Literature DB >> 27109030

Intrinsic and extrinsic regulatory mechanisms are required to form and maintain a lens of the correct size and shape.

J W McAvoy1, L J Dawes2, Y Sugiyama2, F J Lovicu3.   

Abstract

Understanding how tissues and organs acquire and maintain an appropriate size and shape remains one of the most challenging areas in developmental biology. The eye lens represents an excellent system to provide insights into regulatory mechanisms because in addition to its relative simplicity in cellular composition (being made up of only two forms of cells, epithelial and fiber cells), these cells must become organized to generate the precise spheroidal arrangement that delivers normal lens function. Epithelial and fiber cells also represent spatially distinct proliferation and differentiation compartments, respectively, and an ongoing balance between these domains must be tightly regulated so that the lens achieves and maintains appropriate dimensions during growth and ageing. Recent research indicates that reciprocal inductive interactions mediated by Wnt-Frizzled and Notch-Jagged signaling pathways are important for maintaining and organizing these compartments. The Hippo-Yap pathway has also been implicated in maintaining the epithelial progenitor compartment and regulating growth processes. Thus, whilst some molecules and mechanisms have been identified, further work in this important area is needed to provide a clearer understanding of how lens size and shape is regulated.
Copyright © 2016 Elsevier Ltd. All rights reserved.

Entities:  

Keywords:  Epithelial cell proliferation; FGF; Fiber cell differentiation; Hippo-yap; Lens epithelial cells; Lens fiber cells; Lens morphogenesis; Notch-jagged; Wnt-frizzled

Mesh:

Substances:

Year:  2016        PMID: 27109030      PMCID: PMC5360546          DOI: 10.1016/j.exer.2016.04.009

Source DB:  PubMed          Journal:  Exp Eye Res        ISSN: 0014-4835            Impact factor:   3.467


  40 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.  The penny pusher: a cellular model of lens growth.

Authors:  Yanrong Shi; Alicia De Maria; Snježana Lubura; Hrvoje Šikić; Steven Bassnett
Journal:  Invest Ophthalmol Vis Sci       Date:  2014-12-16       Impact factor: 4.799

3.  Accommodation of an endocapsular silicone lens (Phaco-Ersatz) in the nonhuman primate.

Authors:  E Haefliger; J M Parel; F Fantes; E W Norton; D R Anderson; R K Forster; E Hernandez; W J Feuer
Journal:  Ophthalmology       Date:  1987-05       Impact factor: 12.079

4.  The tumor suppressor merlin is required for cell cycle exit, terminal differentiation, and cell polarity in the developing murine lens.

Authors:  Luke A Wiley; Lisa K Dattilo; Kai B Kang; Marco Giovannini; David C Beebe
Journal:  Invest Ophthalmol Vis Sci       Date:  2010-02-24       Impact factor: 4.799

5.  Lens thickness and five-year cumulative incidence of cataracts: The Beaver Dam Eye Study.

Authors:  B E Klein; R Klein; S E Moss
Journal:  Ophthalmic Epidemiol       Date:  2000-12       Impact factor: 1.648

6.  Transduction of mechanical and cytoskeletal cues by YAP and TAZ.

Authors:  Georg Halder; Sirio Dupont; Stefano Piccolo
Journal:  Nat Rev Mol Cell Biol       Date:  2012-08-16       Impact factor: 94.444

7.  Lens regeneration using endogenous stem cells with gain of visual function.

Authors:  Haotian Lin; Hong Ouyang; Jie Zhu; Shan Huang; Zhenzhen Liu; Shuyi Chen; Guiqun Cao; Gen Li; Robert A J Signer; Yanxin Xu; Christopher Chung; Ying Zhang; Danni Lin; Sherrina Patel; Frances Wu; Huimin Cai; Jiayi Hou; Cindy Wen; Maryam Jafari; Xialin Liu; Lixia Luo; Jin Zhu; Austin Qiu; Rui Hou; Baoxin Chen; Jiangna Chen; David Granet; Christopher Heichel; Fu Shang; Xuri Li; Michal Krawczyk; Dorota Skowronska-Krawczyk; Yujuan Wang; William Shi; Daniel Chen; Zheng Zhong; Sheng Zhong; Liangfang Zhang; Shaochen Chen; Sean J Morrison; Richard L Maas; Kang Zhang; Yizhi Liu
Journal:  Nature       Date:  2016-03-09       Impact factor: 49.962

8.  Wnt signaling is required for organization of the lens fiber cell cytoskeleton and development of lens three-dimensional architecture.

