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Stress bears a negative impact on adult neurogenesis. High levels of corticoids have been shown to inhibit neural stem cell proliferation,and are considered responsible for the loss of neural precursors. Their effects on the differentiation of the glial and neuronal lineages have been less studied. We examined the effect of dexamethasone (Dex),a synthetic glucocorticoid,on the differentiation of rat neural stem cells in vitro. Dex had no effect on the differentiation of cells cultured under standard conditions. Since we previously determined that NSC,when cultured under classical conditions,were deprived of polyunsaturated fatty acids (PUFA),and displayed phospholipid compositions very different from the in vivo figures [1],we examined the effect of Dex under PUFA supplementation. Dex impaired neuron and oligodendrocyte maturation in PUFA-supplemented cells,demonstrated by the reduction of neurite lengths and oligodendrocyte sizes. This effect was mediated by the glucocorticoid receptor (GR),since it was eliminated by mifepristone,a GR antagonist,and could be relayed by a reduction of ERK phosphorylation. We determined that GR was associated with PPAR β and α under basal conditions,and that this association was disrupted when PUFA were added in combination with Dex. We assumed that this effect on the receptor status enabled the effect of Dex on PUFA supplemented cells,since we determined that the binding to the glucocorticoid response element was higher in cells incubated with PUFA and Dex. In conclusion,corticoids can impair NSC differentiation,and consequently impact the entire process of neurogenesis. View Publication

Multiple research groups have observed neuropathological phenotypes and molecular symptoms in vitro using induced pluripotent stem cell (iPSC)-derived neural cell cultures (i.e. patient-specific neurons and glia). However,the global differences/similarities that may exist between in vitro neural cells and their tissue-derived counterparts remain largely unknown. In this study,we compared temporal series of iPSC-derived in vitro neural cell cultures to endogenous brain tissue from the same autopsy donor. Specifically,we utilized RNA sequencing (RNA-Seq) to evaluate the transcriptional progression of in vitro-differentiated neural cells (over a timecourse of 0,35,70,105 and 140 days),and compared this with donor-identical temporal lobe tissue. We observed in vitro progression towards the reference brain tissue,and the following three results support this conclusion: (i) there was a significant increasing monotonic correlation between the days of our timecourse and the number of actively transcribed protein-coding genes and long intergenic non-coding RNAs (lincRNAs) (P < 0.05),consistent with the transcriptional complexity of the brain; (ii) there was an increase in CpG methylation after neural differentiation that resembled the epigenomic signature of the endogenous tissue; and (iii) there was a significant decreasing monotonic correlation between the days of our timecourse and the percent of in vitro to brain-tissue differences (P < 0.05) for tissue-specific protein-coding genes and all putative lincRNAs. Taken together,these results are consistent with in vitro neural development and physiological progression occurring predominantly by transcriptional activation of downregulated genes rather than deactivation of upregulated genes. View Publication

Retinal ganglion cells (RGCs) are the projection neurons of the retina and transmit visual information to postsynaptic targets in the brain. While this function is shared among nearly all RGCs,this class of cell is remarkably diverse,comprised of multiple subtypes. Previous efforts have identified numerous RGC subtypes in animal models,but less attention has been paid to human RGCs. Thus,efforts of this study examined the diversity of RGCs differentiated from human pluripotent stem cells (hPSCs) and characterized defined subtypes through the expression of subtype-specific markers. Further investigation of these subtypes was achieved using single-cell transcriptomics,confirming the combinatorial expression of molecular markers associated with these subtypes,and also provided insight into more subtype-specific markers. Thus,the results of this study describe the derivation of RGC subtypes from hPSCs and will support the future exploration of phenotypic and functional diversity within human RGCs. View Publication

