Abstract
ABSTRACTNotch signaling regulates a multitude of cellular processes. During ocular lens development this pathway is required for lens progenitor growth, differentiation and maintenance of the transition zone. After ligand-receptor binding, the receptor proteins are processed, first by ADAM proteases, then by γ-secretase cleavage. This results in the release of a Notch intracellular domain (N-ICD), which is recruited into a nuclear transcription factor complex that activates Notch target genes. Previous in vitro studies showed that the Delta-like and Jagged ligand proteins can also be cleaved by the γ-secretase complex, but it remains unknown whether such processing occurs during in vivo vertebrate development. Here we show that mouse and human lens progenitor cells endogenously express multiple Jagged1 protein isoforms, including a Jagged1 intracellular domain. We also found that pharmacologic blockage of γ-secretase activity in vitro resulted in an accumulation of Jagged1 polypeptide intermediates. Finally, overexpression of an epitope-tagged Jagged1 intracellular domain displayed nuclear localization and induced the upregulation of endogenous JAG1 mRNA expression. These findings support the idea that along with its classical role as a Notch pathway ligand, Jagged1 is regulated post-translationally, to produce multiple active protein isoforms.
Highlights
The Notch signaling pathway is highly conserved among metazoans and functions in a variety of cellular activities, including cell fate determination
Multiple Jag1 protein isoforms are present during mouse embryogenesis Previous in vitro work demonstrated that epitope-tagged rat Deltalike (Dll) and Jagged1 (Jag1) proteins are cleaved by the γ-secretase complex (LaVoie and Selkoe, 2003)
Given that the removal of Jag1 activity during mouse lens development results in postnatal lens aphakia (Le et al, 2009), we hypothesized that post-translational processing of this ligand may be one mechanism for regulating its activity during embryogenesis
Summary
The Notch signaling pathway is highly conserved among metazoans and functions in a variety of cellular activities, including cell fate determination. One developing tissue that relies on Notch signaling is the ocular lens. The vertebrate lens consists of anterior epithelial progenitor cells that terminally differentiate into organelle-free fiber cells. This is an attractive tissue for studying complex cell–cell signaling pathways, given its simple architecture and dispensability. Lens placode formation relies on signals from the underlying optic vesicle, a neuroepithelium extension of the ventral forebrain that gives rise to both the neural retina and retinal pigment epithelium (Fuhrmann, 2010). At E10.5, the lens placode invaginates into a lens pit, which subsequently detaches from the surface ectoderm as a hollow lens vesicle, Department of Cell Biology & Human Anatomy, University of California, 1 Shields Avenue, Davis, CA 95616, USA
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