Reelin deficiency causes specific defects in the molecular composition of the synapses in the adult brain
about
Dab1 stabilizes its interaction with Cin85 by suppressing Cin85 phosphorylation at serine 587GABAB-mediated rescue of altered excitatory-inhibitory balance, gamma synchrony and behavioral deficits following constitutive NMDAR-hypofunction.The involvement of Reelin in neurodevelopmental disorders.New Insights into Reelin-Mediated Signaling PathwaysRELN Mutations in Autism Spectrum DisorderEpigenetic RELN Dysfunction in Schizophrenia and Related Neuropsychiatric DisordersSchizophrenia and reelin: a model based on prenatal stress to study epigenetics, brain development and behaviorReelin-Related Disturbances in Depression: Implications for Translational StudiesBalancing Proliferation and Connectivity in PTEN-associated Autism Spectrum DisorderPrenatal stress down-regulates Reelin expression by methylation of its promoter and induces adult behavioral impairments in ratsThe Neurobiological Basis for Social Affiliation in Autism Spectrum Disorder and Schizophrenia.Dab1 is required for synaptic plasticity and associative learningReelin Regulates the Maturation of Dendritic Spines, Synaptogenesis and Glial Ensheathment of Newborn Granule Cells.Identification of a 31-bp deletion in the RELN gene causing lissencephaly with cerebellar hypoplasia in sheep.Extracellular proteolysis of reelin by tissue plasminogen activator following synaptic potentiationTargeting mTOR as a novel therapeutic strategy for traumatic CNS injuries.F-spondin gene transfer improves memory performance and reduces amyloid-β levels in mice.Decreased reelin expression and organophosphate pesticide exposure alters mouse behaviour and brain morphologyIdentification of RELN variation p.Thr3192Ser in a Chinese family with schizophreniaContributions of VLDLR and LRP8 in the establishment of retinogeniculate projectionsA Complex Interaction Between Reduced Reelin Expression and Prenatal Organophosphate Exposure Alters Neuronal Cell Morphology.Development and characterization of NEX- Pten, a novel forebrain excitatory neuron-specific knockout mouse.CG hypomethylation in Lsh-/- mouse embryonic fibroblasts is associated with de novo H3K4me1 formation and altered cellular plasticity.Extracellular matrix control of dendritic spine and synapse structure and plasticity in adulthood.The Role of Reelin Signaling in Alzheimer's Disease.The Functional and Molecular Properties, Physiological Functions, and Pathophysiological Roles of GluN2A in the Central Nervous System.Experience-Dependent Regulation of Cajal-Retzius Cell Networks in the Developing and Adult Mouse Hippocampus.The Role of GluN2A in Cerebral Ischemia: Promoting Neuron Death and Survival in the Early Stage and Thereafter.Functional Roles of the Interaction of APP and Lipoprotein Receptors.Interference with the PTEN-MAST2 interaction by a viral protein leads to cellular relocalization of PTEN.Interfering of the Reelin/ApoER2/PSD95 Signaling Axis Reactivates Dendritogenesis of Mature Hippocampal Neurons.Association between RELN Gene Polymorphisms and Attention Deficit Hyperactivity Disorder in Korean Children.Heterozygous reelin mutations cause autosomal-dominant lateral temporal epilepsy.Multivariate synaptic and behavioral profiling reveals new developmental endophenotypes in the prefrontal cortex.Reelin Exerts Structural, Biochemical and Transcriptional Regulation Over Presynaptic and Postsynaptic Elements in the Adult HippocampusNicotine restores Wt-like levels of reelin and GAD67 gene expression in brain of heterozygous reeler mice.The de novo autism spectrum disorder RELN R2290C mutation reduces Reelin secretion and increases protein disulfide isomerase expression.Corticosterone treatment during adolescence induces down-regulation of reelin and NMDA receptor subunit GLUN2C expression only in male mice: implications for schizophrenia.Structural and Synaptic Organization of the Adult Mouse Somatosensory Neocortex: A Comparative Fine-Scale Electron Microscopic Study of With Wild Type MiceReelin in the Years: Controlling Neuronal Migration and Maturation in the Mammalian Brain
