. Neuroreport, 9, 2847, 1998.
25.
NumanS., GallC.M., and SeroogyK.B.Developmental expression of neurotrophins and their receptors in postnatal rat ventral midbrain. J Mol Neurosci, 27, 245, 2005.
26.
ZamanV., NelsonM.E., GerhardtG.A., and RohrerB.Neurodegenerative alterations in the nigrostriatal system of trkB hypomorphic mice. Exp Neurol, 190, 337, 2004.
27.
JontesJ.D., and SmithS.J.Filopodia, spines, and the generation of synaptic diversity. Neuron, 27, 11, 2000.
28.
LendvaiB., SternE.A., ChenB., and SvobodaK.Experience-dependent plasticity of dendritic spines in the developing rat barrel cortex in vivo. Nature, 404, 876, 2000.
29.
IwamaE., TsuchimotoD., IyamaT., SakumiK., NakagawaraA., TakayamaK., et al.Cancer-related PRUNE2 protein is associated with nucleotides and is highly expressed in mature nerve tissues. J Mol Neurosci, 44, 103, 2011.
30.
BandtlowC.E., and ZimmermannD.R.Proteoglycans in the developing brain: new conceptual insights for old proteins. Physiol Rev, 80, 1267, 2000.
31.
DwyerC., and MatthewsR.The neural extracellular matrix, cell adhesion molecules and proteolysis in glioma invasion and tumorigenicity. In: GaramiM., ed. Molecular Targets of CNS Tumors. Rijeka: InTech, 2011, pp. 239–264.
32.
GaffieldM.A., and BetzW.J.Imaging synaptic vesicle exocytosis and endocytosis with FM dyes. Nat Protoc, 1, 2916, 2006.
33.
HoopmannP., RizzoliS.O., and BetzW.J.Imaging synaptic vesicle recycling by staining and destaining vesicles with FM dyes. Cold Spring Harb Protoc, 2012, 77, 2012.
34.
IkegayaY., Le Bon-JegoM., and YusteR.Large-scale imaging of cortical network activity with calcium indicators. Neurosci Res, 52, 132, 2005.
35.
TashiroA., GoldbergJ., and YusteR.Calcium oscillations in neocortical astrocytes under epileptiform conditions. J Neurobiol, 50, 45, 2002.
36.
CoetzeeW.A., AmarilloY., ChiuJ., ChowA., LauD., McCormackT., et al.Molecular diversity of K+ channels. Ann N Y Acad Sci, 868, 233, 1999.
37.
KorotkovaT.M., PonomarenkoA.A., BrownR.E., and HaasH.L.Functional diversity of ventral midbrain dopamine and GABAergic neurons. Mol Neurobiol, 29, 243, 2004.
38.
BodeaG.O., and BlaessS.Organotypic slice cultures of embryonic ventral midbrain: a system to study dopaminergic neuronal development in vitro. J Vis Exp (59), e3350, 2012.
39.
SchwarzJ.Developmental perspectives on human midbrain-derived neural stem cells. Parkinsonism Relat Disord, 13(S3), S466, 2007.
40.
SchaarschmidtG., SchewtschikS., KraftR., WegnerF., EilersJ., SchwarzJ., et al.A new culturing strategy improves functional neuronal development of human neural progenitor cells. J Neurochem, 109, 238, 2009.
Alves dos SantosM.T.M., and SmidtM.P.En1 and Wnt signaling in midbrain dopaminergic neuronal development. Neural Dev, 6, 1, 2011.
43.
AngS.-L.Transcriptional control of midbrain dopaminergic neuron development. Development, 133, 3499, 2006.
44.
PrakashN., and WurstW.Genetic networks controlling the development of midbrain dopaminergic neurons. J Physiol, 575, 403, 2006.
45.
AbeliovichA., and HammondR.Midbrain dopamine neuron differentiation: factors and fates. Dev Biol, 304, 447, 2007.
46.
WegnerF., KraftR., BusseK., HärtigW., SchaarschmidtG., SchwarzS.C., et al.Functional and molecular analysis of GABA receptors in human midbrain-derived neural progenitor cells. J Neurochem, 107, 1056, 2008.
47.
