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Start Over Author "Dietl, Paul" Publisher wiley-blackwell
12 results on '"Dietl, Paul"'

1. P2X4 receptor re‐sensitization depends on a protonation/deprotonation cycle mediated by receptor internalization and recycling.

Author

Fois, Giorgio, Föhr, Karl J., Kling, Carolin, Fauler, Michael, Wittekindt, Oliver H., Dietl, Paul, and Frick, Manfred

Subjects
PROTON transfer reactions, HISTIDINE, CELL membranes, ADENOSINE triphosphate, IMMUNE response
Abstract

Key points: Re‐sensitization of P2X4 receptors depends on a protonation/de‐protonation cycleProtonation and de‐protonation of the receptors is achieved by internalization and recycling of P2X4 receptors via acidic compartmentsProtonation and de‐protonation occurs at critical histidine residues within the extracellular loop of P2X4 receptorsRe‐sensitization is blocked in the presence of the receptor agonist ATP P2X4 receptors are members of the P2X receptor family of cation‐permeable, ligand‐gated ion channels that open in response to the binding of extracellular ATP. P2X4 receptors are implicated in a variety of biological processes, including cardiac function, cell death, pain sensation and immune responses. These physiological functions depend on receptor activation on the cell surface. Receptor activation is followed by receptor desensitization and deactivation upon removal of ATP. Subsequent re‐sensitization is required to return the receptor into its resting state. Desensitization and re‐sensitization are therefore crucial determinants of P2X receptor signal transduction and responsiveness to ATP. However, the molecular mechanisms controlling desensitization and re‐sensitization are not fully understood. In the present study, we provide evidence that internalization and recycling via acidic compartments is essential for P2X4 receptor re‐sensitization. Re‐sensitization depends on a protonation/de‐protonation cycle of critical histidine residues within the extracellular loop of P2X4 receptors that is mediated by receptor internalization and recycling. Interestingly, re‐sensitization under acidic conditions is completely revoked by receptor agonist ATP. Our data support the physiological importance of the unique subcellular distribution of P2X4 receptors that is predominantly found within acidic compartments. Based on these findings, we suggest that recycling of P2X4 receptors regulates the cellular responsiveness in the sustained presence of ATP. Key points: Re‐sensitization of P2X4 receptors depends on a protonation/de‐protonation cycleProtonation and de‐protonation of the receptors is achieved by internalization and recycling of P2X4 receptors via acidic compartmentsProtonation and de‐protonation occurs at critical histidine residues within the extracellular loop of P2X4 receptorsRe‐sensitization is blocked in the presence of the receptor agonist ATP [ABSTRACT FROM AUTHOR]

Published
2018
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3. Fusion-activated cation entry (FACE) via P2X4 couples surfactant secretion and alveolar fluid transport.

Author

Thompson, Kristin E., Korbmacher, Jonas P., Hecht, Elena, Hobi, Nina, Wittekindt, Oliver H., Dietl, Paul, Kranz, Christine, and Frick, Manfred

Subjects
PHYSIOLOGICAL effects of surface active agents, PULMONARY alveoli, EXOCYTOSIS, LUNG physiology, BODY fluids, ATOMIC force microscopy
Abstract

Two fundamental mechanisms within alveoli are essential for lung function: regulated fluid transport and secretion of surfactant. Surfactant is secreted via exocytosis of lamellar bodies (LBs) in alveolar type II (ATII) cells. We recently reported that LB exocytosis results in fusion-activated cation entry (FACE) via P2X4 receptors on LBs. We propose that FACE, in addition to facilitating surfactant secretion, modulates alveolar fluid transport. Correlative fluorescence and atomic force microscopy revealed that FACE-dependent water influx correlated with individual fusion events in rat primary ATII cells. Moreover, ATII cell monolayers grown at air-liquid interface exhibited increases in short-circuit current (Isc) on stimulation with ATP or UTP. Both are potent agonists for LB exocytosis, but only ATP activates FACE. ATP, not UTP, elicited additional fusion-dependent increases in Isc. Overexpressing dominant-negative P2X4 abrogated this effect by ~50%, whereas potentiating P2X4 lead to ~80% increase in Isc. Finally, we monitored changes in alveolar surface liquid (ASL) on ATII monolayers by confocal microscopy. Only stimulation with ATP, not UTP, led to a significant, fusion-dependent, 20% decrease in ASL, indicating apical-to-basolateral fluid transport across ATII monolayers. Our data support the first direct link between LB exocytosis, regulation of surfactant secretion, and transalveolar fluid resorption via FACE. [ABSTRACT FROM AUTHOR]

Published
2013
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4. Effects of keratin phosphorylation on the mechanical properties of keratin filaments in living cells.

