Mechanical strain of alveolar type II cells in culture: changes in the transcellular cytokeratin network and adaptations

Felder, Edward; Siebenbrunner, Marcus; Busch, Tobias; Fois, Giorgio; Miklavc, Pika; Walther, Paul; Dietl, Paul

doi:10.1152/ajplung.00503.2007

Cited by 32 publications

(33 citation statements)

References 40 publications

(36 reference statements)

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“…Indeed, Gajic et al found signs of reversible cell membrane stress failure in rats ventilated with high tidal volumes using propidium iodide as a cell-impermeable marker of cell damage [72]. In addition, we found ultrastructural evidence for membrane damage in type II pneumocytes stretched on silastic membranes [71]. In summary, in pathophysiological conditions, ATP leakage from wounded cells could influence type II cells and surfactant secretion in an autocrine/paracrine way.…”

Section: Possible Causes Of Atp Release In the Alveolussupporting

confidence: 60%

“…However, although various anion channels have been identified in fetal and adult pneumocytes [70], their involvement in alveolar ATP release has not yet been demonstrated. It is unlikely that membrane stress alone is the reason for ATP release from cells under physiological conditions, because moderate amounts of stretch are in general tolerated without signs of membrane damage [35,36,71,72]. However, ATP may exit all cells under conditions of cell damage, and this could be the case in hyperinflation-induced lung injury.…”

Section: Possible Causes Of Atp Release In the Alveolusmentioning

confidence: 99%

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Lamellar Body Exocytosis by Cell Stretch or Purinergic Stimulation: Possible Physiological Roles, Messengers and Mechanisms

Dietl

Liss

Felder

et al. 2010

Cell Physiol Biochem

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A major function of the pulmonary alveolar type II cell is the secretion of surfactant, a lipoprotein-like substance, via exocytosis of secretory vesicles termed lamellar bodies (LBs). The process of surfactant secretion is remarkable in several aspects, considering stimulus-delayed fusion activity, poor solubility of vesicle contents, long hemifusion lifetimes, slow fusion pore expansion and active, actin-driven content release. Cell stretch as well as P2Y₂ receptor stimulation by extracellular ATP are considered the most potent stimuli for LB exocytosis. For both stimuli, elevation of the cytoplasmic Ca²⁺ concentration [Ca²⁺]_c is a key step. This review summarizes possible physiological roles and pathways of stretch- or ATP-induced surfactant secretion and discusses molecular mechanisms controlling the pre-, hemi- and postfusion phase, in comparison with neuroendocrine release mechanisms.

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Section: Possible Causes Of Atp Release In the Alveolussupporting

confidence: 60%

Section: Possible Causes Of Atp Release In the Alveolusmentioning

confidence: 99%

Lamellar Body Exocytosis by Cell Stretch or Purinergic Stimulation: Possible Physiological Roles, Messengers and Mechanisms

Dietl

Liss

Felder

et al. 2010

Cell Physiol Biochem

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“…In the liver, K8/K18 levels increase about threefold (mRNA and protein) in response to injury, as noted in mice treated with agents that induce Mallory–Denk body formation (Zatloukal et al , 2007) and in the hepatoma cell line HepG2 treated with doxorubicin (Wang et al , 2009; Hammer et al , 2010), and two- to fourfold (protein) in patients with primary biliary cirrhosis (Fickert et al , 2003). In alveolar epithelial cells, shear stress causes structural remodeling of the keratin IF network (Felder et al , 2008; Sivaramakrishnan et al , 2008), whereas hypoxia results in network disassembly and K8/K18 degradation (Na et al , 2010). Similarly, the keratin cytoskeleton disintegrates in mammary epithelial cells under metabolic (combined glucose and oxygen deprivation mimicking the tumor microenvironment; Nelson et al , 2004) stress (Kongara et al , 2010).…”

