Early lens development in the zebrafish: A three‐dimensional time‐lapse analysis

Greiling, Teri M.; Clark, John I.

doi:10.1002/dvdy.21997

Cited by 80 publications

(79 citation statements)

References 21 publications

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“…16 In zebrafish, mutations that produce ocular disorders, including cataracts, are found in a similar spectrum of candidate genes as we have seen in humans, suggesting that eye development processes in the two systems are fundamentally similar at the cellular level despite differences in timing and morphology during development. 4,17,41,42 In conclusion, we have characterized a human UNC45B mutation in a Danish family with autosomal dominant cataract developing in early childhood. Experimental data using a zebrafish unc45b mutant show an eye developmental phenotype.…”

Section: Discussionmentioning

confidence: 88%

“…Differentiation of lens fiber cells begins in the zebrafish at B24 h post fertilization (hpf) and involves processes including cellular reorganization and organelle degeneration that result in a transparent lens and functional visual system by 72 hpf. 17,18 Disassembly of actin stress fibers is believed to induce lens cell differentiation and lead to the formation of cortical fibers through the reorganization of actin filaments. 18,19 Zebrafish embryonic eyes were examined for lens fiber cell boundaries, differentiation, and nuclear retention.…”

Section: Zebrafish Studiesmentioning

confidence: 99%

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The myosin chaperone UNC45B is involved in lens development and autosomal dominant juvenile cataract

et al. 2014

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Genome-wide linkage analysis, followed by targeted deep sequencing, in a Danish multigeneration family with juvenile cataract revealed a region of chromosome 17 co-segregating with the disease trait. Affected individuals were heterozygous for two potentially protein-disrupting alleles in this region, in ACACA and UNC45B. As alterations of the UNC45B protein have been shown to affect eye development in model organisms, effort was focused on the heterozygous UNC45B missense mutation. UNC45B encodes a myosin-specific chaperone that, together with the general heat shock protein HSP90, is involved in myosin assembly. The mutation changes p.Arg805 to Trp in the UCS domain, an amino acid that is highly conserved from yeast to human. UNC45B is strongly expressed in the heart and skeletal muscle tissue, but here we show expression in human embryo eye and zebrafish lens. The zebrafish mutant steif, carrying an unc45b nonsense mutation, has smaller eyes than wild-type embryos and shows accumulation of nuclei in the lens. Injection of RNA encoding the human wild-type UNC45B protein into the steif homozygous embryo reduced the nuclei accumulation and injection of human mutant UNC45B cDNA in wild-type embryos resulted in development of a phenotype similar to the steif mutant. The p.Arg805Trp alteration in the mammalian UNC45B gene suggests that developmental cataract may be caused by a defect in non-muscle myosin assembly during maturation of the lens fiber cells. Keywords: congenital cataract; UNC45B; non-muscle myosin; epithelial lens cell; zebrafish steif mutant INTRODUCTION Congenital/infantile cataract (CC) is a developmental anomaly characterized by opacities in the crystal lens of the eye and is a common cause of restricted vision and blindness in children. Environmental and intrinsic factors are involved, including metabolic and genetic causes for CC. Mendelian forms of CC comprise a broad spectrum of syndromic and nonsyndromic phenotypes characterized by a set of associated ocular and/or systemic abnormalities. More than 35 loci, including at least 25 known genes, have been associated with nonsyndromic cataract, the majority showing autosomal dominant inheritance with high penetrance (ADCC). 1,2 Mutations in crystallins, particularly CRYAA, CRYBB2, and CRYGD and the connexin genes GJA3 and GJA8 comprise the largest group of loci causing ADCC, but mutations are also found in the membrane proteins MIP, LIM2, TMEM114 and CHMP4B, in cytoskeleton proteins (BSFP1 and BSFP2) and in transcription factors (HSF4 and MAF). 1,2 In a recent study, 3 we reported that these loci represented most of the causative mutations in 19 out of 28 unrelated Danish CC families. Among the unsolved families was one in which genome-wide linkage analysis revealed two candidate loci at 2q32.3-q33.3 and 17q11.2-q21.2, respectively. 3 The family comprised three generations with nine

