Induction Of Neuronal Differentiation Research Articles

Selective targeting of IRAK1 attenuates low molecular weight hyaluronic acid-induced stemness and non-canonical STAT3 activation in epithelial ovarian cancer

Advanced epithelial ovarian cancer (EOC) survival rates are dishearteningly low, with ~25% surviving beyond 5 years. Evidence suggests that cancer stem cells contribute to acquired chemoresistance and tumor recurrence. Here, we show that IRAK1 is upregulated in EOC tissues, and enhanced expression correlates with poorer overall survival. Moreover, low molecular weight hyaluronic acid, which is abundant in malignant ascites from patients with advanced EOC, induced IRAK1 phosphorylation leading to STAT3 activation and enhanced spheroid formation. Knockdown of IRAK1 impaired tumor growth in peritoneal disease models, and impaired HA-induced spheroid growth and STAT3 phosphorylation. Finally, we determined that TCS2210, a known inducer of neuronal differentiation in mesenchymal stem cells, is a selective inhibitor of IRAK1. TCS2210 significantly inhibited EOC growth in vitro and in vivo both as monotherapy, and in combination with cisplatin. Collectively, these data demonstrate IRAK1 as a druggable target for EOC.

Retinoic acid induced specific changes in the phosphoproteome of C17.2 neural stem cells.

Retinoic acid (RA), a vitamin A derivative, is an effective cell differentiating factor which plays critical roles in neuronal differentiation induction and the production of neurotransmitters in neurons. However, the specific changes in phosphorylation levels and downstream signalling pathways associated with RA remain unclear. This study employed qualitative and quantitative phosphoproteomics approaches based on mass spectrometry to investigate the phosphorylation changes induced by RA in C17.2 neural stem cells (NSCs). Dimethyl labelling, in conjunction with TiO2 phosphopeptide enrichment, was utilized to profile the phosphoproteome of self-renewing and RA-induced differentiated cells in C17.2 NSCs. The results of our study revealed that, qualitatively, 230 and 14 phosphoproteins were exclusively identified in the self-renewal and RA-induced groups respectively. Quantitatively, we successfully identified and quantified 177 unique phosphoproteins, among which 70 exhibited differential phosphorylation levels. Analysis of conserved phosphorylation motifs demonstrated enrichment of motifs corresponding to cyclin-dependent kinase and MAPK in the RA-induced group. Additionally, through a comprehensive literature and database survey, we found that the differentially expressed proteins were associated with the Wnt/β-catenin and Hippo signalling pathways. This work sheds light on the changes in phosphorylation levels induced by RA in C17.2 NSCs, thereby expanding our understanding of the molecular mechanisms underlying RA-induced neuronal differentiation.

Establishment of TUBB3-mCherry knock-in human pluripotent stem cell line using CRISPR/Cas9 (SNUe003-A-4)

TUBB3 is a structural neuronal protein important for multiple neuronal functions including axonal guidance and maturation. This study aimed to generate a human pluripotent stem cell (hPSC) line with a TUBB3-mCherry reporter using CRISPR/SpCas9 nuclease. The stop codon in the last exon of TUBB3 was replaced with a T2A-mCherry cassette using CRISPR/SpCas9-mediated homologous recombination. The established TUBB3-mCherry knock-in cell line exhibited typical pluripotent characteristics. The mCherry reporter faithfully replicated the endogenous level of TUBB3 upon induction of neuronal differentiation. The reporter cell line could contribute to the investigation of neuronal differentiation, neuronal toxicity, and neuronal tracing.

Sel1l May Contributes to the Determinants of Neuronal Lineage and Neuronal Maturation Regardless of Hrd1 via Atf6-Sel1l Signaling.

