The effect of elevated intraocular oxygen on organelle degradation in the embryonic chicken lens

Bassnett, Steven; McNulty, Richard

doi:10.1242/jeb.00670

Cited by 33 publications

(27 citation statements)

References 25 publications

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“…These studies demonstrated that TNF-related molecules and their signalling components are expressed in the developing lens and therefore support the suggestion that TNFrelated signalling is potentially involved in regulating organelle loss in lens fibre cells and/or lens fibre cell differentiation. The results therefore suggest that organelle loss could be a process activated by TNFamediated cell signalling cascades, although the involvement of a passive process (such as a reduction in oxygen tension at a specific point within the lens fibre cell mass) cannot be ruled out [62].…”

Section: Overview Of Factors Involved In Lens Fibre Cell Differentiatmentioning

confidence: 82%

Lens fibre cell differentiation and organelle loss: many paths lead to clarity

Wride

2011

Phil. Trans. R. Soc. B

180

152

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The programmed removal of organelles from differentiating lens fibre cells contributes towards lens transparency through formation of an organelle-free zone (OFZ). Disruptions in OFZ formation are accompanied by the persistence of organelles in lens fibre cells and can contribute towards cataract. A great deal of work has gone into elucidating the nature of the mechanisms and signalling pathways involved. It is apparent that multiple, parallel and redundant pathways are involved in this process and that these pathways form interacting networks. Furthermore, it is possible that the pathways can functionally compensate for each other, for example in mouse knockout studies. This makes sense given the importance of lens clarity in an evolutionary context. Apoptosis signalling and proteolytic pathways have been implicated in both lens fibre cell differentiation and organelle loss, including the Bcl-2 and inhibitor of apoptosis families, tumour necrosis factors, p53 and its regulators (such as Mdm2) and proteolytic enzymes, including caspases, cathepsins, calpains and the ubiquitinproteasome pathway. Ongoing approaches being used to dissect the molecular pathways involved, such as transgenics, lens-specific gene deletion and zebrafish mutants, are discussed here. Finally, some of the remaining unresolved issues and potential areas for future studies are highlighted.

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Section: Overview Of Factors Involved In Lens Fibre Cell Differentiatmentioning

confidence: 82%

Lens fibre cell differentiation and organelle loss: many paths lead to clarity

Wride

2011

Phil. Trans. R. Soc. B

180

152

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“…These regions are diagrammed in Figure 1. The elimination of organelles from the FC region of the chicken lens begins at E12 and a transparent organelle-free zone (OFZ) is apparent by E15 (Bassnett and McNulty 2003; Costello et al 2013; Basu et al 2014b). The E13 stage of embryonic chicken lens development (E13) was chosen because this represents an early stage of OFZ formation when molecules required for removal of organelles would be expected to be up-regulated in the fiber cell zones.…”

Section: Resultsmentioning

confidence: 99%

Differentiation State-Specific Mitochondrial Dynamic Regulatory Networks Are Revealed by Global Transcriptional Analysis of the Developing Chicken Lens

Chauss

Basu

Rajakaruna

et al. 2014

G3 Genes|Genomes|Genetics

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The mature eye lens contains a surface layer of epithelial cells called the lens epithelium that requires a functional mitochondrial population to maintain the homeostasis and transparency of the entire lens. The lens epithelium overlies a core of terminally differentiated fiber cells that must degrade their mitochondria to achieve lens transparency. These distinct mitochondrial populations make the lens a useful model system to identify those genes that regulate the balance between mitochondrial homeostasis and elimination. Here we used an RNA sequencing and bioinformatics approach to identify the transcript levels of all genes expressed by distinct regions of the lens epithelium and maturing fiber cells of the embryonic Gallus gallus (chicken) lens. Our analysis detected more than 15,000 unique transcripts expressed by the embryonic chicken lens. Of these, more than 3000 transcripts exhibited significant differences in expression between lens epithelial cells and fiber cells. Multiple transcripts coding for separate mitochondrial homeostatic and degradation mechanisms were identified to exhibit preferred patterns of expression in lens epithelial cells that require mitochondria relative to lens fiber cells that require mitochondrial elimination. These included differences in the expression levels of metabolic (DUT, PDK1, SNPH), autophagy (ATG3, ATG4B, BECN1, FYCO1, WIPI1), and mitophagy (BNIP3L/NIX, BNIP3, PARK2, p62/SQSTM1) transcripts between lens epithelial cells and lens fiber cells. These data provide a comprehensive window into all genes transcribed by the lens and those mitochondrial regulatory and degradation pathways that function to maintain mitochondrial populations in the lens epithelium and to eliminate mitochondria in maturing lens fiber cells.

