The long-term goal of our research is to understand the molecular and cellular mechanisms governing morphogenesis of the neural tube in vertebrate embryos. The proposed experiments are significant because failure of neural tube morphogenesis is the second most common human birth defect. Our focus is on a cell shape change called apical constriction, a conversion of columnar cells into wedge-shaped cells, that contributes importantly to neural tube closure. Apical constriction involves accumulation of actin filaments at the apical surface of polarized epithelial cells. The molecular mechanisms underlying this process are unknown, but we have shown that a single protein, Shroom, is sufficient to induce both apical actin assembly and apical constriction. Shroom is essential for neural tube closure. This proposal aims to understand how Shroom-mediated reorganization of the actin cytoskeleton influences cell shape changes that are necessary for neural tube closure. We propose to determine the molecular mechanisms of Shroom-mediated actin assembly. We hypothesize that the actin regulators, Arp2/3, formin, and Mena are required for this process. We will test this using a gain-of-function assay for Shroom activity and inhibitors of the actin regulatory proteins. We suggest that cell behaviors associated with apical constriction are inter-related and controlled by Shroom. We will address this with loss-of-function experiments in Xenopus embryos and confocal imaging. Finally, we suggest that a Shroom-related gene, called APXL, controls apical constrictions in cells that lack Shroom expression. We will use both gain- and loss-of-function strategies to test this hypothesis. This work will help to elucidate the regulatory networks that govern cell shape-change in general and neural tube closure in particular. Moreover, this work has the potential to shed light on the underpinnings of human neural tube defects.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM074104-03
Application #
7215712
Study Section
Development - 1 Study Section (DEV)
Program Officer
Haynes, Susan R
Project Start
2005-04-01
Project End
2010-03-31
Budget Start
2007-04-01
Budget End
2008-03-31
Support Year
3
Fiscal Year
2007
Total Cost
$256,104
Indirect Cost
Name
University of Texas Austin
Department
Biology
Type
Schools of Arts and Sciences
DUNS #
170230239
City
Austin
State
TX
Country
United States
Zip Code
78712
Sedzinski, Jakub; Hannezo, Edouard; Tu, Fan et al. (2017) RhoA regulates actin network dynamics during apical surface emergence in multiciliated epithelial cells. J Cell Sci 130:420-428
Sedzinski, Jakub; Hannezo, Edouard; Tu, Fan et al. (2016) Emergence of an Apical Epithelial Cell Surface In Vivo. Dev Cell 36:24-35
Brooks, Eric R; Wallingford, John B (2015) In vivo investigation of cilia structure and function using Xenopus. Methods Cell Biol 127:131-59
Park, Tae Joo; Kim, Su Kyoung; Wallingford, John B (2015) The planar cell polarity effector protein Wdpcp (Fritz) controls epithelial cell cortex dynamics via septins and actomyosin. Biochem Biophys Res Commun 456:562-6
Chung, Mei-I; Kwon, Taejoon; Tu, Fan et al. (2014) Coordinated genomic control of ciliogenesis and cell movement by RFX2. Elife 3:e01439
Brooks, Eric R; Wallingford, John B (2014) Multiciliated cells. Curr Biol 24:R973-82
Tabler, Jacqueline M; Bolger, TriĆ³na G; Wallingford, John et al. (2014) Hedgehog activity controls opening of the primary mouth. Dev Biol 396:1-7
Shindo, Asako; Wallingford, John B (2014) PCP and septins compartmentalize cortical actomyosin to direct collective cell movement. Science 343:649-52
Wallingford, John B; Niswander, Lee A; Shaw, Gary M et al. (2013) The continuing challenge of understanding, preventing, and treating neural tube defects. Science 339:1222002
Chung, Mei-I; Peyrot, Sara M; LeBoeuf, Sarah et al. (2012) RFX2 is broadly required for ciliogenesis during vertebrate development. Dev Biol 363:155-65

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