Neurotoxicity testing still relies on ethically debated,expensive and time consuming in vivo experiments,which are unsuitable for high-throughput toxicity screening. There is thus a clear need for a rapid in vitro screening strategy that is preferably based on human-derived neurons to circumvent interspecies translation. Recent availability of commercially obtainable human induced pluripotent stem cell (hiPSC)-derived neurons and astrocytes holds great promise in assisting the transition from the current standard of rat primary cortical cultures to an animal-free alternative. We therefore composed several hiPSC-derived neuronal models with different ratios of excitatory and inhibitory neurons in the presence or absence of astrocytes. Using immunofluorescent stainings and multi-well micro-electrode array (mwMEA) recordings we demonstrate that these models form functional neuronal networks that become spontaneously active. The differences in development of spontaneous neuronal activity and bursting behavior as well as spiking patterns between our models confirm the importance of the presence of astrocytes. Preliminary neurotoxicity assessment demonstrates that these cultures can be modulated with known seizurogenic compounds,such as picrotoxin (PTX) and endosulfan,and the neurotoxicant methylmercury (MeHg). However,the chemical-induced effects on different parameters for neuronal activity,such as mean spike rate (MSR) and mean burst rate (MBR),may depend on the ratio of inhibitory and excitatory neurons. Our results thus indicate that hiPSC-derived neuronal models must be carefully designed and characterized prior to large-scale use in neurotoxicity screening. View Publication

The electrophoretic pattern of the large microtubule-associated protein,MAP2,changes during rat brain development. Immunoblots of NaDodSO4 extracts obtained from the cerebral cortex,cerebellum,and thalamus at 10-15 days after birth reveal only a single electrophoretic species when probed with any of three MAP2 monoclonal antibodies. By contrast,adult MAP2 contains two immunoreactive species,MAP2a and MAP2b. The single band of MAP2 from immature brain electrophoretically comigrates with adult MAP2b. Between postnatal days 17 and 18,immature MAP2 simultaneously resolves into two species in both the cerebellum and cerebral cortex. Immunoblots of NaDodSO4 extracts from spinal cord demonstrate the adult complement of MAP2 by day 10,indicating that MAP2 does not change coordinately throughout the entire central nervous system. In vitro cAMP-dependent phosphorylation of immature MAP2 causes a band split reminiscent of that seen during brain development in vivo. The possibility that the developmentally regulated changes observed in MAP2 during brain maturation are due to timed phosphorylation events is discussed. View Publication

The low success rate of animal cloning by somatic cell nuclear transfer (SCNT) is believed to be associated with epigenetic errors including abnormal DNA hypermethylation. Recently,we elucidated by using round spermatids that,after nuclear transfer,treatment of zygotes with trichostatin A (TSA),an inhibitor of histone deacetylase,can remarkably reduce abnormal DNA hypermethylation depending on the origins of transferred nuclei and their genomic regions [S. Kishigami,N. Van Thuan,T. Hikichi,H. Ohta,S. Wakayama. E. Mizutani,T. Wakayama,Epigenetic abnormalities of the mouse paternal zygotic genome associated with microinsemination of round spermatids,Dev. Biol. (2005) in press]. Here,we found that 5-50 nM TSA-treatment for 10 h following oocyte activation resulted in more efficient in vitro development of somatic cloned embryos to the blastocyst stage from 2- to 5-fold depending on the donor cells including tail tip cells,spleen cells,neural stem cells,and cumulus cells. This TSA-treatment also led to more than 5-fold increase in success rate of mouse cloning from cumulus cells without obvious abnormality but failed to improve ES cloning success. Further,we succeeded in establishment of nuclear transfer-embryonic stem (NT-ES) cells from TSA-treated cloned blastocyst at a rate three times higher than those from untreated cloned blastocysts. Thus,our data indicate that TSA-treatment after SCNT in mice can dramatically improve the practical application of current cloning techniques. View Publication