The endoplasmic reticulum (ER) is the primary site of intracellular quality control involved in the recognition and degradation of unfolded proteins. A variety of stresses, including hypoxia and glucose starvation, can lead to accumulation of unfolded proteins triggering the ER-associated degradation (ERAD) pathway. Suppressor Enhancer Lin12/Notch1 Like (Sel1l) acts as a "gate keeper" in the quality control of de novo synthesized proteins and complexes with the ubiquitin ligase Hrd1 in the ER membrane. We previously demonstrated that ER stress-induced aberrant neural stem cell (NSC) differentiation and inhibited neurite outgrowth. Inhibition of neurite outgrowth was associated with increased Hrd1 expression; however, the contribution of Sel1l remained unclear. To investigate whether ER stress is induced during normal neuronal differentiation, we semi-quantitatively evaluated mRNA expression levels of unfolded protein response (UPR)-related genes in P19 embryonic carcinoma cells undergoing neuronal differentiation in vitro. Stimulation with all-trans retinoic acid (ATRA) for 4days induced the upregulation of Nestin and several UPR-related genes (Atf6, Xbp1, Chop, Hrd1, and Sel1l), whereas Atf4 and Grp78/Bip were unchanged. Small-interfering RNA (siRNA)-mediated knockdown of Sel1l uncovered that mRNA levels of the neural progenitor marker Math1 (also known as Atoh1) and the neuronal marker Math3 (also known as Atoh3 and NeuroD4) were significantly suppressed at 4days after ATRA stimulation. Consistent with this result, Sel1l silencing significantly reduced protein levels of immature neuronal marker βIII-tubulin (also known as Tuj-1) at 8days after induction of neuronal differentiation, whereas synaptogenic factors, such as cell adhesion molecule 1 (CADM1) and SH3 and multiple ankyrin repeat domain protein 3 (Shank3) were accumulated in Sel1l silenced cells. These results indicate that neuronal differentiation triggers ER stress and suggest that Sel1l may facilitate neuronal lineage through the regulation of Math1 and Math3 expression.

Long Non-Coding RNA Lacuna Regulates Neuronal Differentiation of Neural Stem Cells During Brain Development.

Although long non-coding RNAs (lncRNAs) is one of the most abundant classes of RNAs encoded within the mammalian genome and are highly expressed in the adult brain, they remain poorly characterized and their roles in the brain development are not well understood. Here we identify the lncRNA Lacuna (also catalogued as NONMMUT071331.2 in NONCODE database) as a negative regulator of neuronal differentiation in the neural stem/progenitor cells (NSCs) during mouse brain development. In particular, we show that Lacuna is transcribed from a genomic locus near to the Tbr2/Eomes gene, a key player in the transition of intermediate progenitor cells towards the induction of neuronal differentiation. Lacuna RNA expression peaks at the developmental time window between E14.5 and E16.5, consistent with a role in neural differentiation. Overexpression experiments in ex vivo cultured NSCs from murine cortex suggest that Lacuna is sufficient to inhibit neuronal differentiation, induce the number of Nestin+ and Olig2+ cells, without affecting proliferation or apoptosis of NSCs. CRISPR/dCas9-KRAB mediated knockdown of Lacuna gene expression leads to the opposite phenotype by inducing neuronal differentiation and suppressing Nestin+ and Olig2+ cells, again without any effect on proliferation or apoptosis of NSCs. Interestingly, despite the negative action of Lacuna on neurogenesis, its knockdown inhibits Eomes transcription, implying a simultaneous, but opposite, role in facilitating the Eomes gene expression. Collectively, our observations indicate a critical function of Lacuna in the gene regulation networks that fine tune the neuronal differentiation in the mammalian NSCs.

Neuroplasticity Mechanisms and Prospects for Personalized Rehabilitation Strategies in Patients with Motor and Cognitive Impairments

