Capulet and Slingshot share overlapping functions during Drosophila eye morphogenesis

Lin, Chiao-Ming; Lin, Pei-Yi; Li, Yu-Chiao; Hsu, Jui-Chou

doi:10.1186/1423-0127-19-46

Cited by 7 publications

(6 citation statements)

References 31 publications

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“…Besides decreased expression, it is also notable that E‐cadherin displayed a discontinuous pattern in BPH, indicating alterations in prostatic epithelial cell‐cell contacts and perhaps deficits in its membrane protein trafficking. Discontinuous and weaker E‐cadherin staining patterns have been reported by others in epithelial choroid plexus cell lines used to study the blood‐cerebrospinal fluid barrier; and discontinuous adherens junctions have been associated with cell border retraction in endothelial cells . Our in vitro studies revealed that E‐cadherin knockdown increased monolayer permeability and disrupted tight‐junction formation without affecting cell density.…”

Section: Discussionsupporting

confidence: 78%

“…Discontinuous and weaker E-cadherin staining patterns have been reported by others in epithelial choroid plexus cell lines used to study the blood-cerebrospinal fluid barrier 35 ; and discontinuous adherens junctions have been associated with cell border retraction in endothelial cells. [36][37][38] Our in vitro studies revealed that E-cadherin knockdown and differentiation of the prostatic bud epithelium. 42 In murine urogenital sinus, blocking of E-cadherin function increases the number of prostatic buds undergoing morphogenesis and accelerates prostate lumen formation.…”

Section: Discussionmentioning

confidence: 79%

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E‐cadherin is downregulated in benign prostatic hyperplasia and required for tight junction formation and permeability barrier in the prostatic epithelial cell monolayer

Pascal

Stolz

et al. 2019

The Prostate

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Background We previously reported the presence of prostate‐specific antigen (PSA) in the stromal compartment of benign prostatic hyperplasia (BPH). Since PSA is expressed exclusively by prostatic luminal epithelial cells, PSA in the BPH stroma suggests increased tissue permeability and the compromise of epithelial barrier integrity. E‐cadherin, an important adherens junction component and tight junction regulator, is known to exhibit downregulation in BPH. These observations suggest that the prostate epithelial barrier is disrupted in BPH and E‐cadherin downregulation may increase epithelial barrier permeability. Methods The ultra‐structure of cellular junctions in BPH specimens was observed using transmission electron microscopy (TEM) and E‐cadherin immunostaining analysis was performed on BPH and normal adjacent specimens from BPH patients. In vitro cell line studies using benign prostatic epithelial cell lines were performed to determine the impact of small interfering RNA knockdown of E‐cadherin on transepithelial electrical resistance and diffusion of fluorescein isothiocyanate (FITC)‐dextran in transwell assays. Results The number of kiss points in tight junctions was reduced in BPH epithelial cells as compared with the normal adjacent prostate. Immunostaining confirmed E‐cadherin downregulation and revealed a discontinuous E‐cadherin staining pattern in BPH specimens. E‐cadherin knockdown increased monolayer permeability and disrupted tight junction formation without affecting cell density. Conclusions Our results indicate that tight junctions are compromised in BPH and loss of E‐cadherin is potentially an important underlying mechanism, suggesting targeting E‐cadherin loss could be a potential approach to prevent or treat BPH.

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Section: Discussionsupporting

confidence: 78%

Section: Discussionmentioning

confidence: 79%

E‐cadherin is downregulated in benign prostatic hyperplasia and required for tight junction formation and permeability barrier in the prostatic epithelial cell monolayer

Pascal

Stolz

et al. 2019

The Prostate

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“…It has been shown that rat CAP1 is enriched in the neuronal growth cones (Lu et al, 2011;Nozumi et al, 2009), suggesting that CAP is a conserved regulator of neuronal growth. Mutations in Drosophila CAP also disturb oocyte polarity (Baum et al, 2000), epithelial cell polarity (Baum and Perrimon, 2001), Hedgehog signaling (Benlali et al, 2000), Hippo signaling (Fernández et al, 2011) and eye development (Benlali et al, 2000;Lin et al, 2012). However, it is not clear whether these phenotypic changes are owing to the direct role of CAP in certain signaling pathways or because of secondary effects of disorganized actin filaments.…”

Section: Function Of Cap As a Regulator Of The Actin Cytoskeleton In mentioning

confidence: 97%

The role of cyclase-associated protein in regulating actin filament dynamics – more than a monomer-sequestration factor

Ono

2013

Journal of Cell Science

108

150

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SummaryDynamic reorganization of the actin cytoskeleton is fundamental to a number of cell biological events. A variety of actin-regulatory proteins modulate polymerization and depolymerization of actin and contribute to actin cytoskeletal reorganization. Cyclase-associated protein (CAP) is a conserved actin-monomer-binding protein that has been studied for over 20 years. Early studies have shown that CAP sequesters actin monomers; recent studies, however, have revealed more active roles of CAP in actin filament dynamics. CAP enhances the recharging of actin monomers with ATP antagonistically to ADF/cofilin, and also promotes the severing of actin filaments in cooperation with ADF/cofilin. Self-oligomerization and binding to other proteins regulate activities and localization of CAP. CAP has crucial roles in cell signaling, development, vesicle trafficking, cell migration and muscle sarcomere assembly. This Commentary discusses the recent advances in our understanding of the functions of CAP and its implications as an important regulator of actin cytoskeletal dynamics, which are involved in various cellular activities.

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“…Ssh is a cofilin phosphatase of the Slingshot family, with an important role in eye morphogenesis during the assembly of ommatidia (the basic units of the compound insect eye), where it works to inhibit actin polymerization by activating cofilin [168]. In addition to its catalytic domain, Ssh , like its human orthologs (SSH1, SSH2 and SSH3), also contains a DEK domain N‐terminal to the phosphatase catalytic domain, and C‐terminal serine‐ and glutamine‐rich regions.…”

Section: The Drosophila Tyrosine Phosphatome Is a Streamlined Versionmentioning

confidence: 99%

A Drosophila‐centric view of protein tyrosine phosphatases

et al. 2015

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a b s t r a c tMost of our knowledge on protein tyrosine phosphatases (PTPs) is derived from human pathologies and mouse knockout models. These models largely correlate well with human disease phenotypes, but can be ambiguous due to compensatory mechanisms introduced by paralogous genes. Here we present the analysis of the PTP complement of the fruit fly and the complementary view that PTP studies in Drosophila will accelerate our understanding of PTPs in physiological and pathological conditions. With only 44 PTP genes, Drosophila represents a streamlined version of the human complement. Our integrated analysis places the Drosophila PTPs into evolutionary and functional contexts, thereby providing a platform for the exploitation of the fly for PTP research and the transfer of knowledge onto other model systems.

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Capulet and Slingshot share overlapping functions during Drosophila eye morphogenesis

Cited by 7 publications

References 31 publications

E‐cadherin is downregulated in benign prostatic hyperplasia and required for tight junction formation and permeability barrier in the prostatic epithelial cell monolayer

E‐cadherin is downregulated in benign prostatic hyperplasia and required for tight junction formation and permeability barrier in the prostatic epithelial cell monolayer

The role of cyclase-associated protein in regulating actin filament dynamics – more than a monomer-sequestration factor

A Drosophila‐centric view of protein tyrosine phosphatases

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