Numerous proteins undergo modification by palmitic acid (S-acylation) for their biological functions including signal transduction,vesicular transport and maintenance of cellular architecture. Although palmitoylation is an essential modification,these proteins must also undergo depalmitoylation for their degradation by lysosomal proteases. Palmitoyl-protein thioesterase-1 (PPT1),a lysosomal enzyme,cleaves thioester linkages in S-acylated proteins and removes palmitate residues facilitating the degradation of these proteins. Thus,inactivating mutations in the PPT1 gene cause infantile neuronal ceroid lipofuscinosis (INCL),a devastating neurodegenerative storage disorder of childhood. Although rapidly progressing brain atrophy is the most dramatic pathological manifestation of INCL,the molecular mechanism(s) remains unclear. Using PPT1-knockout (PPT1-KO) mice that mimic human INCL,we report here that the endoplasmic reticulum (ER) in the brain cells of these mice is structurally abnormal. Further,we demonstrate that the level of growth-associated protein-43 (GAP-43),a palmitoylated neuronal protein,is elevated in the brains of PPT1-KO mice. Moreover,forced expression of GAP-43 in PPT1-deficient cells results in the abnormal accumulation of this protein in the ER. Consistent with these results,we found evidence for the activation of unfolded protein response (UPR) marked by elevated levels of phosphorylated translation initiation factor,eIF2alpha,increased expression of chaperone proteins such as glucose-regulated protein-78 and activation of caspase-12,a cysteine proteinase in the ER,mediating caspase-3 activation and apoptosis. Our results,for the first time,link PPT1 deficiency with the activation of UPR,apoptosis and neurodegeneration in INCL and identify potential targets for therapeutic intervention in this uniformly fatal disease. View Publication

Neural stem cells (NSCs) possess immunosuppressive characteristics,but effects of NSCs on human dendritic cells (DCs),the most important antigen presenting cells,are less well studied. We used an in vitro approach to evaluate the effects of human NSCs on differentiation of human blood CD14+ monocytes into DCs. NSCs derived from H1 human embryonic stem cells (hESC-NSCs) and human ReNcell NSC line,as well as human bone marrow derived mesenchymal stem cells (MSCs),were tested. We observed that in response to treatment with interleukin-4 and granulocyte macrophage colony-stimulating factor CD14+ monocytes co-cultured with NSCs were able to down-regulate CD14 and up-regulate the differentiation marker CD1a,whereas MSC co-culture strongly inhibited CD1a expression and supported prolonged expression of CD14. A similar difference between NSCs and MSCs was noted when lipopolysaccharides were included to induce maturation of monocyte-derived DCs. However,when effects on the function of derived DCs were investigated,NSCs suppressed the elevation of the DC maturation marker CD83,although not the up-regulation of costimulatory molecules CD80,CD86 and CD40,and impaired the functional capacity of the derived DCs to stimulate alloreactive T cells. We did not observe any obvious difference between hESC-NSCs and ReNcell NSCs in inhibiting DC maturation and function. Our data suggest that although human NSCs are less effective than human MSCs in suppressing monocyte differentiation into DCs,these stem cells can still affect the function of DCs,ultimately regulating specific immune responses. View Publication

In human glioblastomas (hGBMs),tumor-propagating cells with stem-like characteristics (TPCs) represent a key therapeutic target. We found that the EphA2 receptor tyrosine kinase is overexpressed in hGBM TPCs. Cytofluorimetric sorting into EphA2(High) and EphA2(Low) populations demonstrated that EphA2 expression correlates with the size and tumor-propagating ability of the TPC pool in hGBMs. Both ephrinA1-Fc,which caused EphA2 downregulation in TPCs,and siRNA-mediated knockdown of EPHA2 expression suppressed TPCs self-renewal ex vivo and intracranial tumorigenicity,pointing to EphA2 downregulation as a causal event in the loss of TPCs tumorigenicity. Infusion of ephrinA1-Fc into intracranial xenografts elicited strong tumor-suppressing effects,suggestive of therapeutic applications. View Publication