Section: Keratins In Healthmentioning

confidence: 99%

Keratins in health and cancer: more than mere epithelial cell markers

Karantza¹

2010

Oncogene

468

420

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Keratins are the intermediate filament (IF)-forming proteins of epithelial cells. Since their initial characterization almost 30 years ago, the total number of mammalian keratins has increased to 54, including 28 type I and 26 type II keratins. Keratins are obligate heteropolymers and, similarly to other IFs, they contain a dimeric central α-helical rod domain that is flanked by non-helical head and tail domains. The 10-nm keratin filaments participate in the formation of a proteinaceous structural framework within the cellular cytoplasm and, as such, serve an important role in epithelial cell protection from mechanical and non-mechanical stressors, a property extensively substantiated by the discovery of human keratin mutations predisposing to tissue-specific injury and by studies in keratin knockout and transgenic mice. More recently, keratins have also been recognized as regulators of other cellular properties and functions, including apico-basal polarization, motility, cell size, protein synthesis and membrane traffic and signaling. In cancer, keratins are extensively used as diagnostic tumor markers, as epithelial malignancies largely maintain the specific keratin patterns associated with their respective cells of origin, and, in many occasions, full-length or cleaved keratin expression (or lack there of) in tumors and/or peripheral blood carries prognostic significance for cancer patients. Quite intriguingly, several studies have provided evidence for active keratin involvement in cancer cell invasion and metastasis, as well as in treatment responsiveness, and have set the foundation for further exploration of the role of keratins as multifunctional regulators of epithelial tumorigenesis.

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“…Post-translational modifications are major regulators of keratin function Ku et al, 1999;Toivola et al, 2004;Magin et al, 2007). In particular, serine phosphorylation of keratins plays a major role in various cellular events including apoptosis and mechanical or nonmechanical stress (Liao et al, 1995b;Liao et al, 1997;Ridge et al, 2005;Jeon et al, 2006;Felder et al, 2008). Serine hyperphosphorylation of keratins, for example by treatment of cells with okadaic acid, leads to disruption of the filament network (Ku and Omary, 1994;Ku et al, 1999;Strnad et al, 2002).…”

Section: Journal Of Cell Science 125 (9) 2154mentioning

confidence: 99%

Keratin 8 phosphorylation regulates keratin reorganization and migration of epithelial tumor cells

Busch

Armacki

Eiseler

et al. 2012

Journal of Cell Science

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SummaryCell migration and invasion are largely dependent on the complex organization of the various cytoskeletal components. Whereas the role of actin filaments and microtubules in cell motility is well established, the role of intermediate filaments in this process is incompletely understood. Organization and structure of the keratin cytoskeleton, which consists of heteropolymers of at least one type 1 and one type 2 intermediate filament, are in part regulated by post-translational modifications. In particular, phosphorylation events influence the properties of the keratin network. Sphingosylphosphorylcholine (SPC) is a bioactive lipid with the exceptional ability to change the organization of the keratin cytoskeleton, leading to reorganization of keratin filaments, increased elasticity, and subsequently increased migration of epithelial tumor cells. Here we investigate the signaling pathways that mediate SPC-induced keratin reorganization and the role of keratin phosphorylation in this process. We establish that the MEK-ERK signaling cascade regulates both SPC-induced keratin phosphorylation and reorganization in human pancreatic and gastric cancer cells and identify Ser431 in keratin 8 as the crucial residue whose phosphorylation is required and sufficient to induce keratin reorganization and consequently enhanced migration of human epithelial tumor cells.

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Mechanical strain of alveolar type II cells in culture: changes in the transcellular cytokeratin network and adaptations

Cited by 32 publications

References 40 publications

Lamellar Body Exocytosis by Cell Stretch or Purinergic Stimulation: Possible Physiological Roles, Messengers and Mechanisms

Lamellar Body Exocytosis by Cell Stretch or Purinergic Stimulation: Possible Physiological Roles, Messengers and Mechanisms

Keratins in health and cancer: more than mere epithelial cell markers

Keratin 8 phosphorylation regulates keratin reorganization and migration of epithelial tumor cells

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