Aim. To highlight the most important areas of research on the problems of rehabilitation after stroke and the prospects for the development of new rehabilitation strategies, taking into account individual characteristics. Neuroplastic outcomes of anemic infarctions are presented by multi-pattern positive processes of synaptogenesis, sprouting, synthesis of neuroprotective proteins, and destructive effects of stress plasticity inducing dystonic disturbances, deterioration of stabilometric parameters and locomotor gait mechanisms with support deterioration [1]. Thus, specialists in neurorehabilitation should know the basics of fundamental neurophysiological processes in the central nervous system, interhemispheric networks of the brain, and optimize rehabilitation programs, taking into account individualized recovery profiles [2]. One of the factors influencing recovery after a stroke is nervous reorganization, which is proportional to the amount of damage [3]. The processes of neuroplasticity are studied from the standpoint of returning to the pre-stroke recovery model (with minor injuries) – forming “optimal” plasticity and compensatory strategies of “destructive” plasticity (with extensive hemispheric injuries). Micro-RNA (miRNA) are understudied in the neuroprotective reaction to cerebral ischemia. Another important modulator of stroke outcomes is the brain-derived neurotrophic factor (BDNF). Processing of the defective BDNF synthesis when the amino acid valine is replaced by methionine (val-met) that occurs during allelic disorders is of outstanding interest. Conclusion. Promising research areas for strategic approaches to rehabilitation after a stroke are the study of hemispheric introduction, miRNA and neuroprotection cascades; BDNF as an inducer of neuronal differentiation. Allelic BDNF polymorphisms induce lower recovery potential after stroke. Under certain environmental conditions motor learning can overcome the neuroplasticity deficit in the BDNF gene polymorphism. The studies have shown general patterns of positive effects of aerobic stimuli with enhanced BDNF secretion in the recovery of patients with cognitive and motor impairments; nevertheless, the onset period, intensity, duration and exercises rhythmicity have not been established in cerebral stroke. Future studies are likely to optimize rehabilitation profiles based on genetic characteristics.

Comparison of the Effects of Intratubal Injection of Adipose-Derived Mesenchymal Stem Cells in a Rat Sciatic Nerve Transection: An Experimental Study.

This study was designed to evaluate the efficacy of epineural tubulization (ENT) with or without intratubal application of adipose-derived mesenchymal stem cells (ASCs) in the rat model of sciatic nerve transection. After formation of 1-cm defect in the left sciatic nerve and ENT, 32 adults female Wistar albino rats were separated into 4 groups (n = 8 for each) including ENT per se (group 1; ENT group) and ENT plus intratubal ASC injection groups killed on day 21 (group 2; ENT-ASC-21-day group), 60 days (group 3; ENT-ASC-60-day group), and 120 days (group 4; ENT-ASC-120-day group). Functional (sciatic function index, hip circumference, withdrawal reflex latency, muscle weight ratio), electrophysiological, histomorphometric, and immunohistochemical analyses were performed in each group. Sciatic function index was significantly higher (-51.98 ± 5.94, P < 0.01) and withdrawal reflex latency was shorter (-6.21 ± 2.14, P < 0.01), in the group 4 as compared with all other groups on day 21. Amplitude of contraction was significantly lower in the group 4 as compared with all other groups (0.22 ± 0.05 vs 0.34 ± 0.07, 0.50 ± 0.11, and 0.61 ± 0.16, P < 0.01 for each). Immunohistochemical analysis revealed presence of green fluorescent protein, vimentin-stained cells, and single neural progenitor cells indicating that induction of neuronal differentiation by ASCs and direct involvement of ASCs within the axonal structure alongside extension of ASCs to the muscular layer of the group 4. In conclusion, our findings revealed that use of ENT plus intratubal ASC injection in a rat sciatic nerve transection model was associated with satisfactory functional outcome and improved peripheral axonal regeneration along with stem cell neural differentiation.

Dental Pulp from Human Exfoliated Deciduous Teeth-derived Stromal Cells Demonstrated Neuronal Potential: In Vivo and In Vitro Studies.

Mesenchymal Stromal Cells (MSC) have the potential for self-renewal and differentiation in different tissues, characteristics that encourage their use in regenerative medicine. Dental tissue MSCs are easy to collect, have the same embryonic origin as neurons and have neuronal markers that allow their use in treating neurodegenerative diseases. Human Exfoliated Deciduous teeth (SHED)-derived stromal cells are considered immature and present positive expression of pluripotency and neuronal markers. Studies have shown that after the induction of neuronal differentiation in vitro, SHED increased the expression of neuronal markers, such as βIIItubulin, nestin, GFAP, NeuN, and NFM, demonstrating the potential use of these cells in preclinical studies. The results of this review reflect the consensus that in diseases such as spinal cord injury, cerebral ischaemia, and Alzheimer's and Parkinson's disease, SHED could function in the suppression of the inflammatory response, neuroprotection, and neuronal replacement. For these cells to be used in large-scale clinical trials, standardization of the isolation techniques and theneuronal induction medium are necessary. The potential of SHED to induce neuronal differentiation is evident, demonstrating that this resource is promising and shows great potential for use in future preclinical and clinical trials of neurodegenerative diseases.