GoldbergJ.L., and BarresB.A.The relationship between neuronal survival and regeneration. Annu Rev Neurosci, 23, 579, 2000.
48.
MichelP.P., and AgidY.Chronic activation of the cyclic AMP signaling pathway promotes development and long-term survival of mesencephalic dopaminergic neurons. J Neurochem, 67, 1633, 1996.
49.
ZahirT., ChenY.F., MacDonaldJ.F., LeipzigN., TatorC.H., and ShoichetM.S.Neural stem/progenitor cells differentiate in vitro to neurons by the combined action of dibutyryl cAMP and interferon-gamma. Stem Cells Dev, 18, 1423, 2009.
50.
TioM., TanK.H., LeeW., WangT.T., and UdolphG.Roles of db-cAMP, IBMX and RA in aspects of neural differentiation of cord blood derived mesenchymal-like stem cells. PLoS One, 5, e9398, 2010.
51.
ZwingmannC., and LeibfritzD.Regulation of glial metabolism studied by 13C-NMR. NMR Biomed, 16, 370, 2003.
52.
CruzF., VillalbaM., García-EspinosaM.A., BallesterosP., BogónezE., SatrústeguiJ., et al.Intracellular compartmentation of pyruvate in primary cultures of cortical neurons as detected by (13)C NMR spectroscopy with multiple (13)C labels. J Neurosci Res, 66, 771, 2001.
53.
FornazariM., NascimentoI.C., NeryA.A., da SilvaC.C.C., KowaltowskiA.J., and UlrichH.Neuronal differentiation involves a shift from glucose oxidation to fermentation. J Bioenerg Biomembr, 43, 531, 2011.
54.
MagistrettiP.J., and AllamanI.Brain energy metabolism. In: PfaffD.W., ed. Neuroscience in the 21st Century: From Basic to Clin. New York: Springer, 2013, pp. 1591–1620.
55.
ZalaD., HinckelmannM.-V., YuH., Lyra da CunhaM.M., LiotG., CordelièresF.P., et al.Vesicular glycolysis provides on-board energy for fast axonal transport. Cell, 152, 479, 2013.
56.
SchillingS., WasternackC., and DemuthH.-U.Glutaminyl cyclases from animals and plants: a case of functionally convergent protein evolution. Biol Chem, 389, 983, 2008.
57.
KumarA., and BachhawatA.K.Pyroglutamic acid: throwing light on a lightly studied metabolite. Curr Sci, 102, 288, 2012.
58.
BixelM.G., EngelmannJ., WillkerW., HamprechtB., and LeibfritzD.Metabolism of [U-(13)C]leucine in cultured astroglial cells. Neurochem Res, 29, 2057, 2004.
59.
FolmesC.D.L., NelsonT.J., DzejaP.P., and TerzicA.Energy metabolism plasticity enables stemness programs. Ann N Y Acad Sci, 1254, 82, 2012.
ZitoK., KnottG., ShepherdG.M.G., ShenolikarS., and SvobodaK.Induction of spine growth and synapse formation by regulation of the spine actin cytoskeleton. Neuron, 44, 321, 2004.
62.
ValtortaF., PozziD., BenfenatiF., and FornasieroE.F.The synapsins: multitask modulators of neuronal development. Semin Cell Dev Biol, 22, 378, 2011.
63.
EvansG.J.O., and CousinM.A.Simultaneous monitoring of three key neuronal functions in primary neuronal cultures. J Neurosci Methods, 160, 197, 2007.
64.
SchaarschmidtG., WegnerF., SchwarzS.C., SchmidtH., and SchwarzJ.Characterization of voltage-gated potassium channels in human neural progenitor cells. PLoS One, 4, e6168, 2009.
65.
WegnerF., KraftR., BusseK., SchaarschmidtG., HärtigW., SchwarzS.C., et al.Glutamate receptor properties of human mesencephalic neural progenitor cells: NMDA enhances dopaminergic neurogenesis in vitro. J Neurochem, 111, 204, 2009.
66.
KirkebyA., GrealishS., WolfD.A., NelanderJ., WoodJ., LundbladM., et al.Generation of regionally specified neural progenitors and functional neurons from human embryonic stem cells under defined conditions. Cell Rep, 1, 703, 2012.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
