Neural Stem Cells Expressing bFGF Reduce Brain Damage and Restore Sensorimotor Function after Neonatal Hypoxia-Ischemia

Ye, Qingsong; Wu, Yanqing; Wu, Jing; Zou, Shuang; Al-Zaazaai, Ali Ahmed; Zhang, Hongyu; Shi, Hongxue; Xie, Ling; Liu, Yanlong; Xu, Ke; He, Huacheng; Zhang, Fabiao; Ji, Yiming; He, Yan; Xiao, Jian

doi:10.1159/000486226

Cited by 15 publications

(12 citation statements)

References 37 publications

(25 reference statements)

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“…However, a closer look at the mechanisms and pathways of intranasal cell delivery discovered by us 11 years ago, reveals that cells use nearly the same delivery mechanisms (besides active migration) as described for peptides and growth factors [43]. This is evidenced by their rapid appearance within the brain, just a few hours after administration as shown by us for MSC [10,44] or within a day as reported by other groups for NSC [45,46]. Hereby, it is suggested that besides active migration promoting the cell distribution within the brain, a complex of tools such as bulk flow, vessel pulsation when the cells move along perivascular spaces, as well as nose-to-brain interconnection of lymphatic and cerebrospinal fluid systems contribute to their rapid entry into the brain and further distribution to different brain areas [43,44].…”

Section: Discussionsupporting

confidence: 59%

Cell motility and migration as determinants of stem cell efficacy

Danielyan

Schwab

Siegel³

et al. 2020

EBioMedicine

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Background Stem cells` (SC) functional heterogeneity and its poorly understood aetiology impedes clinical development of cell-based therapies in regenerative medicine and oncology. Recent studies suggest a strong correlation between the SC migration potential and their therapeutic efficacy in humans. Designating SC migration as a denominator of functional SC heterogeneity, we sought to identify highly migrating subpopulations within different SC classes and evaluate their therapeutic properties in comparison to the parental non-selected cells. Methods We selected highly migrating subpopulations from mesenchymal and neural SC (sMSC and sNSC), characterized their features including but not limited to migratory potential, trophic factor release and transcriptomic signature. To assess lesion-targeted migration and therapeutic properties of isolated subpopulations in vivo, surgical transplantation and intranasal administration of MSCs in mouse models of glioblastoma and Alzheimer's disease respectively were performed. Findings Comparison of parental non-selected cells with isolated subpopulations revealed superior motility and migratory potential of sMSC and sNSC in vitro. We identified podoplanin as a major regulator of migratory features of sMSC/sNSC. Podoplanin engineering improved oncovirolytic activity of virus-loaded NSC on distantly located glioblastoma cells. Finally, sMSC displayed more targeted migration to the tumour site in a mouse glioblastoma model and remarkably higher potency to reduce pathological hallmarks and memory deficits in transgenic Alzheimer's disease mice. Interpretation Functional heterogeneity of SC is associated with their motility and migration potential which can serve as predictors of SC therapeutic efficacy. Funding This work was supported in part by the Robert Bosch Stiftung (Stuttgart, Germany) and by the IZEPHA grant.

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Section: Discussionsupporting

confidence: 59%

Cell motility and migration as determinants of stem cell efficacy

Danielyan

Schwab

Siegel³

et al. 2020

EBioMedicine

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“…In the current study, TNF-α-pretreated-hNPCs and non-pretreated hNPCs were injected 3 days after induction of HI brain injury. In animal models of HI brain injury, stem cells have been transplanted between the first hour and 7 days after brain injury, with different degrees of beneficial outcome [14,[39][40][41]. Most of these studies have a variety of types, including transplant cell types, injury models, evaluation methods, etc., making it difficult to determine the best time for stem/progenitor cell therapy.…”

Section: Discussionmentioning

confidence: 99%

TNF-α Pretreatment Improves the Survival and Function of Transplanted Human Neural Progenitor Cells Following Hypoxic-Ischemic Brain Injury