A human relevant mixture of persistent organic pollutants (POPs) and perfluorooctane sulfonic acid (PFOS) enhance nerve growth factor (NGF)-induced neurite outgrowth in PC12 cells

Disruption of neurite outgrowth is a marker for neurotoxicity. Persistent organic pollutants (POPs) are potential developmental neurotoxicants. We investigated their effect on neurite outgrowth in PC12 rat pheochromocytoma cells, in absence or presence of nerve growth factor (NGF), an inducer of neuronal differentiation. Cells were exposed for 72 h to a defined mixture of POPs with chemical composition and concentrations based on blood levels in the Scandinavian population. We also evaluated perfluorooctane sulfonic acid (PFOS) alone, the most abundant compound in the POP mixture. Only higher concentrations of POP mixture reduced tetrazolium salt (MTT) conversion. High-content analysis showed a decrease in cell number, but no changes for nuclear and mitochondrial cellular health parameters. Robust glutathione levels were observed in NGF-differentiated cells. Live imaging, using the IncuCyte ZOOM platform indicated ongoing cell proliferation over time, but slower in presence of NGF. The pollutants did not inhibit neuritogenesis, but rather increased NGF-induced neurite length. PFOS induced neurite outgrowth to about 50 % of the level seen with the POP mixture. Neither the POP mixture nor PFOS affected neurite length in the absence of NGF. Our observations indicate that realistic complex mixtures of environmental pollutants can affect neuronal connectivity via NGF-induced neurite outgrowth.

Recombinant stromal cell‑derived factor‑1 protein promotes neurite outgrowth in PC‑12 cells.

Stromal cell‑derived factor‑1 (SDF‑1) is a chemokine involved in neuronal differentiation, as well as proliferation and migration. In the present study, the effects of recombinant SDF‑1 on neurite outgrowth for nerve regeneration and engineering were evaluated in PC‑12 cells. The effects of purified SDF‑1 protein on cell toxicity, proliferation and migration were also assessed. SDF‑1 significantly augmented cell proliferation in a dose‑dependent manner, with low cytotoxicity in PC‑12 cells. Cell migration also increased in the presence of SDF‑1. SDF‑1 significantly increased neurite number and length, compared with the control (untreated cells). Neurofilament mRNA levels, which are involved in neuronal differentiation, were also significantly upregulated in the presence of SDF‑1. These results suggested that SDF‑1 might prove useful for tissue engineering through induction of neuronal differentiation.

GIP receptor suppresses PAC1receptor-mediated neuronal differentiation via formation of a receptor heterocomplex.

Pituitary adenylate cyclase-activating peptide (PACAP) receptor (PAC1R) is a class B Gprotein-coupled receptor (GPCR) that is widely expressed in the human body and is involved in neuronal differentiation. As class B GPCRs are known to form heterocomplexes with family members, we hypothesized that PAC1R mediates neuronal differentiation through interaction with a class B GPCR. We used the BRET assay to identify potential interactions between PAC1R and 11 class B GPCRs. Gastric inhibitory polypeptide receptor (GIPR) and secretin receptor were identified as putative binding partners of PAC1R. The effect of heterocomplex formation by PAC1R on receptor activation was evaluated with the cyclic (c)AMP, luciferase reporter, and calcium signaling assays; and the effects on receptor internalization and subcellular localization were examined by confocal microscopy. The results suggested he PAC1R/GIPR heterocomplex suppressed signaling events downstream of PAC1R, including cAMP production, serum response element and calcium signaling, and β-arrestin recruitment. Protein-protein interaction was analyzed in silico, and induction of neuronal differentiation by the PAC1R heterocomplex was assessed in SH-SY5Y neuronal cells by measure the morphological changes and marker genes expression by real-time quantitative PCR and western blot. Over-expression of GIPR suppressed PACAP/PAC1R-mediated neuronal differentiation and the differentiation markers expression in SH-SY5Y cells. GIPR regulates neuronal differentiation through heterocomplex formation with PAC1R.

