H. Stoeckel scite author profile

One of the major tyrosine phosphorylation activities linked to integrin signalling is that of focal adhesion kinase (FAK). High amounts of FAK are located at specialised subcellular compartments known as focal adhesions. FAK tyrosine phosphorylation at focal adhesions is increased by various stimuli including integrin engagement during migration processes, growth factors and oncogene transformation. Phosphorylation of FAK at various tyrosine residues regulates focal adhesion turnover by mechanisms that are not well understood. We made a fluorescent FAK mutant (Y397F-FAK/YCam) to analyse, in living cells, how phosphorylation of FAK regulates the turnover of focal adhesions. We found that expression of Y397F-FAK/YCam in human astrocytoma cells decreases the level of phosphorylation of FAK at endogenous Tyr-397 residues and at both endogenous and exogenous Tyr-576 residues, in the putative activation loop of the kinase. This corresponds to a decrease in phosphorylation of FAK at focal adhesions in Y397F-FAK/YCam cells, since the cellular localisation of FAK phosphoTyr-576 in cells expressing Y397F-FAK/YCam or FAK/YCam was not different. Furthermore, FRAP analysis showed that phosphorylation of FAK at Tyr-397 increases specifically the time-residency of FAK at focal adhesions but not in cytosol. This in turn induces disassembly of focal adhesions at the cell tail and promotes cell motility as shown by the decrease in microtubule-mediated turnover of Y397F-FAK/YCam-containing focal adhesions. Our data show that phosphorylation of FAK at Tyr-397 is a key determinant of how FAK controls focal adhesion turnover.

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Voltage-activated potassium, but not calcium currents in cultured bovine aortic endothelial cells

Takeda

1987

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The electrophysiological properties of cultured bovine aortic endothelial cells were characterized using the patch clamp technique. Resting potentials were measured on passing to the whole cell recording configuration and were close to--65 mV in healthy cells. In cell-attached recordings with a high potassium pipette solution, inward single channel currents were observed with zero applied pipette potential. A linear slope conductance of 25 pS was found for a wide range of hyperpolarizing patch potentials and also for depolarizing patch potentials of up to 50-60 mV. A pronounced inward rectification was apparent as no reversal of these currents was seen for larger depolarizations. Whole cell recording in physiological solutions revealed the presence of a hyperpolarization-activated inward current with strong inward rectification and no voltage-dependent ionic current was observed upon depolarization in this subset of cells. Substitution of potassium for external sodium resulted in a shift in the zero current potential consistent with potassium being the main permeant ion. Together with the characteristic voltage-dependent blocking actions of external sodium ions and low concentrations of barium and caesium ions, our results indicate that this current is very similar to the classical inward rectifier as originally described in skeletal muscle and in tunicate eggs. In a second population of cells, a depolarization-activated outward current displaying characteristics of the fast transient A-type potassium current as first reported in molluscan neurones was also observed. No evidence for inward voltage dependent sodium or calcium currents was found.

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Fluorescent Probe Based on Intramolecular Proton Transfer for Fast Ratiometric Measurement of Cellular Transmembrane Potential

et al. 2006

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Development of fast-response potentiometric probes for measuring the transmembrane potential Vm in cell plasma membranes remains a challenge. To overcome the limitations of the classical charge-shift potentiometric probes, we selected a 3-hydroxychromone fluorophore undergoing an excited-state intramolecular proton transfer (ESIPT) reaction that generates a dual emission highly sensitive to electric fields. To achieve the highest sensitivity to the electric field associated to Vm, we modified the fluorophore by adding two rigid legs containing terminal polar sulfonate groups to allow a deep vertical insertion of the fluorophore into the membrane. Fluorescence spectra of the new dye in lipid vesicles and cell membranes confirm the fluorophore location in the hydrophobic region of the membranes. Variation of Vm in lipid vesicles and cell plasma membranes results in a change of the intensity ratio of the two emission bands of the probe. The ratiometric response of the dye in cells is approximately 15% per 100 mV, and is thus quite large in comparison with most single-fluorophore, fast-response probes reported to date. Combined patch-clamp/fluorescence data further show that the ratiometric response of the dye in cells is faster than 1 ms. Analysis of the excitation and emission shifts further suggests that the probe responds to changes in Vm by a mechanism based on electrochromic modulation of its ESIPT reaction. Thus, for the first time, the ESIPT reaction has been successfully applied as a sensing principle for detection of transmembrane potential, allowing to couple classical electrochromic band shifts with changes in the relative intensities of the two well-separated emission bands. The fast two-band ratiometric response as well as the relatively high sensitivity of the new probe are the key features that make it useful for rapid detection of Vm changes in cell suspensions and single cells. Moreover, the new design principles proposed in the present work should allow further improvement of the probe sensitivity.

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H. Stoeckel

Regulation of focal adhesion dynamics and disassembly by phosphorylation of FAK at tyrosine 397

Voltage-activated potassium, but not calcium currents in cultured bovine aortic endothelial cells

Fluorescent Probe Based on Intramolecular Proton Transfer for Fast Ratiometric Measurement of Cellular Transmembrane Potential

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