CNTF/LIF/gp130 receptor complex signaling maintains a VZ precursor differentiation gradient in the developing ventral forebrain

doi:10.1242/dev.01592

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Development ePress online publication date 5 Jan 2005
doi: 10.1242/dev.01592

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Research article

CNTF/LIF/gp130 receptor complex signaling maintains a VZ precursor differentiation gradient in the developing ventral forebrain

Christopher Gregg and Samuel Weiss^*
^* Author for correspondence (e-mail: weiss{at}ucalgary.ca)

The extrinsic signaling pathways responsible for the formationand maintenance of the unique laminar organization of the forebraingerminal zones are largely unknown. In the present study, weasked whether ciliary neurotrophic factor (CNTF)/leukemia inhibitoryfactor (LIF)/gp130 signaling plays a role in the developmentof the germinal layers in the lateral ganglionic eminence. Wefound that CNTF/LIF/gp130 receptor signaling promotes the self-renewal/expansionof a subpopulation of fibroblast growth factor-responsive ventricularzone (VZ) precursors in the ventral forebrain. Analysis of Lifr^-/-mice suggests that CNTF/LIF/gp130 signaling maintains a subpopulationof GSH2+ VZ precursors, which are necessary for normal growthof the early ventral forebrain and for maintaining a gradientof VZ precursor differentiation in the lateral ganglionic eminence,as defined by GSH2, MASH1 and DLX2 expression. Furthermore,addition of exogenous CNTF to embryonic forebrain explant culturesdeprived of choroid plexus-derived CNTF, was sufficient to promotea VZ differentiation gradient. In contrast to the forebrain,CNTF/LIF/gp130 signaling reduced, rather than enhanced, precursorself-renewal/expansion in the spinal cord. These results demonstratea novel region-specific role for CNTF/LIF/gp130 signaling inthe development of the germinal layers of the embryonic telencephalon.

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