Developmental Neurotoxicity Screening for Nanoparticles Using Neuron-Like Cells of Human Umbilical Cord Mesenchymal Stem Cells: Example with Magnetite Nanoparticles.

Metallic nanoparticles (NPs), as iron oxide NPs, accumulate in organs, cross the blood-brain barrier and placenta, and have the potential to elicit developmental neurotoxicity (DNT). Human stem cell-derived in vitro models may provide more realistic platforms to study NPs effects on neural cells, and to obtain relevant information on the potential for early or late DNT effects in humans. Primary neuronal-like cells (hNLCs) were generated from mesenchymal stem cells derived from human umbilical cord lining and the effects caused by magnetite (Fe3O4NPs, 1–50 μg/mL) evaluated. Neuronal differentiation process was divided into stages: undifferentiated, early, mid- and fully-differentiated (from day-2 to 8 of induction) based on different neuronal markers and morphological changes over time. Reduction in neuronal differentiation induction after NP exposure was observed associated with NP uptake: β-tubulin III (β-Tub III), microtubule-associated protein 2 (MAP-2), enolase (NSE) and nestin were downregulated (10–40%), starting from 25 μg/mL at the early stage. Effects were exacerbated at higher concentrations and persisted up to 8 days without cell morphology alterations. Adenosine triphosphate (ATP) and caspase-3/7 activity data indicated Fe3O4NPs-induced cell mortality in a concentration-dependent manner and increases of apoptosis: effects appeared early (from day-3), started at low concentrations (≥5 μg/mL) and persisted. This new human cell-based model allows different stages of hNLCs to be cultured, exposed to NPs/chemicals, and analyzed for different endpoints at early or later developmental stage.

Isolation and Characterization of Mesenchymal Stem Cells from Human Gingiva

A new nonimmortalized cell line (MSC-GING) was isolated from the gingiva of a 35-year-old healthy donor and characterized. The analysis of different properties was carried out at the 6th, 7th, 13th, 18th, 20th, and 23rd passages. During long-term cultivation, the proportion of aging cells according to the activity of β-galactosidase increased. The cloning efficiency of MSC-GING cells was significantly reduced, and the number of aging β-galactosidase-positive cells was gradually increased during cell prolonged cultivation. Growth curves showed active cell proliferation at the sixth passage. It was significantly declined by the 18th and 20th passages. Karyotypic analysis at the 7th and 18th passages showed the presence of a diploid number of chromosomes (46) in metaphase plates. At passage 7, however, the proportion of cells with a normal diploid karyotype 46, XX, was 50 ± 5%. Other cells had a clonal rearrangement inv (10) (q21.1q25.1), an inversion of the long arm of chromosome 10. Their number significantly decreased during cultivation up to passage 18, while the proportion of cells with a normal diploid karyotype increased. The cell number with surface antigens common for human mesenchymal stem cells (CD44, CD73, CD90, CD105, HLA-ABC) and vimentin was high at passages 6 and 20, while CD34, CD45, and HLA-DR positive cells were very rare. It is noteworthy that no cells carrying markers of undifferentiated embryonic stem cells (Oct-4, SSEA-4, and SOX2) are observed at passages 6 and 20. It was shown that MSC-GING cells were able to differentiate in osteogenic and chondrogenic directions. The ability to differentiate in the adipogenic direction was manifested only at the level of glut4 gene expression. Induction of neuronal differentiation increased the expression the nse gene (neurospecific elonase). In general, the results confirmed the MSC status for the obtained line, but revealed significant karyotypic instability in the early passages, which decreased during the replicative aging.

