about
P184
Pioneer longitudinal axons navigate using floor plate and Slit/Robo signalsMultiple requirements for Hes 1 during early eye formationR-cadherin is a Pax6-regulated, growth-promoting cue for pioneer axonsPax-6 functions in boundary formation and axon guidance in the embryonic mouse forebrainPax6 guides a relay of pioneer longitudinal axons in the embryonic mouse forebrainRobo1 and Robo2 have distinct roles in pioneer longitudinal axon guidanceMotor neuron cell bodies are actively positioned by Slit/Robo repulsion and Netrin/DCC attraction.Pax6 regulates the identity of embryonic diencephalic neurons.Ascending midbrain dopaminergic axons require descending GAD65 axon fascicles for normal pathfindingTwo miRNA clusters, miR-34b/c and miR-449, are essential for normal brain development, motile ciliogenesis, and spermatogenesis.Identification of target genes regulated by homeotic proteins in Drosophila melanogaster through genetic selection of Ultrabithorax protein-binding sites in yeast.Pioneer midbrain longitudinal axons navigate using a balance of Netrin attraction and Slit repulsion.Precocious retinal neurons: Pax6 controls timing of differentiation and determination of cell typeSlit-Robo signals regulate pioneer axon pathfinding of the tract of the postoptic commissure in the mammalian forebrainSparking new frontiers: using in vivo electroporation for genetic manipulations.Slit and Semaphorin signaling governed by Islet transcription factors positions motor neuron somata within the neural tubeMotor axon exit from the mammalian spinal cord is controlled by the homeodomain protein Nkx2.9 via Robo-Slit signaling.Netrin1-DCC-Mediated Attraction Guides Post-Crossing Commissural Axons in the HindbrainThe Slit receptor Robo1 is predominantly expressed via the Dutt1 alternative promoter in pioneer neurons in the embryonic mouse brain and spinal cord.Dscam guides embryonic axons by Netrin-dependent and -independent functionsA dlx2- and pax6-dependent transcriptional code for periglomerular neuron specification in the adult olfactory bulb.ISL1-based LIM complexes control Slit2 transcription in developing cranial motor neurons.Longitudinal axons are guided by Slit/Robo signals from the floor plate.Caveolin-1 and a 29-kDa caveolin-associated protein are phosphorylated on tyrosine in cells expressing a temperature-sensitive v-Abl kinase.Contralateral migration of oculomotor neurons is regulated by Slit/Robo signaling.Midbrain dopaminergic axons are guided longitudinally through the diencephalon by Slit/Robo signals.Initial organization of neurons and tracts in the embryonic mouse fore- and midbrain.Repression and activation of the Drosophila dopa decarboxylase gene in glia.Male jeffrey pine beetle, Dendroctonus jeffreyi, synthesizes the pheromone component frontalin in anterior midgut tissue.Dlx transcription factors regulate differentiation of dopaminergic neurons of the ventral thalamus.EphB receptor tyrosine kinases control morphological development of the ventral midbrain.Motor axons are guided to exit points in the spinal cord by Slit and Netrin signals.Motor neuron migration and positioning mechanisms: New roles for guidance cues.Early deletion of neuromeres in Wnt-1-/- mutant mice: evaluation by morphological and molecular markers.Midgut tissue of male pine engraver, Ips pini, synthesizes monoterpenoid pheromone component ipsdienol de novo.Mutations within the Ddc promoter alter its neuron-specific pattern of expression.Neurophilic Descending Migration of Dorsal Midbrain Neurons Into the HindbrainFam49/CYRI interacts with Rac1 and locally suppresses protrusionsRobo1 and 2 Repellent Receptors Cooperate to Guide Facial Neuron Cell Migration and Axon Projections in the Embryonic Mouse Hindbrain
P50
Q24647738-04e27dc8-4cba-9be1-464f-5b3fcfd0b604Q28506484-E988CE59-02DC-47F3-A27B-9204A32CAEE3Q28507190-3db56c7c-471e-fc14-5e14-d958ed567016Q28586871-b9e94626-43f1-2b0e-d148-69a87146853dQ28592611-68f9025e-45f3-0195-a888-e6d6dc8ce14aQ29394617-71bf47d5-412f-63dd-fcef-5a5e3c8dcd07Q30389570-5afc2d08-430b-024d-64a5-4850de400a0dQ31847154-48215c13-486e-030a-822b-69dfd3c74a1fQ33714104-07134627-443b-9cc3-e6d6-b48dc8a3bf77Q33925986-ca81000b-4e6a-461c-cee2-56cfd2cece8aQ33964269-dc26c5f0-4985-b939-f6d5-18135ead1db0Q33986090-6F93061E-40FA-4D37-BBBD-C3536E549143Q34026421-09f141dc-4d81-43f1-74a9-84b762bb9b96Q34026436-b671eb52-4442-a5f0-00bd-db5dbd3ee569Q34229786-a2ae62f4-4012-1021-2918-0d617c5d92ecQ35655538-1c7425e8-4bb5-5c7a-4096-5517c6dd5df5Q35841010-c0409a4d-4044-2b14-7526-363ea47fceafQ35968151-f51015ea-4ae1-b23e-ded1-14c072e2ab1eQ36149114-48c64449-4c45-201f-cd2b-c7f42c192466Q37266626-A3583D48-1DCC-4DC6-B012-3EFEBE99D369Q37352341-24998642-4db0-bc04-f80c-477a8717cfa8Q37397243-200A257A-AB7B-4629-9A3B-9E7809C5A991Q37705754-46c6a719-4f9c-6e7a-0120-dc12a2565eedQ40807873-f1e98405-4d63-f663-527b-00336d9d2b41Q41539591-088f36b6-4099-ef55-218b-e043a8d870c2Q42098267-e15d5e65-43d1-e039-d312-79e90806cc97Q42514615-97829cdd-44fd-de04-7412-f5be84e2e20cQ43183420-62577bcc-48ec-9fe6-bef1-82105004ad5eQ44221000-3889363a-435b-0ffc-0495-a1e3006c5ecaQ44473486-0d5e4317-4218-36c4-3972-5964ad5339eaQ46417017-d5a36cd3-4311-508f-a92e-3c1cec412a9dQ47685682-1844df7f-474e-00b2-65f6-98b41097664fQ47968291-faded215-4df1-ca14-1806-295767917ceeQ48891192-5021c2ea-40c3-59f7-cd52-5e99da6e099dQ50233703-adf7d89d-4d6f-b790-6638-a1dd2eada8e9Q52446767-ea1856d2-4a3a-d245-8b38-587084d5eec7Q59335614-0acc282d-40ed-298b-144f-66446b98ef2cQ62023162-E9541920-9F17-45A3-BED8-5B1AF3DCBCA9Q91237656-FA6BA5F6-2373-41D8-BC47-306776B27145
P50
description
neuroscientist
@en
wetenschapper
@nl
name
Grant Mastick
@ast
Grant Mastick
@en
Grant Mastick
@es
Grant Mastick
@nl
type
label
Grant Mastick
@ast
Grant Mastick
@en
Grant Mastick
@es
Grant Mastick
@nl
altLabel
Grant S Mastick
@en
Grant S. Mastick
@en
prefLabel
Grant Mastick
@ast
Grant Mastick
@en
Grant Mastick
@es
Grant Mastick
@nl
P1053
A-2907-2013
P1153
6602818064
P185
P1960
ZNyxV3QAAAAJ
P21
P2381
P2798
P31
P3829
P496
0000-0002-9148-6194