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“…Conversely, an increase in D signifies that organelle degradation is delayed (32). Organelle degradation commences in the mouse lens during the late stages of embryonic development, and by P2 (the age examined here) the OFZ is a well defined region in the center of the tissue.…”

Section: Figmentioning

confidence: 87%

Role of the Executioner Caspases during Lens Development

Zandy

Lakhani

Zheng

et al. 2005

Journal of Biological Chemistry

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The notion that the cell death machinery is utilized during lens organelle degradation is supported by the observation that well characterized apoptotic substrates are cleaved during this process. Here, we test directly the role of executioner caspases (caspase-3, -6, and -7) in fiber cell differentiation. The distribution of mRNA, protein, and enzymatic activity for each caspase was determined in the mouse lens. Transcripts for all three executioner caspases were identified in lens fiber cells by real time RT-PCR, although only caspase-6 and -7 proteins were detected subsequently by Western blot analysis. Endogenous proteolytic activity was noted for caspase-3 but not caspase-6 or -7. We tested the role of executioner caspases in organelle degradation by examining lenses from mice deficient in each caspase. Knock-out lenses appeared grossly normal with the exception of caspase-3 ؊/؊ lenses, which exhibited marked cataracts at the anterior lens pole. The distribution of lens organelles was mapped by confocal microscopy. There was no significant difference in the size of the lens organelle-free zone (OFZ) 1 between wild-type and knock-out lenses. In response to treatment with staurosporine, caspase-3 and -6 (but not caspase-7) enzymatic activities were induced. We generated double knock-out animals to examine the phenotype of lenses deficient in both caspase-3 and -6. Histological examination of such lenses indicated the presence of a properly formed OFZ. Thus, no single executioner caspase (nor a combination of caspase-3 and -6) is required for organelle loss, although caspase-3 activity may be required for other aspects of lens transparency.Apoptosis, or programmed cell death, is an active process accompanied by characteristic morphological and biochemical changes. It can be triggered by stimuli either intrinsic or extrinsic to the cell. An internal stress, such as hypoxia, can activate the intrinsic pathway through the disruption of mitochondria. Extrinsic activation may occur following ligand binding to so-called death receptors. The intrinsic and extrinsic pathways are believed to converge on a conserved family of cysteine proteases called caspases. Following receipt of an appropriate apoptotic signal, caspases are cleaved from inactive precursors to active mature forms. The initiator caspases (caspase-2, -8, and -9) are responsible for the activation of the effector caspases (caspase-3, -6, and -7). These effector (or executioner) caspases play critical roles in the cleavage of key structural and regulatory proteins, such as poly(ADP-ribose) polymerase, nuclear lamins, DNA fragmentation factor, and spectrin (reviewed in Refs.

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The effect of elevated intraocular oxygen on organelle degradation in the embryonic chicken lens

Cited by 33 publications

References 25 publications

Lens fibre cell differentiation and organelle loss: many paths lead to clarity

Lens fibre cell differentiation and organelle loss: many paths lead to clarity

Differentiation State-Specific Mitochondrial Dynamic Regulatory Networks Are Revealed by Global Transcriptional Analysis of the Developing Chicken Lens

Role of the Executioner Caspases during Lens Development

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