Literature DB >> 22218899

Analysis of PCP defects in mammalian eye lens.

Yuki Sugiyama1, John W McAvoy.   

Abstract

Multicellular tissues and organs often show planar cell polarity (PCP) where the constituent cells align along an axis to form coordinated patterns. Mammalian eye lenses are mainly comprised of epithelial-derived fibre cells, which exhibit highly ordered alignment that is regulated by PCP signaling. Each fibre cell has an apically situated primary cilium and in most cases this is polarized towards the lens anterior pole. Here we describe how to visualize the global cellular alignment of lens fibre cells by examining the suture pattern that is formed by the tips of fibres meeting at the anterior pole. We also describe a method for whole mount preparation, which allows observation of the polarized distribution of primary cilia at the apical surface of lens fibres. Given its relative simplicity, at least in cellular terms, and its requirement for a high degree of precision in cellular alignment and orientation, we predict that the lens will be an excellent model system to help elucidate the role of cilia and PCP components in the development of three-dimensional organization in tissues and organs.

Entities:  

Mesh:

Year:  2012        PMID: 22218899      PMCID: PMC3812065          DOI: 10.1007/978-1-61779-510-7_12

Source DB:  PubMed          Journal:  Methods Mol Biol        ISSN: 1064-3745


  13 in total

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Authors:  R Ashery-Padan; T Marquardt; X Zhou; P Gruss
Journal:  Genes Dev       Date:  2000-11-01       Impact factor: 11.361

Review 2.  Tissue/planar cell polarity in vertebrates: new insights and new questions.

Authors:  Yanshu Wang; Jeremy Nathans
Journal:  Development       Date:  2007-02       Impact factor: 6.868

Review 3.  Frizzled/PCP signalling: a conserved mechanism regulating cell polarity and directed motility.

Authors:  Jessica R K Seifert; Marek Mlodzik
Journal:  Nat Rev Genet       Date:  2007-02       Impact factor: 53.242

4.  Ciliogenesis defects in embryos lacking inturned or fuzzy function are associated with failure of planar cell polarity and Hedgehog signaling.

Authors:  Tae Joo Park; Saori L Haigo; John B Wallingford
Journal:  Nat Genet       Date:  2006-02-19       Impact factor: 38.330

5.  Basal bodies, kinocilia and planar cell polarity.

Authors:  Jeffrey D Axelrod
Journal:  Nat Genet       Date:  2008-01       Impact factor: 38.330

Review 6.  Polycystic kidney disease: cell division without a c(l)ue?

Authors:  M Simons; G Walz
Journal:  Kidney Int       Date:  2006-06-28       Impact factor: 10.612

7.  Disruption of Bardet-Biedl syndrome ciliary proteins perturbs planar cell polarity in vertebrates.

Authors:  Alison J Ross; Helen May-Simera; Erica R Eichers; Masatake Kai; Josephine Hill; Daniel J Jagger; Carmen C Leitch; J Paul Chapple; Peter M Munro; Shannon Fisher; Perciliz L Tan; Helen M Phillips; Michel R Leroux; Deborah J Henderson; Jennifer N Murdoch; Andrew J Copp; Marie-Madeleine Eliot; James R Lupski; David T Kemp; Hélène Dollfus; Masazumi Tada; Nicholas Katsanis; Andrew Forge; Philip L Beales
Journal:  Nat Genet       Date:  2005-09-18       Impact factor: 38.330

Review 8.  The primary cilium as the cell's antenna: signaling at a sensory organelle.

Authors:  Veena Singla; Jeremy F Reiter
Journal:  Science       Date:  2006-08-04       Impact factor: 47.728

9.  Insertion of a Pax6 consensus binding site into the alphaA-crystallin promoter acts as a lens epithelial cell enhancer in transgenic mice.

Authors:  Haotian Zhao; Ying Yang; Christian M Rizo; Paul A Overbeek; Michael L Robinson
Journal:  Invest Ophthalmol Vis Sci       Date:  2004-06       Impact factor: 4.799

Review 10.  Planar cell polarity: one or two pathways?

Authors:  Peter A Lawrence; Gary Struhl; José Casal
Journal:  Nat Rev Genet       Date:  2007-06-12       Impact factor: 53.242
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  6 in total

1.  Dual function of Yap in the regulation of lens progenitor cells and cellular polarity.

Authors:  Ji Yun Song; Raehee Park; Jin Young Kim; Lucinda Hughes; Li Lu; Seonhee Kim; Randy L Johnson; Seo-Hee Cho
Journal:  Dev Biol       Date:  2013-12-31       Impact factor: 3.582

2.  Loss of Sip1 leads to migration defects and retention of ectodermal markers during lens development.

Authors:  Abby L Manthey; Salil A Lachke; Paul G FitzGerald; Robert W Mason; David A Scheiblin; John H McDonald; Melinda K Duncan
Journal:  Mech Dev       Date:  2013-10-23       Impact factor: 1.882

3.  The klotho-related protein KLPH (lctl) has preferred expression in lens and is essential for expression of clic5 and normal lens suture formation.

Authors:  Jianguo Fan; Joshua Lerner; M Keith Wyatt; Phillip Cai; Katherine Peterson; Lijin Dong; Graeme Wistow
Journal:  Exp Eye Res       Date:  2018-02-07       Impact factor: 3.467

Review 4.  The molecular mechanisms underlying lens fiber elongation.

Authors:  Dylan S Audette; David A Scheiblin; Melinda K Duncan
Journal:  Exp Eye Res       Date:  2016-03-23       Impact factor: 3.467

5.  Non-essential role for cilia in coordinating precise alignment of lens fibres.

Authors:  Yuki Sugiyama; Elizabeth J Shelley; Bradley K Yoder; Zbynek Kozmik; Helen L May-Simera; Philip L Beales; Frank J Lovicu; John W McAvoy
Journal:  Mech Dev       Date:  2016-01-26       Impact factor: 1.882

6.  Crim1 regulates integrin signaling in murine lens development.

Authors:  Ying Zhang; Jieqing Fan; Joshua W K Ho; Tommy Hu; Stephen C Kneeland; Xueping Fan; Qiongchao Xi; Michael A Sellarole; Wilhelmine N de Vries; Weining Lu; Salil A Lachke; Richard A Lang; Simon W M John; Richard L Maas
Journal:  Development       Date:  2015-12-17       Impact factor: 6.868
  6 in total

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