Loss of the Chr16p11.2 ASD candidate gene QPRT leads to aberrant neuronal differentiation in the SH-SY5Y neuronal cell model

BackgroundAltered neuronal development is discussed as the underlying pathogenic mechanism of autism spectrum disorders (ASD). Copy number variations of 16p11.2 have recurrently been identified in individuals with ASD. Of the 29 genes within this region, quinolinate phosphoribosyltransferase (QPRT) showed the strongest regulation during neuronal differentiation of SH-SY5Y neuroblastoma cells. We hypothesized a causal relation between this tryptophan metabolism-related enzyme and neuronal differentiation. We thus analyzed the effect of QPRT on the differentiation of SH-SY5Y and specifically focused on neuronal morphology, metabolites of the tryptophan pathway, and the neurodevelopmental transcriptome.MethodsThe gene dosage-dependent change of QPRT expression following Chr16p11.2 deletion was investigated in a lymphoblastoid cell line (LCL) of a deletion carrier and compared to his non-carrier parents. Expression of QPRT was tested for correlation with neuromorphology in SH-SY5Y cells. QPRT function was inhibited in SH-SY5Y neuroblastoma cells using (i) siRNA knockdown (KD), (ii) chemical mimicking of loss of QPRT, and (iii) complete CRISPR/Cas9-mediated knock out (KO). QPRT-KD cells underwent morphological analysis. Chemically inhibited and QPRT-KO cells were characterized using viability assays. Additionally, QPRT-KO cells underwent metabolite and whole transcriptome analyses. Genes differentially expressed upon KO of QPRT were tested for enrichment in biological processes and co-regulated gene-networks of the human brain.ResultsQPRT expression was reduced in the LCL of the deletion carrier and significantly correlated with the neuritic complexity of SH-SY5Y. The reduction of QPRT altered neuronal morphology of differentiated SH-SY5Y cells. Chemical inhibition as well as complete KO of the gene were lethal upon induction of neuronal differentiation, but not proliferation. The QPRT-associated tryptophan pathway was not affected by KO. At the transcriptome level, genes linked to neurodevelopmental processes and synaptic structures were affected. Differentially regulated genes were enriched for ASD candidates, and co-regulated gene networks were implicated in the development of the dorsolateral prefrontal cortex, the hippocampus, and the amygdala.ConclusionsIn this study, QPRT was causally related to in vitro neuronal differentiation of SH-SY5Y cells and affected the regulation of genes and gene networks previously implicated in ASD. Thus, our data suggest that QPRT may play an important role in the pathogenesis of ASD in Chr16p11.2 deletion carriers.

Probing biological activity through structural modelling of ligand-receptor interactions of 2,4-disubstituted thiazole retinoids

Retinoids, such as all-trans-retinoic acid (ATRA), regulate cellular differentiation and signalling pathways in chordates by binding to nuclear retinoic acid receptors (RARα/β/γ). Polar interactions between receptor and ligand are important for binding and facilitating the non-polar interactions and conformational changes necessary for RAR-mediated transcriptional regulation. The constraints on activity and RAR-type specificity with respect to the structural link between the polar and non-polar functions of synthetic retinoids are poorly understood. To address this, predictions from in silico ligand-RAR docking calculations and molecular dynamics simulations for a small library of stable, synthetic retinoids (designated GZ series) containing a central thiazole linker structure and different hydrophobic region substituents, were tested using a ligand binding assay and a range of cellular biological assays. The docking analysis showed that these thiazole-containing retinoids were well suited to the binding pocket of RARα, particularly via a favorable hydrogen bonding interaction between the thiazole and Ser232 of RARα. A bulky hydrophobic region (i.e., present in compounds GZ23 and GZ25) was important for interaction with the RAR binding pockets. Ligand binding assays generally reflected the findings from in silico docking, and showed that GZ25 was a particularly strongly binding ligand for RARα/β. GZ25 also exhibited higher activity as an inducer of neuronal differentiation than ATRA and other GZ derivatives. These data demonstrate that GZ25 is a stable synthetic retinoid with improved activity which efficiently regulates neuronal differentiation and help to define the key structural requirements for retinoid activity enabling the design and development of the next generation of more active, selective synthetic retinoids as potential therapeutic regulators of neurogenesis.

