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Inactivation of VCP/ter94 suppresses retinal pathology caused by misfolded rhodopsin in DrosophilaElk3 deficiency causes transient impairment in post-natal retinal vascular development and formation of tortuous arteries in adult murine retinaeThe glial and the neuronal glycine transporters differ in their reactivity to sulfhydryl reagentsAnalysis of mammalian gene function through broad-based phenotypic screens across a consortium of mouse clinicsA comparative phenotypic and genomic analysis of C57BL/6J and C57BL/6N mouse strains.High resolution fundus imaging by confocal scanning laser ophthalmoscopy in the mouse.Functional implication of Dp71 in osmoregulation and vascular permeability of the retinaHyperactivation of Alk induces neonatal lethality in knock-in AlkF1178L miceReevaluation of dystrophin localization in the mouse retina.Why glycine transporters have different stoichiometries.beta-Endorphin expression in the mouse retinaDelta opioid receptors regulate temporoammonic-activated feedforward inhibition to the mouse CA1 hippocampus.Deletion of the App-Runx1 region in mice models human partial monosomy 21.Comparing the Bbs10 complete knockout phenotype with a specific renal epithelial knockout one highlights the link between renal defects and systemic inactivation in miceGlycine receptors in a population of adult mammalian cones.Mammalian retinal horizontal cells are unconventional GABAergic neurons.Kir4.1 and AQP4 associate with Dp71- and utrophin-DAPs complexes in specific and defined microdomains of Müller retinal glial cell membrane.Rhodopsin maturation defects induce photoreceptor death by apoptosis: a fly model for RhodopsinPro23His human retinitis pigmentosa.Asymmetrical Functional Deficits of ON and OFF Retinal Processing in the mdx3Cv Mouse Model of Duchenne Muscular Dystrophy.Panretinal, high-resolution color photography of the mouse fundus.The glutamate transporter EAAT5 works as a presynaptic receptor in mouse rod bipolar cells.A postsynaptic signaling pathway that may account for the cognitive defect due to IL1RAPL1 mutation.Drosophila fatty acid transport protein regulates rhodopsin-1 metabolism and is required for photoreceptor neuron survival.Murine neonatal infection provides an efficient model for congenital ocular toxoplasmosis.Panton-Valentine Leukocidin Colocalizes with Retinal Ganglion and Amacrine Cells and Activates Glial Reactions and Microglial Apoptosis.Physiological maturation of photoreceptors depends on the voltage-gated sodium channel NaV1.6 (Scn8a).Proteomic survey reveals altered energetic patterns and metabolic failure prior to retinal degeneration.A Population Study of Common Ocular Abnormalities in C57BL/6N rd8 Mice.Transsynaptic Binding of Orphan Receptor GPR179 to Dystroglycan-Pikachurin Complex Is Essential for the Synaptic Organization of PhotoreceptorsPanton-Valentine Leucocidin Proves Direct Neuronal Targeting and Its Early Neuronal and Glial Impacts a Rabbit Retinal Explant ModelIdentification of genes required for eye development by high-throughput screening of mouse knockoutsErratum: Author Correction: Identification of genes required for eye development by high-throughput screening of mouse knockoutsGTP hydrolysis mechanisms in ras p21 and in the ras-GAP complex studied by fluorescence measurements on tryptophan mutantsEvidence for functional GABAA but not GABAC receptors in mouse cone photoreceptors
P50
Q27346679-EC4CEE7D-8731-48B6-BADC-C46127DA1FAAQ27348777-5BBBAD46-6392-4E85-8530-A31BC6865CC7Q28361613-6AFC7141-D6F9-4999-8BEF-707B7EBCB287Q30389888-3C6C38FC-5672-477C-A303-138A69503155Q30436818-5A8E8B55-5B73-4372-B3DB-4AAC019ABC42Q33227237-4B692349-2864-45F5-B67A-0ECC0D900E90Q33509027-2C99DB59-FD72-4284-8A86-1E325F533315Q33757085-B7922AD9-09DF-4D5A-9B08-4E5742F1111DQ34012496-EB90B007-0559-49D1-A6D2-398A9656AFABQ34922230-1A276659-C67D-4304-AF0E-7AE7E92C99A7Q34985213-9B944012-C033-4D2A-8BAE-A683FE3C0CCCQ35048207-D04F5F11-337B-430C-8216-FE85AA23CD1FQ35687108-389E8D7D-9294-44CC-83AB-3D6088438EF7Q35951221-8C8EC559-EAC4-4FA2-B0E9-0C411B125038Q38890457-5265904C-9C28-4862-A49C-D0EB7FEC1458Q38970284-7C82F4B8-4165-4A9B-8ECD-1CCA605923A1Q39008841-2C90996E-82B5-4DC6-BE00-C3689A31A538Q39016254-C14143B0-4D0A-4EB3-AC49-527774D14E02Q39238183-1D008CFB-7FB1-4C07-90C6-F7ABD347D49AQ39337698-599CE225-B744-4026-A40B-95CBF66BE656Q39587671-6F673CB3-DD6A-4397-9E17-ED10BECF6A34Q39753533-176FF1E4-0C4E-4D0D-8043-45CCE81A97CBQ42118593-ADB2139F-AD72-4BB2-B46D-61795E4096BDQ48459046-897423E6-9352-4222-8BED-531B3D3BC44AQ49746282-9345AF6E-0074-4B29-8672-4D0E09560F28Q52049502-96A06B81-5548-472A-A373-8C0EE72C7BE0Q52766506-D5D65CF3-4348-41E6-A59F-CFA86364D37DQ55076091-B0DFA835-2291-453B-B087-9708961233ECQ57044836-9449EB2B-98BF-4847-870F-76DD57452508Q58613254-FA187D6B-5DB0-4F2A-B403-D7CD72F83285Q60300295-AE08F54B-A809-4A80-B7D7-D8C14C74C297Q64120095-A8375340-F10E-420C-B9AE-4CD24AC71D84Q67962000-F0C4B193-4C4F-45DE-BD7C-308A43D902FAQ92746039-D0E3F2EC-4661-4AC8-BB5E-47C099ED0B87
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Michel Roux
@ast
Michel Roux
@en
Michel Roux
@es
Michel Roux
@nl
Michel Roux
@sl
type
label
Michel Roux
@ast
Michel Roux
@en
Michel Roux
@es
Michel Roux
@nl
Michel Roux
@sl
prefLabel
Michel Roux
@ast
Michel Roux
@en
Michel Roux
@es
Michel Roux
@nl
Michel Roux
@sl
P1053
A-3213-2009
P106
P21
P31
P3829
P496
0000-0002-5812-5215
P569
2000-01-01T00:00:00Z