Hyo Sang Go

The critical period of valproate exposure to induce autistic symptoms in Sprague–Dawley rats

Prenatal exposure to valproic acid (VPA) induces neural tube defects and impairment in social behaviors related to autistic spectrum disorder in newborns, which make it a useful animal model of autism. In this study, we compared the effects of different time window of prenatal valproic acid exposure for inducing the altered social behaviors relevant to autism from embryonic day 7 to embryonic day 15 in Sprague-Dawley rats to determine the critical periods for the impairment. Compared to E7, E9.5 and E15 exposure, VPA exposure at E12 showed most significant changes in behaviors over control animals with reduced sociability and social preference. E9.5 exposure to valproic acid showed strong reproductive toxicity including decrease in the number of live birth. In general, exposure at E15 showed only marginal effects on reproduction and social behaviors. Finally, VPA-exposed rats at E12 were more sensitive to electric shock than VPA-exposed rats at any other periods. These results suggested that E12 is the critical period in rats when valproate exposure has prominent effects for inducing the altered social behavior similar to human autistic behavior.

Male‐specific alteration in excitatory post‐synaptic development and social interaction in pre‐natal valproic acid exposure model of autism spectrum disorder

Autism spectrum disorder (ASD) is a pervasive developmental disorder characterized by three main behavioral symptoms including social deficits, impaired communication, and stereotyped and repetitive behaviors. ASD prevalence shows gender bias to male. Prenatal exposure to valproic acid (VPA), a drug used in epilepsy and bipolar disorder, induces autistic symptoms in both human and rodents. As we reported previously, prenatally VPA‐exposed animals at E12 showed impairment in social behavior without any overt reproductive toxicity. Social interactions were not significantly different between male and female rats in control condition. However, VPA‐exposed male offspring showed significantly impaired social interaction while female offspring showed only marginal deficits in social interaction. Similar male inclination was observed in hyperactivity behavior induced by VPA. In addition to the ASD‐like behavioral phenotype, prenatally VPA‐exposed rat offspring shows crooked tail phenotype, which was not different between male and female groups. Both male and female rat showed reduced GABAergic neuronal marker GAD and increased glutamatergic neuronal marker vGluT1 expression. Interestingly, despite of the similar increased expression of vGluT1, post‐synaptic marker proteins such as PSD‐95 and α‐CAMKII expression was significantly elevated only in male offspring. Electron microscopy showed increased number of post‐synapse in male but not in female at 4 weeks of age. These results might suggest that the altered glutamatergic neuronal differentiation leads to deranged post‐synaptic maturation only in male offspring prenatally exposed to VPA. Consistent with the increased post‐synaptic compartment, VPA‐exposed male rats showed higher sensitivity to electric shock than VPA‐exposed female rats. These results suggest that prenatally VPA‐exposed rats show the male preponderance of ASD‐like behaviors including defective social interaction similar to human autistic patients, which might be caused by ectopic increase in glutamatergic synapses in male rats.

Prenatal exposure to valproic acid increases the neural progenitor cell pool and induces macrocephaly in rat brain via a mechanism involving the GSK-3β/β-catenin pathway

Autism is a spectrum of neurodevelopmental disorders characterized by social isolation and lack of interaction. Anatomically, autism patients often show macrocephaly and high neuronal density. To investigate the mechanism underlying the higher neuronal populations seen in ASD, we subcutaneously injected VPA (400 mg/kg) into pregnant Sprague-Dawley rats on E12, an animal model often used in ASD study. Alternatively, cultured rat neural progenitor cells were treated with VPA. Until E18, VPA induced NPC proliferation and delayed neurogenesis in fetal brain, but the subsequent differentiation of NPCs to neurons increased brain neuronal density afterward. Similar findings were observed with NPCs treated with VPA in vitro. At a molecular level, VPA enhanced Wnt1 expression and activated the GSK-3β/β-catenin pathway. Furthermore, inhibition of this pathway attenuated the effects of VPA. The findings of this study suggest that an altered developmental process underlies the macrocephaly and abnormal brain structure observed in the autistic brain.

Pax6-Dependent Cortical Glutamatergic Neuronal Differentiation Regulates Autism-Like Behavior in Prenatally Valproic Acid-Exposed Rat Offspring