Kim

Jung

et al. 2020

Cells

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Neural progenitor cells (NPCs) therapy offers great promise in hypoxic-ischemic (HI) brain injury. However, the poor survival of implanted NPCs in the HI host environment limits their therapeutic effects. Tumor necrosis factor-alpha (TNF-α) is a pleiotropic cytokine that is induced in response to a variety of pathological processes including inflammation and immunity. On the other hand, TNF-α has protective effects on cell apoptosis and death and affects the differentiation, proliferation, and survival of neural stem/progenitor cells in the brain. The present study investigated whether TNF-α pretreatment on human NPCs (hNPCs) enhances the effectiveness of cell transplantation therapy under ischemic brain. Fetal brain tissue-derived hNPCs were pretreated with TNF-α before being used in vitro experiments or transplantation. TNF-α significantly increased expression of cIAP2, and the use of short hairpin RNA-mediated knockdown of cIAP2 demonstrated that cIAP2 protected hNPCs against HI-induced cytotoxicity. In addition, pretreatment of hNPCs with TNF-α mediated neuroprotection by altering microglia polarization via increased expression of CX3CL1 and by enhancing expression of neurotrophic factors. Furthermore, transplantation of TNF-α-treated hNPCs reduced infarct volume and improved neurological functions in comparison with non-pretreated hNPCs or vehicle. These findings show that TNF-α pretreatment, which protects hNPCs from HI-injured brain-induced apoptosis and increases neuroprotection, is a simple and safe approach to improve the survival of transplanted hNPCs and the therapeutic efficacy of hNPCs in HI brain injury.

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“…The bFGF is an important neurotrophin which possesses superior properties to promote neural stem cell (NSC) migration, proliferation, and self-renewal ( Yeoh and de Haan, 2007 ). Ye et al further informed that the bFGF could promote the survival and differentiation of NSCs to reduce brain damage and restore sensorimotor function after neonatal hypoxia-ischemia ( Ye et al, 2018 ). The bFGF has also been reported to be able to maintain the survival of neuronal and glial cells, probably by protecting neurons from ROS-induced cell death and antagonizing the neuronal apoptosis induced by glutamate ( Liu and Zhu, 1999 ).…”

Section: The Underlying Mechanisms Of Basic Fibroblast Growth Factor In Dental Pulp Repair and Regenerationmentioning

confidence: 99%

“…In summary, the results from the aforementioned studies emphasize the important role of the bFGF in neural differentiation and promise new therapeutic strategies by using the bFGF to treat neurological diseases and repair neuronal damage, such as spinal cord injury (SCI), Parkinson’s disease, neonatal hypoxia-ischemia (NHI), and Alzheimer’s disease ( Barzilay et al, 2008 ; Zhang et al, 2014 ; Luo et al, 2018a ; Ye et al, 2018 ). However, achieving the neurite growth in root canals with the treatment of the bFGF needs more experimental reports.…”

Section: The Underlying Mechanisms Of Basic Fibroblast Growth Factor In Dental Pulp Repair and Regenerationmentioning

confidence: 99%

The Regenerative Potential of bFGF in Dental Pulp Repair and Regeneration

Liu

et al. 2021

Front. Pharmacol.

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Regenerative endodontic therapy intends to induce the host’s natural wound-healing process, which can restore the vitality, immunity, and sensitivity of the inflammatory or necrotic pulp tissue destroyed by infection or trauma. Myriads of growth factors are critical in the processes of pulp repair and regeneration. Among the key regulatory factors are the fibroblast growth factors, which have turned out to be the master regulators of both organogenesis and tissue homeostasis. Fibroblast growth factors, a family composed of 22 polypeptides, have been used in tissue repair and regeneration settings, in conditions as diverse as burns, ulcers, bone-related diseases, and spinal cord injuries. Meanwhile, in dentistry, the basic fibroblast growth factor is the most frequently investigated. Thereby, the aim of this review is 2-fold: 1) foremost, to explore the underlying mechanisms of the bFGF in dental pulp repair and regeneration and 2) in addition, to shed light on the potential therapeutic strategies of the bFGF in dental pulp–related clinical applications.

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Neural Stem Cells Expressing bFGF Reduce Brain Damage and Restore Sensorimotor Function after Neonatal Hypoxia-Ischemia

Cited by 15 publications

References 37 publications

Cell motility and migration as determinants of stem cell efficacy

Cell motility and migration as determinants of stem cell efficacy

TNF-α Pretreatment Improves the Survival and Function of Transplanted Human Neural Progenitor Cells Following Hypoxic-Ischemic Brain Injury

The Regenerative Potential of bFGF in Dental Pulp Repair and Regeneration

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