Author

Fois, Giorgio, Weimer, Michael, Busch, Tobias, Felder, Erika T., Oswald, Franz, von Wichert, Götz, Seufferlein, Thomas, Dietl, Paul, and Felder, Edward

Subjects
CYTOSKELETON, CYTOARCHITECTONICS, CYTOPLASMIC filaments, KERATIN, PHOSPHORYLATION, MYOSIN, SQUAMOUS cell carcinoma
Abstract

Keratin filaments impart resilience against mechanical extension of the cell. Despite the pathophysiological relevance of this function, very little is known about the mechanical properties of intermediate filaments in living cells and how these properties are modulated. We used keratin mutants that mimic or abrogate phosphorylation of keratin 8-serine431 and keratin 18-serine52 and investigated their effect on keratin tortuousness after cell stretch release in squamous cell carcinoma cells. Cells transfected with the wild-type keratins were used as controls. We can show that keratin dephosphorylation alters the stretch response of keratin in living cells since keratin tortuousness was abolished when phosphorylation of keratin18-serine52 was abrogated. Additional experiments demonstrate that keratin tortuousness is not simply caused by a plastic overextension of keratin filaments because tortuousness is reversible and requires an intact actin-myosin system. The role of actin in this process remains unclear, but we suggest anchorage of keratin filaments to actin during stretch that leads to buckling on stretch release. Dephosphorylated keratin18-serine52 might strengthen the recoil force of keratin filaments and hence explain the abolished buckling. The almost exclusive immunolabeling for phosphorylated keratin18-serine 52 in the cell periphery points at a particular role of the peripheral keratin network in this regard. [ABSTRACT FROM AUTHOR]

Published
2013
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5. Ca2+-Dependent Actin Coating of Lamellar Bodies after Exocytotic Fusion: A Prerequisite for Content Release or Kiss-and-Run.

Author

Miklavc, Pika, Wittekindt, Oliver H., Felder, Edward, and Dietl, Paul

Subjects
EXOCYTOSIS, CELL fusion, LIPOPROTEINS, LIPIDS, CELLS, PROTEINS, CELL physiology, CYTOLOGY, BIOLOGY
Abstract

Type II pneumocytes secrete surfactant, a lipoprotein-like substance reducing the surface tension in the lung, by regulated exocytosis of secretory vesicles termed lamellar bodies (LBs). This secretory process is characterized by a protracted postfusion phase in which fusion pores open slowly and may act as mechanical barriers for release. Combining dark-field with fluorescence microscopy, we show in ß-actin green fluorescent protein-transfected pneumocytes that LB fusion with the plasma membrane is followed by actin coating of the fused LB. This is inhibited by cytoplasmic Ca2+ chelation or the phospholipase D inhibitor C2 ceramide. Actin coating occurs by polymerization of actin monomers, as evidenced by staining with Alexa 568 phalloidin. After actin coating of the fused LB, it either shrinks while releasing surfactant (“kiss-coat-and-release”), remains in this fused state without further action (“kiss-coat-and-wait”), or is retrieved and pushed forward in the cell on top of an actin tail (“kiss-coat-and-run”). In the absence of actin coating, no release or run was observed. These data suggest that actin coating creates a force needed for either extrusion of vesicle contents or retrieval and intracellular propulsion. [ABSTRACT FROM AUTHOR]

Published
2009
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6. Formation of cellular projections in neural progenitor cells depends on SK3 channel activity.

Author

Liebau, Stefan, Vaida, Bianca, Proepper, Christian, Grissmer, Stephan, Storch, Alexander, Boeckers, Tobias M., Dietl, Paul, and Wittekindt, Oliver H.

Subjects
ION channels, CALCIUM-dependent potassium channels, MEMBRANE proteins, GENETIC transcription, GENE expression, NEUROCHEMISTRY
Abstract

Ion channels are potent modulators for developmental processes in progenitor cells. In a screening approach for different ion channels in neural progenitor cells (NPCs) we observed a 1-ethyl-2-benzimidazolinone (1-EBIO) activated inward current, which could be blocked by scyllatoxin (ScTX, IC50 = 2 ± 0.3 nmol/L). This initial evidence for the expression of the small conductance Ca2+ activated K+-channel SK3 was confirmed by the detection of SK3 transcripts and protein in NPCs. Interestingly, SK3 proteins were highly expressed in non-differentiated NPCs with a focused localization in lamellipodia as well as filopodial structures. The activation of SK3 channels using 1-EBIO lead to an immediate filopodial sprouting and the translocation of the protein into these novel filopodial protrusions. Both effects could be prevented by the pre-incubation of NPCs with ScTX. Our study gives first evidence that the formation and prolongation of filopodia in NPCs is, at least in part, effectively induced and regulated by SK3 channels. [ABSTRACT FROM AUTHOR]

Published
2007
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