Imbalance in excitatory/inhibitory signal in the brain has been proposed as one of the main pathological features in autism spectrum disorders, although the underlying cellular and molecular mechanism is unclear yet. Because excitatory/inhibitory imbalance can be induced by aberration in glutamatergic/GABAergic neuronal differentiation, we investigated the mechanism of dysregulated neuronal differentiation between excitatory and inhibitory neurons in the embryonic and postnatal brain of prenatally valproic acid-exposed rat offspring, which is often used as an animal model of autism spectrum disorders. Transcription factor Pax6, implicated in glutamatergic neuronal differentiation, was transiently increased in embryonic cortex by valproate exposure, which resulted in the increased expression of glutamatergic proteins in postnatal brain of offspring. Chromatin immunoprecipitation showed increased acetylated histone binding on Pax6 promoter region, which may underlie the transcriptional up-regulation of Pax6. Other histone deacetylase (HDAC) inhibitors including TSA and SB but not valpromide, which is devoid of HDAC inhibitor activity, induced Pax6 up-regulation. Silencing Pax6 expression in cultured rat primary neural progenitor cells demonstrated that up-regulation of Pax6 plays an essential role in valproate-induced glutamatergic differentiation. Blocking glutamatergic transmission with MK-801 or memantine treatment, and to a lesser extent with MPEP treatment, reversed the impaired social behaviors and seizure susceptibility of prenatally valproate-exposed offspring. Together, environmental factors may contribute to the imbalance in excitatory/inhibitory neuronal activity in autistic brain by altering expression of transcription factors governing glutamatergic/GABAergic differentiation during fetal neural development, in conjunction with the genetic preload.

Valproic acid inhibits neural progenitor cell death by activation of NF-κB signaling pathway and up-regulation of Bcl-XL.

BackgroundAt the beginning of neurogenesis, massive brain cell death occurs and more than 50% of cells are eliminated by apoptosis along with neuronal differentiation. However, few studies were conducted so far regarding the regulation of neural progenitor cells (NPCs) death during development. Because of the physiological role of cell death during development, aberration of normal apoptotic cell death is detrimental to normal organogenesis.Apoptosis occurs in not only neuron but also in NPCs and neuroblast. When growth and survival signals such as EGF or LIF are removed, apoptosis is activated as well as the induction of differentiation. To investigate the regulation of cell death during developmental stage, it is essential to investigate the regulation of apoptosis of NPCs.MethodsNeural progenitor cells were cultured from E14 embryonic brains of Sprague-Dawley rats. For in vivo VPA animal model, pregnant rats were treated with VPA (400 mg/kg S.C.) diluted with normal saline at E12. To analyze the cell death, we performed PI staining and PARP and caspase-3 cleavage assay. Expression level of proteins was investigated by Western blot and immunocytochemical assays. The level of mRNA expression was investigated by RT-PCR. Interaction of Bcl-XL gene promoter and NF-κB p65 was investigated by ChIP assay.ResultsIn this study, FACS analysis, PI staining and PARP and caspase-3 cleavage assay showed that VPA protects cultured NPCs from cell death after growth factor withdrawal both in basal and staurosporine- or hydrogen peroxide-stimulated conditions. The protective effect of prenatally injected VPA was also observed in E16 embryonic brain. Treatment of VPA decreased the level of IκBα and increased the nuclear translocation of NF-κB, which subsequently enhanced expression of anti-apoptotic protein Bcl-XL.ConclusionTo the best of our knowledge, this is the first report to indicate the reduced death of NPCs by VPA at developmentally critical periods through the degradation of IκBα and the activation of NF-κB signaling. The reduced NPCs death might underlie the neurodevelopmental defects collectively called fetal valproate syndrome, which shows symptoms such as mental retardation and autism-like behavior.

Activation of protease-activated receptor1 mediates induction of matrix metalloproteinase-9 by thrombin in rat primary astrocytes.

Thrombin plays an important role in diverse neurological processes such as proliferation, cell migration, differentiation and neuroinflammation. In this study, we investigated the effect of thrombin on matrix metalloprotease-9 (MMP-9) expression in rat primary astrocytes. Thrombin (1-10U/ml) induced a significant increase in MMP-9 activity as measured by gelatin zymography. Thrombin also increased MMP-9 mRNA expression. Among three isotypes of thrombin receptor, i.e. protease-activated receptor (PAR)-1, -3 and -4, PAR1 agonist (1-100muM) but not PAR3 and PAR4 agonist induced MMP-9 expression. Inhibition of thrombin-induced MMP-9 production by SCH 79797 (10-50nM), a selective PAR1 receptor antagonist, confirmed that PAR1 is a main receptor for thrombin-induced MMP-9 expression. In astrocytes, thrombin activated Erk1/2, and it was inhibited by PD98059. In this study, thrombin-induced MMP-9 expression was inhibited by PD98059. PAR1 agonist activated Erk1/2 and PD98059 inhibited PAR1 agonist-induced MMP-9 expression. MMP-9 promoter reporter assay confirmed the positive effect of ERK1/2 on MMP-9 expression. These results suggest that the activation of PAR1 mediates thrombin-induced MMP-9 expression through the regulation of Erk1/2.

Increased proliferation and gliogenesis of cultured rat neural progenitor cells by lipopolysaccharide-stimulated astrocytes.

