Hedgehog regulated Slit expression determines commissure and glial cell position in the zebrafish forebrain

doi:10.1242/dev.01929

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Development ePress online publication date 20 Jul 2005
doi: 10.1242/dev.01929

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Research article

Hedgehog regulated Slit expression determines commissure and glial cell position in the zebrafish forebrain

Michael J.F. Barresi, Lara D. Hutson, Chi-Bin Chien, and Rolf O. Karlstrom^*
^* Author for correspondence (e-mail: karlstrom{at}bio.umass.edu)

Three major axon pathways cross the midline of the vertebrateforebrain early in embryonic development: the postoptic commissure(POC), the anterior commissure (AC) and the optic nerve. Weshow that a small population of Gfap+ astroglia spans the midlineof the zebrafish forebrain in the position of, and prior to,commissural and retinal axon crossing. These glial 'bridges'form in regions devoid of the guidance molecules slit2 and slit3,although a subset of these glial cells express slit1a. We showthat Hh signaling is required for commissure formation, glialbridge formation, and the restricted expression of the guidancemolecules slit1a, slit2, slit3 and sema3d, but that Hh doesnot appear to play a direct role in commissural and retinalaxon guidance. Reducing Slit2 and/or Slit3 function expandedthe glial bridges and caused defasciculation of the POC, consistentwith a 'channeling' role for these repellent molecules. By contrast,reducing Slit1a function led to reduced midline axon crossing,suggesting a distinct role for Slit1a in midline axon guidance.Blocking Slit2 and Slit3, but not Slit1a, function in the Hhpathway mutant yot (gli2DR) dramatically rescued POC axon crossingand glial bridge formation at the midline, indicating that expandedSlit2 and Slit3 repellent function is largely responsible forthe lack of midline crossing in these mutants. This analysisshows that Hh signaling helps to pattern the expression of Slitguidance molecules that then help to regulate glial cell positionand axon guidance across the midline of the forebrain.

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