P2860
05e988282810224ae4afbdba62f36e2274f74f8809ed6526a97538397f78c40222efeea025e8183f21d956050dbd8fc3794eced2169b2887ac7ce8592381844c10e19b257f5dc17d68a7510fdb5f860d26e9e5d50c1c0052875c6d30de71cafc655fe04f2a3478cb6005a989885065e07db8d9e696a4a6f52c062fab41ac445c5562266cb93b30d3a807879b3e297292da1de227726d7f662c0692880d12c1b642a82ae92abc4f62781752114defb843e43ce6454804b35e695d447c033324fa40772e528145506f51dc861c963d01497d9a2ea1c2852ecaa62a08ad730f1614547c41bc803d2b957caef90e760dd0298511e4bdcccc8f46e91022133c93035752fab6dd97731d4083bb717b75129f59a9bcc916e6ab0d3b9b9c1e6d81f015f8db8275b55dc635fc894bee6ac38f732f358820e1b92ce1d42d630c6c6b19039cef8a82f228996152b0e30fa9ab85aaa1b7038d4af15a09f67e67c26156ada99e96580e90921c9358f9d487b36b6156b3a0f0371cf2b2851f8c7b4a07
P248
Q24304886-8B934039-25FD-41F7-B032-A9ADF726F906Q24625065-755D89AB-FC82-4442-85BB-3108BA666745Q24632484-DCE127EF-4D92-41AE-9603-61445A6F154FQ26744747-6FD9A73C-7FF5-4F1A-A8B7-1224526D5198Q26750436-6CC5F02E-9E42-4612-B15F-CCA1476CF9ABQ26752594-85C5862A-F7A4-45C3-B696-A577142B2F91Q26766246-87910231-E24C-4FFD-BA74-203D1DF566BEQ26768609-81E15D46-67DF-4596-9D8E-3CC28F92D1E8Q26822064-17A03DBC-0E20-43A7-BAA9-DE6143BA0169Q28543467-3CB7AA6C-ED04-41A3-94C2-BE628DBB103CQ30355076-0A26C947-B34C-4E90-A2FC-0BA7C78F9729Q30441312-4B04F802-C5BA-4E60-9307-CCB8FB476E4EQ30823270-EB35AFC8-0E70-4F2A-B6BB-9C6DBC84ECABQ35049421-6FBE2624-3DB0-4311-81B5-07ECE6AA7465Q35239810-C317BFF9-6F81-4933-9691-321911DB0D84Q36140051-A17E53E4-1651-49EF-9AD4-86D56BFB6D04Q36317638-AB206F8B-A512-4417-90F3-1B5EC3890683Q36617356-803533E3-F515-4E34-8013-D6F5664474BCQ36793075-049B9747-BD1C-4EE1-86F0-46D0F3AF9CCCQ36937621-E79FA861-CF70-475A-8FD3-E7F5676F6A9DQ37129205-2F27B5DA-15B4-4F34-A3B0-5E6153DE6875Q37156089-6FE61F51-F0C2-4A22-AC72-8A07D61DCB7BQ37725247-A988B84C-ED18-4716-B14E-950D4934EB5AQ38264895-9523FADB-A000-4A4E-8229-2400069FD869Q38613647-467B9B01-DADB-44D5-BB6B-720360CA0DACQ38707263-6DBA9368-9029-4B2A-8B91-F087ED2F97F8Q38715296-12615D10-4B72-4165-9689-5729C9B08EB3Q39094792-6C7606FD-E2B1-44BF-A313-D2890C73C180Q39180867-B6E45D94-83AA-4DB5-90A6-E911B44B24AEQ39297251-833E7D64-07C9-4912-9FA9-881B450C9ADCQ39366268-AC70419C-42EF-449C-A776-7D747EBA4022Q39928217-FCAF0B0F-FFEC-4628-ADC4-C99DE3278F3AQ40866479-053F1967-4A1E-4C7F-B4CE-D62387A9F128Q41523202-A063C0D2-B424-4D59-8947-2F7DB6741C8BQ42102539-D360C84E-87B0-4748-B22F-DEC890FA3BE7Q46314942-85A7E380-E946-4A2D-902C-BF50D1624625Q48264269-277D6886-C0CF-439D-9F10-D379DEAEB3D0Q50658844-BDC31E53-46B2-414F-9FA2-0C2DB0692D5CQ57817979-7274B885-83E6-4D9C-B3D8-CE9E9584683CQ59047757-FCF50354-6432-4100-B70F-A67C080222BC
P2860
Reelin deficiency causes specific defects in the molecular composition of the synapses in the adult brain
description
2011 թուականի Օգոստոսին հրատարակուած գիտական յօդուած
@hyw
2011 թվականի օգոստոսին հրատարակված գիտական հոդված
@hy
artículu científicu espublizáu en 2011
@ast
im August 2011 veröffentlichter wissenschaftlicher Artikel
@de
scientific journal article
@en
vedecký článok (publikovaný 2011/08/25)
@sk
vědecký článek publikovaný v roce 2011
@cs
wetenschappelijk artikel (gepubliceerd op 2011/08/25)
@nl
наукова стаття, опублікована в серпні 2011
@uk
مقالة علمية نشرت في 25-8-2011 حول موضوع: دماغ
@ar
name
Reelin deficiency causes speci ...... he synapses in the adult brain
@ast
Reelin deficiency causes speci ...... he synapses in the adult brain
@en
Reelin deficiency causes speci ...... he synapses in the adult brain
@nl
type
label
Reelin deficiency causes speci ...... he synapses in the adult brain
@ast
Reelin deficiency causes speci ...... he synapses in the adult brain
@en
Reelin deficiency causes speci ...... he synapses in the adult brain
@nl
prefLabel
Reelin deficiency causes speci ...... he synapses in the adult brain
@ast
Reelin deficiency causes speci ...... he synapses in the adult brain
@en
Reelin deficiency causes speci ...... he synapses in the adult brain
@nl
P2093
P921
P3181
P1433
P1476
Reelin deficiency causes speci ...... he synapses in the adult brain
@en
P2093
A. Ventruti
G. D'Arcangelo
T. M. Kazdoba
P3181
P356
10.1016/J.NEUROSCIENCE.2011.05.050
P407
P577
2011-08-25T00:00:00Z