Neural progenitor cells (NPC) are self-renewing multipotent cells that generate neurons and glial cells in the brain. NPCs generate neurons and glia not only during development but also after neural injury. Recent studies have shown that endogenous NPCs are activated after brain injury and migrate toward damaged areas where astrocyte activation occurs. Considering the massive proliferation of astrocytes as well as the production of several kinds of cytoactive molecules after brain injury, such as NO, growth factors and cytokines, it is tempting to think that cytoactive molecules released by activated glial cells regulate neural progenitor differentiation and proliferation through inflammatory mediators. To test this hypothesis, we stimulated rat primary astrocytes with lipopolysaccharide (LPS) to induce the activation of astrocytes. After addition of the conditioned media from LPS-stimulated astrocytes to NPC culture, proliferation was examined by MTT assay and bromodeoxyuridine (BrdU) incorporation. The differentiation of NPC into neurons and astrocytes was examined by Western blot, ELISA and immunocytochemical staining with cell-type-specific mark- ers. Conditioned media from LPS-stimulated astrocytes increased NPC proliferation as well as gliogenesis as compared with control conditioned media from astrocytes without LPS stimulation. In contrast, neurogenesis was decreased by LPS-conditioned media. To investigate the molecular mechanism mediating glial differentiation and proliferation of NPC by reactive astrocytes, we added inhibitors of the Erk and JNK pathways during LPS stimulation. These inhibitors – except for a p38 inhibitor – decreased NPC proliferation and glial differentiation. These results suggest that LPS stimulated astrocytes generate factors regulating NPC proliferation and gliogenesis via the Erk and JNK pathways.

Prenatal exposure of ethanol induces increased glutamatergic neuronal differentiation of neural progenitor cells

BackgroundPrenatal ethanol exposure during pregnancy induces a spectrum of mental and physical disorders called fetal alcohol spectrum disorder (FASD). The central nervous system is the main organ influenced by FASD, and neurological symptoms include mental retardation, learning abnormalities, hyperactivity and seizure susceptibility in childhood along with the microcephaly. In this study, we examined whether ethanol exposure adversely affects the proliferation of NPC and de-regulates the normal ratio between glutamatergic and GABAergic neuronal differentiation using primary neural progenitor culture (NPC) and in vivo FASD models.MethodsNeural progenitor cells were cultured from E14 embryo brain of Sprague-Dawley rat. Pregnant mice and rats were treated with ethanol (2 or 4 g/kg/day) diluted with normal saline from E7 to E16 for in vivo FASD animal models. Expression level of proteins was investigated by western blot analysis and immunocytochemical assays. MTT was used for cell viability. Proliferative activity of NPCs was identified by BrdU incorporation, immunocytochemistry and FACS analysis.ResultsReduced proliferation of NPCs by ethanol was demonstrated using BrdU incorporation, immunocytochemistry and FACS analysis. In addition, ethanol induced the imbalance between glutamatergic and GABAergic neuronal differentiation via transient increase in the expression of Pax6, Ngn2 and NeuroD with concomitant decrease in the expression of Mash1. Similar pattern of expression of those transcription factors was observed using an in vivo model of FASD as well as the increased expression of PSD-95 and decreased expression of GAD67.ConclusionsThese results suggest that ethanol induces hyper-differentiation of glutamatergic neuron through Pax6 pathway, which may underlie the hyper-excitability phenotype such as hyperactivity or seizure susceptibility in FASD patients.

Acknowledgement to the Reviewers

R. Ader, Rochester, N.Y., USA M. Anthracopoulos, Rio Patras, Greece E.G. Araujo, Rio de Janeiro, Brazil E. Arzt, Buenos Aires, Argentina A. Aubert, Tours, France L. Barbeito, Montevideo, Uruguay M. Bauer, Porto Alegre, Brazil I. Berczi, Winnipeg, Man., Canada H.O. Besedovsky, Marburg, Germany S. Bornstein, Dresden, Germany O. Bottasso, Santa Fe, Argentina S.D. Brain, London, UK A. Buske-Kirschbaum, Dresden, Germany M. Canal, Manchester, UK E. Charmandari, Athens, Greece D. Chiasserini, Perugia, Italy F.A. Costa-Pinto, São Paulo, Brazil M. Dardenne, Paris, France E.G. de Moura, Rio de Janeiro, Brazil K. Dornmair, Martinsried, Germany R.L. Doty, Philadelphia, Pa., USA J. Drouin, Montreal, Que., Canada G.E. Duffield, Notre Dame, Ind., USA A.J. Dunn, Honolulu, Hawaii, USA I. Elenkov, Rome, Italy G.G. Freund, Urbana, Ill., USA R. Furlan, Milan, Italy R.C. Gaillard, Lausanne, Switzerland Y. Gidron, Tilburg, The Netherlands N. Gilhus, Bergen, Norway F. Haour, Paris, France K. Hirata, Kyushu, Japan S.K. Jindal, Chandigarh, India J. Kasckow , Pittsburgh, Pa., USA T. Katafuchi, Fukuoka, Japan