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Section: Discussionmentioning

confidence: 88%

Section: Zebrafish Studiesmentioning

confidence: 99%

The myosin chaperone UNC45B is involved in lens development and autosomal dominant juvenile cataract

et al. 2014

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“…Subsequently, the lens pit deepens and the connection with the overlying surface ectoderm, the prospective cornea, is abolished resulting in the formation of the lens vesicle (figure 1d ). In lower vertebrates, such as fish and frog, lens formation proceeds via delamination of the lens placodal cells [4,5]. After formation of the lens vesicle, cells at the centre of the posterior side of the lens will elongate and differentiate into primary lens fibre cells, whereas cells of the lens epithelium at the anterior side of the lens retain their ability to proliferate and will generate fibre cells throughout life (figure 1e) [3].…”

Section: Introductionmentioning

confidence: 99%

The lens: a classical model of embryonic induction providing new insights into cell determination in early development

Gunhaga

2011

Phil. Trans. R. Soc. B

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The lens was the first tissue in which the concept of embryonic induction was demonstrated. For many years lens induction was thought to occur at the time the optic vesicle and lens placode came in contact. Since then, studies have revealed that lens placodal progenitor cells are specified already at gastrula stages, much earlier than previously believed, and independent of optic vesicle interactions. In this review, I will focus on how individual signalling molecules, in particular BMP, FGF, Wnt and Shh, regulate the initial specification of lens placodal cells and the progressive development of lens cells. I will discuss recent work that has shed light on the combination of signalling molecules and the molecular interactions that affect lens specification and proper lens formation. I will also discuss proposed tissue interactions important for lens development. A greater knowledge of the molecular interactions during lens induction is likely to have practical benefits in understanding the causes and consequences of lens diseases. Moreover, knowledge regarding lens induction is providing fundamental important insights into inductive processes in development in general.

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“…In the lens vesicle, posterior epithelial cells differentiate into lens fiber cells, whereas anterior epithelial cells are retained as proliferative lens progenitor cells (Bassnett et al, 1999;Lovicu and McAvoy, 2005). In zebrafish, a lens mass without a vesicle delaminates, and the cells reorganize into the central core and epithelial cells (Greiling and Clark, 2009). At the interface between the anterior lens epithelium and posterior lens fiber core, called the equator, epithelial cells differentiate into lens fiber cells, which elongate towards both anterior and posterior poles of the lens sphere and cover the old lens fiber core.…”

Section: Introductionmentioning

confidence: 99%

The ubiquitin proteasome system is required for cell proliferation of the lens epithelium and for differentiation of lens fiber cells in zebrafish

et al. 2010

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SUMMARYIn the developing vertebrate lens, epithelial cells differentiate into fiber cells, which are elongated and flat in shape and form a multilayered lens fiber core. In this study, we identified the zebrafish volvox (vov) mutant, which shows defects in lens fiber differentiation. In the vov mutant, lens epithelial cells fail to proliferate properly. Furthermore, differentiating lens fiber cells do not fully elongate, and the shape and position of lens fiber nuclei are affected. We found that the vov mutant gene encodes Psmd6, the subunit of the 26S proteasome. The proteasome regulates diverse cellular functions by degrading polyubiquitylated proteins. Polyubiquitylated proteins accumulate in the vov mutant. Furthermore, polyubiquitylation is active in nuclei of differentiating lens fiber cells, suggesting roles of the proteasome in lens fiber differentiation. We found that an E3 ubiquitin ligase anaphase-promoting complex/cyclosome (APC/C) is involved in lens defects in the vov mutant. These data suggest that the ubiquitin proteasome system is required for cell proliferation of lens epithelium and for the differentiation of lens fiber cells in zebrafish.

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Early lens development in the zebrafish: A three‐dimensional time‐lapse analysis

Cited by 80 publications

References 21 publications

The myosin chaperone UNC45B is involved in lens development and autosomal dominant juvenile cataract

The myosin chaperone UNC45B is involved in lens development and autosomal dominant juvenile cataract

The lens: a classical model of embryonic induction providing new insights into cell determination in early development

The ubiquitin proteasome system is required for cell proliferation of the lens epithelium and for differentiation of lens fiber cells in zebrafish

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