Xueyao Fu scite author profile

Understanding gene regulatory networks (GRNs) that control neuronal differentiation will provide systems-level perspectives on neurogenesis. We have previously constructed a model for a GRN in retinal ganglion cell (RGC) differentiation in which four hierarchical tiers of transcription factors ultimately control the expression of downstream terminal genes. Math5 occupies a central node in the hierarchy because it is essential for the formation of RGCs and the expression of the immediate downstream factor Pou4f2. Based on its expression, we also proposed that Isl1, a LIM-homeodomain factor, functions in parallel with Pou4f2 and downstream of Math5 in the RGC GRN. To determine whether this was the case, a conditional Isl1 allele was generated and deleted specifically in the developing retina. Although RGCs formed in Isl1-deleted retinas, most underwent apoptosis, and few remained at later stages. By microarray analysis, we identified a distinct set of genes whose expression depended on Isl1. These genes are all downstream of Math5, and some of them, but not all, also depend on Pou4f2. Additionally, Isl1 was required for the sustained expression of Pou4f2, suggesting that Isl1 positively regulates Pou4f2 after Math5 levels are diminished. The results demonstrate an essential role for Isl1 in RGC development and reveal two distinct but intersecting branches of the RGC GRN downstream of Math5, one directed by Pou4f2 and the other by Isl1. They also reveal that identical RGC expression patterns are achieved by different combinations of divergent inputs from upstream transcription factors.cell differentiation ͉ gene regulatory network ͉ transcription factors ͉ retinogenesis R etinal development is especially attractive for gene regulatory network (GRN) analysis because it represents a relatively simple, highly amenable sensory tissue with a small number of neuronal cell types connected to visual centers in the brain by the optic nerve (1, 2). A canonical GRN has been proposed for retinal determination genes in insects and mammals that is composed of seven to eight highly conserved transcription factors (3). In the mouse, one of the retinal determination factors, the pair-rule homeobox factor Pax6, is essential for the formation of all retinal cell types with the exception of amacrine cells (4). Pax6 is required in retinal progenitor cells (RPCs) for the expression of several critical transcription factors that then control the development of individual retinal cell types. One of these factors is Math5, a proneural basic helix-loop-helix factor that is essential for specifying retinal ganglion cells (RGCs) (5, 6), the first cells to differentiate in the developing retina. Pax6-Math5-expressing RPCs define a competence field that permits the subsequent steps of RGC formation to proceed (7,8). Based on these facts, we have constructed a GRN model for RGC development that features a downward cascade of transcription factors occupying distinct hierarchical tiers (8).In the RGC GRN, Math5 activates genes that encode immediat...

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Effects of Phospholipid Composition on MinD-Membrane Interactions in Vitro and in Vivo

Mileykovskaya¹,

Fishov

Fu³

et al. 2003

Journal of Biological Chemistry

161

191

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The peripheral membrane ATPase MinD is a component of the Min system responsible for correct placement of the division site in Escherichia coli cells. By rapidly migrating from one cell pole to the other, MinD helps to block unwanted septation events at the poles. MinD is an amphitropic protein that is localized to the membrane in its ATP-bound form. A C-terminal domain essential for membrane localization is predicted to be an amphipathic ␣-helix with hydrophobic residues interacting with lipid acyl chains and cationic residues on the opposite face of the helix interacting with the head groups of anionic phospholipids (Szeto, T. H., Rowland, S. L., Rothfield, L. I., and King, G. F.

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A gene network downstream of transcription factor Math5 regulates retinal progenitor cell competence and ganglion cell fate

Sun

et al. 2005

Developmental Biology

125

148

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Math5, a mouse homolog of the Drosophila proneural bHLH transcription factor Atonal, is essential in the developing retina to establish retinal progenitor cell competence for a ganglion cell fate. Elucidating the mechanisms by which Math5 influences progenitor cell competence is crucial for understanding how specification of neuronal cell fate occurs in the retina and it requires knowledge of the downstream target genes that depend on Math5 for their expression. To date, only a handful of genes downstream of Math5 have been identified. To better define the gene network operating downstream of Math5, we used custom-designed microarrays to examine the changes in embryonic retinal gene expression caused by deletion of math5. We identified 270 Math5-dependent genes, including those that were expressed specifically either in progenitor cells or differentiated ganglion cells. The ganglion cell-specific genes included both Brn3b-dependent and Brn3b-independent genes, indicating that Math5 regulates distinct branches of the gene network responsible for retinal ganglion cell differentiation. In math5-null progenitor cells, there was an up-regulation of the proneural genes math3, neuroD, and ngn2, indicating that Math5 suppresses the production of other cell types in addition to promoting retinal ganglion cell formation. The promoter regions of many Math5-dependent genes contained binding sites for REST/NRSF, suggesting that release from general repression in retinal progenitor cells is required for ganglion cell-specific gene activation. The identification of multiple roles for Math5 provides new insights into the gene network that defines progenitor cell competence in the embryonic retina.

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Canonical Wnt signaling functions in second heart field to promote right ventricular growth

Wang

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

179

138

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The second heart field (SHF), progenitor cells that are initially sequestered outside the heart, migrates into the heart and gives rise to endocardium, myocardium, and smooth muscle. Because of its distinct developmental history, the SHF is likely subjected to different signals from that of the first heart field. Previous experiments revealed that canonical Wnt signaling negatively regulated first heart field specification. We inactivated the obligate canonical Wnt effector ␤-catenin using a ␤-catenin conditional null allele and the Mef2c AHF cre driver that directs cre activity specifically in SHF. We also expressed a stabilized form of ␤-catenin to model continuous Wnt signaling in SHF. Our data indicate that Wnt signaling acts in a positive fashion to promote right ventricular and interventricular myocardial expansion. Cyclin D2 and Tgf␤2 expression was drastically reduced in ␤-catenin loss-of-function mutants, indicating that Wnt signaling is required for patterning and expansion of SHF derivatives. Our findings reveal that Wnt signaling plays a major positive role in promoting growth and diversification of SHF precursors into right ventricular and interventricular myocardium.conditional genetics ͉ cardiac progenitor ͉ mouse ͉ development

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Xueyao Fu

Gene-regulation logic in retinal ganglion cell development: Isl1 defines a critical branch distinct from but overlapping with Pou4f2

Effects of Phospholipid Composition on MinD-Membrane Interactions in Vitro and in Vivo

A gene network downstream of transcription factor Math5 regulates retinal progenitor cell competence and ganglion cell fate

Canonical Wnt signaling functions in second heart field to promote right ventricular growth

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