Authors:  Yongjuan Chen; Richard J W Stump; Frank J Lovicu; Akihiko Shimono; John W McAvoy
Journal:  Dev Biol       Date:  2008-09-18       Impact factor: 3.582

9.  Localization of acidic fibroblast growth factor, basic fibroblast growth factor, and heparan sulphate proteoglycan in rat lens: implications for lens polarity and growth patterns.

Authors:  F J Lovicu; J W McAvoy
Journal:  Invest Ophthalmol Vis Sci       Date:  1993-11       Impact factor: 4.799

10.  Hypoxic conditions differentially regulate TAZ and YAP in cancer cells.

Authors:  Libo Yan; Qingchun Cai; Yan Xu
Journal:  Arch Biochem Biophys       Date:  2014-07-29       Impact factor: 4.013
View more
  10 in total

1.  Lens differentiation is characterized by stage-specific changes in chromatin accessibility correlating with differentiation state-specific gene expression.

Authors:  Joshua Disatham; Daniel Chauss; Rifah Gheyas; Lisa Brennan; David Blanco; Lauren Daley; A Sue Menko; Marc Kantorow
Journal:  Dev Biol       Date:  2019-05-25       Impact factor: 3.582

2.  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

3.  Lens development requires DNMT1 but takes place normally in the absence of both DNMT3A and DNMT3B activity.

Authors:  Thanh V Hoang; Evan R Horowitz; Blake R Chaffee; Peipei Qi; Rachel E Flake; Devin G Bruney; Blake J Rasor; Savana E Rosalez; Brad D Wagner; Michael L Robinson
Journal:  Epigenetics       Date:  2016-11-08       Impact factor: 4.528

4.  β1-integrin controls cell fate specification in early lens development.

Authors:  Mallika Pathania; Yan Wang; Vladimir N Simirskii; Melinda K Duncan
Journal:  Differentiation       Date:  2016-09-03       Impact factor: 3.880

Review 5.  The lens growth process.

Authors:  Steven Bassnett; Hrvoje Šikić
Journal:  Prog Retin Eye Res       Date:  2017-04-11       Impact factor: 21.198

6.  A comprehensive spatial-temporal transcriptomic analysis of differentiating nascent mouse lens epithelial and fiber cells.

Authors:  Yilin Zhao; Deyou Zheng; Ales Cvekl
Journal:  Exp Eye Res       Date:  2018-06-05       Impact factor: 3.770

7.  Ocular phenotypic consequences of a single copy deletion of the Yap1 gene (Yap1 +/-) in mice.

Authors:  Soohyun Kim; Sara M Thomasy; Vijay Krishna Raghunathan; Leandro B C Teixeira; Ala Moshiri; Paul FitzGerald; Christopher J Murphy
Journal:  Mol Vis       Date:  2019-02-17       Impact factor: 2.367

8.  Changes in DNA methylation hallmark alterations in chromatin accessibility and gene expression for eye lens differentiation.

Authors:  J Fielding Hejtmancik; Marc Kantorow; Joshua Disatham; Lisa Brennan; Xiaodong Jiao; Zhiwei Ma
Journal:  Epigenetics Chromatin       Date:  2022-03-05       Impact factor: 4.954

9.  Identification of a New Mutation p.P88L in Connexin 50 Associated with Dominant Congenital Cataract.

Authors:  Aixia Jin; Qingqing Zhao; Shuting Liu; Zi-Bing Jin; Shuyan Li; Mengqing Xiang; Mingbing Zeng; Kangxin Jin
Journal:  Front Cell Dev Biol       Date:  2022-04-21

10.  Lens Stretching Modulates Lens Epithelial Cell Proliferation via YAP Regulation.

Authors:  Bharat Kumar; Heather L Chandler; Timothy Plageman; Matthew A Reilly
Journal:  Invest Ophthalmol Vis Sci       Date:  2019-09-03       Impact factor: 4.799
  10 in total

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