Panobinostat, a histone deacetylase inhibitor, suppresses leptomeningeal seeding in a medulloblastoma animal model.

Leptomeningeal seeding is a strong negative prognostic factor for medulloblastoma (MB). The mechanism of leptomeningeal seeding is unclear but may involve epigenetic regulation. In this study, we evaluated the feasibility of a histone deacetylase (HDAC) inhibitor, panobinostat, in the suppression of MB leptomeningeal seeding.Panobinostat decreased the cell viability and proliferation, inducing cell cycle arrest and apoptosis in MB cell lines. The migration and adhesion capabilities were significantly decreased. Panobinostat effectively down-regulated protein expression of CCND1 and ID3 which has been associated with leptomeningeal seeding of MB. After panobinostat treatment, neurophil-like cellular processes developed and expression of synaptophysin and NeuroD1 was increased, indicating neuronal differentiation. In MB leptomeningeal seeding in vivo model, the panobinostat-treated group showed significantly decreased spinal leptomeningeal seeding and a survival benefit.The findings demonstrate that panobinostat suppresses MB leptomeningeal seeding through the down-regulation of ID3 and the induction of neuronal differentiation. An HDAC inhibitor might be a potent treatment option for the treatment of MB patients with leptomeningeal seeding.

New Insights into the Neural Differentiation Potential of Canine Adipose Tissue-Derived Mesenchymal Stem Cells.

Adipose tissue-derived stem cells (ASCs) can be obtained from different adipose tissue sources within the body. It is an abundant cell pool, easily accessible, suitable for cultivation and expansion invitro and preparation for therapeutic approaches. Amongst these therapeutic approaches are tissue engineering and nervous system disorders such as spinal cord injuries. For such treatment, ASCs have to be reliably differentiated in to the neuronal direction. Therefore, we investigated the neural differentiation potential of ASCs using protocols with neurogenic inductors such as valproic acid and forskolin, while dog brain tissue served as control. Morphological changes could already be noticed 1h after neuronal induction. Gene expression analysis revealed that the neuronal markers nestin and βIII-tubulin as well as MAP2 were expressed after induction of neuronal differentiation. Additionally, the expression of the neurotrophic factors NGF, BDNF and GDNF was determined. Some of the neuronal markers and neurotrophic factors were already expressed in undifferentiated cells. Our findings point out that ASCs can reliably be differentiated into the neuronal lineage; therefore, these cells are a suitable cell source for cell transplantation in disorders of the central nervous system. Follow-up studies would show the clinical benefit of these cells after transplantation.

Induction of Neuronal Differentiation by Extracts from 57 Kinds of Traditional Medicinal Plants in Myanmar

Induction of Neuronal Differentiation by Extracts from 57 Kinds of Traditional Medicinal Plants in Myanmar

B-ring modification in prenylflavonoids of hops and the effect on induction of neuronal differentiation

B-ring modification in prenylflavonoids of hops and the effect on induction of neuronal differentiation

Uptake of silica nanoparticles in the brain and effects on neuronal differentiation using different in vitro models

Nanomedicine offers a promising tool for therapies of brain diseases, but they may be associated with potential adverse effects. The aim of this study was to investigate the uptake of silica-nanoparticles engineered for laser-tissue soldering in the brain using SH-SY5Y cells, dissociated and organotypic slice cultures from rat hippocampus. Nanoparticles were predominantly taken up by microglial cells in the hippocampal cultures but nanoparticles were also found in differentiated SH-SY5Y cells. The uptake was time- and concentration-dependent in primary hippocampal cells. Transmission electron microscopy experiments demonstrated nanoparticle aggregates and single particles in the cytoplasm. Nanoparticles were found in the endoplasmic reticulum, but not in other cellular compartments. Nanoparticle exposure did not impair cell viability and neuroinflammation in primary hippocampal cultures at all times investigated. Neurite outgrowth was not significantly altered in SH-SY5Y cells, but the neuronal differentiation markers indicated a reduction in neuronal differentiation induction after nanoparticle exposure.