%0 Journal Article %1 Probst.2007 %A Probst, B. %A Rock, R. %A Gessler, M. %A Vortkamp, A. %A Pueschel, A. W. %D 2007 %J Dev Biol %K *Sequence Acid Animals Dendrites/*metabolism Dentate Embryo;Mammalian/metabolism Gyrus/cytology/metabolism Hippocampus/cytology Homology;Amino Mice Mice;Knockout Mutation/genetics Nerve Phenotype Proteins/*metabolism Tissue Transfection %N 1 %P 461--470 %T The rodent Four-jointed ortholog Fjx1 regulates dendrite extension %V 312 %X The extrinsic and intrinsic factors that regulate the size and complexity of dendritic arborizations are still poorly understood. Here we identify Fjx1, the rodent ortholog of the Drosophila planar cell polarity (PCP) protein Four-jointed (Fj), as a new inhibitory factor that regulates dendrite extension. The Drosophila gene four-jointed (fj) has been suggested to provide directional information in wing discs, but the mechanism how it acts is only poorly understood and the function of its mammalian homolog Fjx1 remains to be investigated. We analyzed the phenotype of a null mutation for mouse Fjx1. Homozygous Fjx1 mutants show an abnormal morphology of dendritic arbors in the hippocampus. In cultured hippocampal neurons from Fjx1 mutant mice, loss of Fjx1 resulted in an increase in dendrite extension and branching. Addition of Fjx1 to cultures of dissociated hippocampal neurons had the opposite effect and reduced the length of dendrites and decreased dendritic branching. Rescue experiments with cultured neurons showed that Fjx1 can act both cell-autonomously and non-autonomously. Our results identify Fjx1 as a new inhibitory factor that regulates dendrite extension.

@article{Probst.2007, abstract = {The extrinsic and intrinsic factors that regulate the size and complexity of dendritic arborizations are still poorly understood. Here we identify Fjx1, the rodent ortholog of the Drosophila planar cell polarity (PCP) protein Four-jointed (Fj), as a new inhibitory factor that regulates dendrite extension. The Drosophila gene four-jointed (fj) has been suggested to provide directional information in wing discs, but the mechanism how it acts is only poorly understood and the function of its mammalian homolog Fjx1 remains to be investigated. We analyzed the phenotype of a null mutation for mouse Fjx1. Homozygous Fjx1 mutants show an abnormal morphology of dendritic arbors in the hippocampus. In cultured hippocampal neurons from Fjx1 mutant mice, loss of Fjx1 resulted in an increase in dendrite extension and branching. Addition of Fjx1 to cultures of dissociated hippocampal neurons had the opposite effect and reduced the length of dendrites and decreased dendritic branching. Rescue experiments with cultured neurons showed that Fjx1 can act both cell-autonomously and non-autonomously. Our results identify Fjx1 as a new inhibitory factor that regulates dendrite extension.}, added-at = {2013-01-29T13:47:26.000+0100}, author = {Probst, B. and Rock, R. and Gessler, M. and Vortkamp, A. and Pueschel, A. W.}, biburl = {https://www.bibsonomy.org/bibtex/2296f8ee52d373bf28daf540a234d751c/ebch}, interhash = {ce263979dc07ce03f6cb6dc18ce4d7de}, intrahash = {296f8ee52d373bf28daf540a234d751c}, journal = {Dev Biol}, keywords = {*Sequence Acid Animals Dendrites/*metabolism Dentate Embryo;Mammalian/metabolism Gyrus/cytology/metabolism Hippocampus/cytology Homology;Amino Mice Mice;Knockout Mutation/genetics Nerve Phenotype Proteins/*metabolism Tissue Transfection}, number = 1, pages = {461--470}, timestamp = {2013-01-29T13:47:30.000+0100}, title = {The rodent Four-jointed ortholog Fjx1 regulates dendrite extension}, volume = 312, year = 2007 }