Impaired formation of desmosomal junctions in ADPKD epithelia

Russo, Ryan J.; Husson, Hervé; Joly, Dominique; Bukanov, Nikolay O.; Patey, Natacha; Ibraghimov‐Beskrovnaya, Oxana

doi:10.1007/s00418-005-0055-3

Cited by 33 publications

(33 citation statements)

References 38 publications

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“…[14][15][16] Importantly, disruption of desmosomal and adherens cell-cell junctions were detected in cystic ADPKD epithelia, suggesting that mutations in polycystin-1 lead to perturbation of intercellular adhesion complexes and cystogenesis. 17,18 In addition, polycystin-1 was found in focal adhesion complexes suggesting its role in cell-matrix adhesion. 19,20 These data clearly suggest that mutation in polycystin-1 results in the disruption of cell-cell/matrix adhesion, which, in turn leads to increased proliferation, de-differentiation and cystic transformation.…”

Section: Polycystins Function In Multiple Subcellular Domainsmentioning

confidence: 99%

Targeting Dysregulated Cell Cycle and Apoptosis for Polycystic Kidney Disease Therapy

Ibraghimov‐Beskrovnaya¹

2007

Cell Cycle

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Previously published online as a Cell Cycle E-publication: http://www.landesbioscience.com/journals/cc/abstract.php?id=4047 Key wOrdspolycystic kidney disease, cyclin dependent kinase inhibitor, cilia, cell cycle, apoptosis AcKnOwledgementsI would like to thank Herve Husson, Laurie Smith, Ryan Russo and Nick Bukanov for their contribution to this work. ABstrActPolycystic kidneys diseases (PKDs) represent a group of disorders characterized by the growth of fluid filled cysts in kidneys and other organs. No effective treatment is currently available for PKDs. A link between dysfunctional cilia and cell cycle regulation has been recently discovered as the most proximal trigger of cystogenesis. We examined the benefit of therapeutic correction of the cell cycle dysregulation in PKD with the cyclin dependent kinase (CDK) inhibitor roscovitine. Our data show that CDK inhibition results in the robust, long lasting arrest of cystogenesis in both slowly progressive and aggressive mouse models of PKD. Dissection of the molecular mechanism of CDK inhibitor action shows effective cell cycle arrest, transcriptional inhibition and attenuation of apoptosis. Roscovitine treatment has proven highly effective in preserving the renal function in treated animals. We also detected significant downregulation of cAMP and aquaporin 2 in treated kidneys, suggesting the effect of CDK inhibition on preservation of epithelial differentiation. CDK inhibition was shown to be efficacious in multiple other types of renal diseases with abnormal cell cycle and proliferation. Thus, therapies directly targeting coordinate regulation of proliferation and apoptosis are emerging as effective approaches to treat multiple renal diseases.

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Section: Polycystins Function In Multiple Subcellular Domainsmentioning

confidence: 99%

Targeting Dysregulated Cell Cycle and Apoptosis for Polycystic Kidney Disease Therapy

Ibraghimov‐Beskrovnaya¹

2007

Cell Cycle

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“…In MDCK cells, we found that PC1 was 1411 PC1 and junction assembly coimmunoprecipitate with E-cadherin and the catenins in human pancreatic adenocarcinoma cells (Huan and van Adelsberg, 1999). In human cystic cells, the absence of surface PC1 is associated with concomitant loss of surface E-cadherin expression and its replacement by N-cadherin (Streets et al, 2003;Roitbak et al, 2004;Russo et al, 2005). A putative role for PC1 in desmosome function has also been postulated because of its immunolocalisation to desmosomal junctions, the mislocalisation of desmosome junction proteins in cystic cells and the reported interaction of the PC1 C-terminus with intermediate filaments (Scheffers et al, 2000;Xu et al, 2001;Russo et al, 2005;Silberberg et al, 2005).…”

Section: Introductionmentioning

confidence: 91%

Homophilic and heterophilic polycystin 1 interactions regulate E-cadherin recruitment and junction assembly in MDCK cells

Streets

Wagner

Harris

et al. 2009

Journal of Cell Science

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Autosomal dominant polycystic kidney disease (ADPKD) is the most common inherited human renal disease and is caused by mutations in two genes, PKD1 (85%) and PKD2 (15%). Cyst epithelial cells are characterised by a complex cellular phenotype including changes in proliferation, apoptosis, basement membrane composition and apicobasal polarity. Since polycystin 1 (PC1), the PKD1 protein, has been located in the basolateral membrane of kidney epithelial cells, we hypothesised that it might have a key role in mediating or stabilising cell-cell interactions. In non-ciliated L929 cells, stable or transient surface expression of the PC1 extracellular domain was sufficient to confer an adhesive phenotype and stimulate junction formation. In MDCK cells, we found that PC1 was recruited to the lateral membranes coincident with E-cadherin within 30 minutes after a `calcium switch'. Recruitment of both proteins was significantly delayed when cells were treated with a PC1 blocking antibody raised to the PKD domains. Finally, PC1 and E-cadherin could be coimmunoprecipitated together from MDCK cells. We conclude that PC1 has a key role in initiating junction formation via initial homophilic interactions and facilitates junction assembly and the establishment of apicobasal polarity by E-cadherin recruitment.

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“…In ADPKD cysts, these desmosomal elements are severely disoriented [42] . Finally, cytoskeletal proteins such as actinbinding proteins, cardiac troponin and tropomysin have been directly associated with PC2 channel activity upon stimulation by osmotic or hydrostatic pressure [43,44] .…”

Section: Referencesmentioning

confidence: 99%

Polycystins and mechanotransduction: From physiology to disease

Piperi

Basdra

2015

WJEM

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Polycystins are key mechanosensor proteins able to respond to mechanical forces of external or internal origin. They are widely expressed in primary cilium and plasma membrane of several cell types including kidney, vascular endothelial and smooth muscle cells, osteoblasts and cardiac myocytes modulating their physiology. Interaction of polycystins with diverse ion channels, cell-cell and cell-extracellular matrix junctional proteins implicates them in the regulation of cell structure, mechanical force transmission and mechanotransduction. Their intracellular localization in endoplasmic reticulum further regulates subcellular trafficking and calcium homeostasis, finely-tuning overall cellular mechanosensitivity. Aberrant expression or genetic alterations of polycystins lead to severe structural and mechanosensing abnormalities including cyst formation, deregulated flow sensing, aneurysms, defective bone development and cancer progression, highlighting their vital role in human physiology.

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Impaired formation of desmosomal junctions in ADPKD epithelia

Cited by 33 publications

References 38 publications

Targeting Dysregulated Cell Cycle and Apoptosis for Polycystic Kidney Disease Therapy

Targeting Dysregulated Cell Cycle and Apoptosis for Polycystic Kidney Disease Therapy

Homophilic and heterophilic polycystin 1 interactions regulate E-cadherin recruitment and junction assembly in MDCK cells

Polycystins and mechanotransduction: From physiology to disease

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