Chemical Conversion of Human Fetal Astrocytes into Neurons through Modulation of Multiple Signaling Pathways

Yin, Jiu Chao; Zhang, Lei; Ning, Xin; Wang, Yue; Lee, Grace; Hou, Xiao Yi; Lei, Zhuo Fan; Zhang, Fengyu; Dong, Feng Ping; Wu, Gang; Chen, Gong

doi:10.1016/j.stemcr.2019.01.003

Cited by 76 publications

(109 citation statements)

References 40 publications

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“…Besides NeuroD1, other groups have reported that expression of transcription factors Ngn2, Ascl1, Sox2, or combinations of factors can also convert internal glial cells into neurons in the brain or spinal cord (Gascon et al, 2016; Grande et al, 2013; Jorstad et al, 2017; Liu et al, 2015; Niu et al, 2015; Niu et al, 2013; Pereira et al, 2017; Rivetti di Val Cervo et al, 2017; Su et al, 2014). In addition to the overexpression of transcription factors, we have also demonstrated that small molecules can directly convert human glial cells into functional neurons (Yin et al, 2019; Zhang et al, 2015) through transcriptome-wide activation of neuronal genes (Ma et al, 2019). Other groups also reported direct chemical reprogramming of glial cells (Gao et al, 2017) or fibroblast cells (Ambasudhan et al, 2011; Hu et al, 2015; Li et al, 2015) into neurons.…”

Section: Introductionmentioning

confidence: 99%

In Vivo Neuroregeneration to Treat Ischemic Stroke in Adult Non-Human Primate Brains through NeuroD1 AAV-based Gene Therapy

Yang

Feng

et al. 2019

Preprint

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Stroke is a leading cause of death and disability but most of the clinical trials have failed in the past, despite our increasing understanding of the molecular and pathological mechanisms underlying stroke. While many signaling pathways have been identified in the aftermath of stroke, the majority of current approaches are focusing on neural protection rather than neuroregeneration. In this study, we report an in vivo neural regeneration approach to convert brain internal reactive astrocytes into neurons through ectopic expression of a neural transcription factor NeuroD1 in adult non-human primate (NHP) brains following ischemic stroke. We demonstrate that NeuroD1 AAV-based gene therapy can convert reactive astrocytes into neurons with high efficiency (90%), but astrocytes are never depleted in the NeuroD1-expressed areas, consistent with the proliferative capability of astrocytes. The NeuroD1-mediated in vivo astrocyte-to-neuron (AtN) conversion in monkey cortex following ischemic stroke increased local neuronal density, reduced reactive microglia, and surprisingly protected parvalbumin interneurons in the converted areas. The NeuroD1 gene therapy showed a broad time window, from 10 days to 30 days following ischemic stroke, in terms of exerting its neuroregenerative and neuroprotective effects. The cortical astrocyte-converted neurons also showed Tbr1+ cortical neuron identity, similar to our earlier findings in rodent animal models. Unexpectedly, NeuroD1 expression in converted neurons showed a significant decrease after 6 months of viral infection, suggesting a potential self-regulatory mechanism of NeuroD1 in adult mature neurons of NHPs. These results suggest that in vivo cell conversion through NeuroD1-based gene therapy may be an effective approach to regenerate new neurons in adult primate brains for tissue repair.

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Section: Introductionmentioning

confidence: 99%

In Vivo Neuroregeneration to Treat Ischemic Stroke in Adult Non-Human Primate Brains through NeuroD1 AAV-based Gene Therapy

Yang

Feng

et al. 2019

Preprint

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“…Recently, the use of diverse small molecule cocktails to reprogram astrocytes into neuronal cells has achieved considerable success [13,14]. Yin et al proved that using three to four small molecules (SB431542, CHIR99021, LDN193189, and DAPT) or their respective functional analogues to modulate the TGF-β/SMAD, BMP, NOTCH, and WNT pathways was su cient to reprogram human foetal astrocytes into neurons [14]. However, RA characteristics are also regulated by other signals, such as the JAK/STAT and P38 MAPK pathways and post-transcriptional levels of several non-coding RNAs.…”

Section: Discussionmentioning

confidence: 99%

“…Alternatively, the biological effects of small molecules are netuneable and reversible; thus, their development into pharmaceuticals can provide broad application prospects for neuronal reprogramming without genetic modi cation [12]. The small molecule cocktail of VPA, CHIR99021, RepSox, forskolin, i-BET151, and ISX-9 reprogrammed adult astrocytes into mainly glutamatergic neurons [13], and foetal astrocyte-derived functional neurons could be obtained via mediation by a small molecule cocktail of SB431542, LDN193189, CHIR99021, and 2,4-diamino-5phenylthiazole (DAPT) [14]. However, since the signals activated or inhibited by each small molecule differ, inconsistent chemical combinations lead to variable neuronal properties and conversion e ciencies.…”

Section: Introductionmentioning

confidence: 99%

MiR-124 and small molecules synergistically regulate the direct generation of neuronal cells from rat cortical reactive astrocytes

Zheng

Huang

et al. 2020

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Background：Irreversible neuron loss caused by central nervous system injuries usually lead to persistent neurological dysfunction. Reactive astrocytes, because of their high proliferative capacity, proximity to neuronal lineage, and significant involvement in glial scarring, are ideal starting cells for neuronal regeneration. Having previously identified several small molecules as important regulators of astrocyte-to-neuron reprogramming, our aim in this study was to explore whether other small molecules and miR-124, a key neural differentiation mediator, could co-regulate reactive astrocyte-to-neuron conversion.Methods: MiR-124, ruxolitinib, SB203580, and forskolin were used to induce postnatal rat cortex reactive astrocytes, and the neuronal phenotype of the induced cells was characterised. To understand the genetic changes, RNA-sequencing analyses were performed on reactive astrocytes, induced neurons, and rat neurons, and the mechanisms underlying the regulatory role of miR-124 during the neuronal conversion was explored.Results：MiR-124, ruxolitinib, SB203580, and forskolin could co-convert rat cortical reactive astrocytes into neurons. The induced cells had reduced astroglial properties, displayed typical neuronal morphologies, and expressed neuronal markers, reflecting 25.9% of cholinergic neurons. Gene analysis revealed that induced neuron gene expression patterns were more similar to that of primary neurons than of initial reactive astrocytes. On the molecular level, miR-124-driven neuronal differentiation of reactive astrocytes was via targeting of the SOX9-NFIA-HES1 axis to inhibit HES1 expression.Conclusions：Providing a novel approach for inducing endogenous rat cortical reactive astrocytes into neurons by co-regulation involving miR-124 and three small molecules, our research has potential implications for inhibiting glial scar formation and promoting neuronal regeneration after central nervous system injury or disease.

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“…Additionally, electrophysiological analysis has proven valuable to define functional neurons, as neurons have very specific electrophysiological features like hyperpolarized membrane potential and spontaneous and triggered action potentials [32,46,49]. In this regard, iNs have been shown to express neuronal markers, show mature neuronal morphology, and possess both spontaneous and induced postsynaptic currents [15,57,81,118,119]. In this regard, iNs have been shown to express neuronal markers, show mature neuronal morphology, and possess both spontaneous and induced postsynaptic currents [15,57,81,118,119].…”

Section: You Are What You Eat: Metabolic Hallmarks Of In Conversionmentioning

confidence: 99%

“…For many studies that are not neuronal function-centered, Ca 2+ imaging and multielectrode arrays can be used as surrogates for electrophysiology and can further deliver insights into neuronal network activity in vitro [20,21,119,120]. In this regard, iNs have been shown to express neuronal markers, show mature neuronal morphology, and possess both spontaneous and induced postsynaptic currents [15,57,81,118,119]. Differentiating neurons in the developing brain and in iPSC differentiation pass through stages that specifically allow them to participate in functional circuits [121], while iNs skip these stages.…”

Section: Updating Our Criteria To Define Neuronsmentioning

confidence: 99%

Next‐generation disease modeling with direct conversion: a new path to old neurons

2019

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Within just over a decade, human reprogramming-based disease modeling has developed from a rather outlandish idea into an essential part of disease research. While iPSCs are a valuable tool for modeling developmental and monogenetic disorders, their rejuvenated identity poses limitations for modeling age-associated diseases. Direct cell-type conversion of fibroblasts into induced neurons (iNs) circumvents rejuvenation and preserves hallmarks of cellular aging. iNs are thus advantageous for modeling diseases that possess strong age-related and epigenetic contributions and can complement iPSCbased strategies for disease modeling. In this review, we provide an overview of the state of the art of direct iN conversion and describe the key epigenetic, transcriptomic, and metabolic changes that occur in converting fibroblasts. Furthermore, we summarize new insights into this fascinating process, particularly focusing on the rapidly changing criteria used to define and characterize in vitro-born human neurons. Finally, we discuss the unique features that distinguish iNs from other reprogramming-based neuronal cell models and how iNs are relevant to disease modeling.

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Chemical Conversion of Human Fetal Astrocytes into Neurons through Modulation of Multiple Signaling Pathways

Cited by 76 publications

References 40 publications

In Vivo Neuroregeneration to Treat Ischemic Stroke in Adult Non-Human Primate Brains through NeuroD1 AAV-based Gene Therapy

In Vivo Neuroregeneration to Treat Ischemic Stroke in Adult Non-Human Primate Brains through NeuroD1 AAV-based Gene Therapy

MiR-124 and small molecules synergistically regulate the direct generation of neuronal cells from rat cortical reactive astrocytes

Next‐generation disease modeling with direct conversion: a new path to old neurons

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