Wolfram Nagel scite author profile

The potential profile of the frog skin epithelium incubated in Cl-Ringer was reinvestigated with improved technique. Under open circuit conditions (PDtr up to 120 mV) the potential profile was demonstrated to be trough like in contrast to the stair-step like potential profile reported by previous investigators which has probably been recorded after injuring of the punctured cells. In 67 successful impalements the potential difference across the basolateral membranes was 108 +/- 2 mV. The potential across the outer, epithelial-facing membrane was inversely related to the transepithelial PD, but was found to be negative (with respect to the epithelial bathing solution) in all punctures. Electrogenic sodium transport might be responsible for part of the potential difference across the basolateral membranes which correlatee directly with the short circuited state was -73 +/- i mV and decreased with increasing short cirucit current. It is suggested that these changes result from variations of the outer membrane sodium conductance.

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Inhibition of potassium conductance by barium in frog skin epithelium

Nagel

1979

Biochimica et Biophysica Acta (BBA) - Biomembranes

148

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Voltage clamping single cells in intact Malpighian tubules of mosquitoes

Masia¹,

Aneshansley

Nagel³

et al. 2000

American Journal of Physiology-Renal Physiology

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Principal cells of the Malpighian tubule of the yellow fever mosquito were studied with the methods of two-electrode voltage clamp (TEVC). Intracellular voltage (V(pc)) was -86.7 mV, and input resistance (R(pc)) was 388.5 kOmega (n = 49 cells). In six cells, Ba(2+) (15 mM) had negligible effects on V(pc), but it increased R(pc) from 325.3 to 684.5 kOmega (P < 0.001). In the presence of Ba(2+), leucokinin-VIII (1 microM) increased V(pc) to -101.8 mV (P < 0.001) and reduced R(pc) to 340.2 kOmega (P < 0.002). Circuit analysis yields the following: basolateral membrane resistance, 652. 0 kOmega; apical membrane resistance, 340.2 kOmega; shunt resistance (R(sh)), 344.3 kOmega; transcellular resistance, 992.2 kOmega. The fractional resistance of the apical membrane (0.35) and the ratio of transcellular resistance and R(sh) (3.53) agree closely with values obtained by cable analysis in isolated perfused tubules and confirm the usefulness of TEVC methods in single principal cells of the intact Malpighian tubule. Dinitrophenol (0.1 mM) reversibly depolarized V(pc) from -94.3 to -10.7 mV (P < 0.001) and reversibly increased R(pc) from 412 to 2,879 kOmega (P < 0.001), effects that were duplicated by cyanide (0.3 mM). Significant effects of metabolic inhibition on voltage and resistance suggest a role of ATP in electrogenesis and the maintenance of conductive transport pathways.

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Effects of antidiuretic hormone upon electrical potential and resistance of apical and basolateral membranes of frog skin

Nagel

1978

J. Membrain Biol.

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The effect of ADH upon the intracellular potential and the resistance of inner and outer borders of the transport pathway was investigated on isolated skins of Rana temporaria. Within 40 min after ADH (100--300 mU/ml), the intracellular potential under short-circuit conditions decreased to about 40% of the control value (--79 +/- 4 mV), concomitant with an increase in the short-circuit current to about 160% of the control value. Amiloride, applied when steady values under ADH had been reached, caused an immediate rise of the intracellular potential to values typical for control conditions. This confirms (i) the intracellular location of the microelectrode and the absence of impalement artifacts, and (ii) the ineffectiveness of ADH upon the electromotive forces of the inner border. ADH had no effect upon the intracellular potential after blockage of the Na entry by Amiloride. The equilibrium potential of the outer border was estimated to be about +20mV under the influence of ADH. As this value is considerably less positive than might be expected for the chemical potential of Na, a significant contribution of ions other than Na to the outer border conductance and equilibrium potential is implicated. The resistance of the outer border was more significantly decreased than that of the active transcellular pathway after ADH due to an increase in the inner border resistance, which exceeded that of the outer border after ADH. The effect of ADH upon the outer membrane characteristics would be underestimated by a factor of two, if the alterations of the electrical potential difference were not taken into consideration.

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Nitric oxide specifically reduces the permeability of Cx37‐containing gap junctions to small molecules

Kameritsch

Khandoga

Nagel

et al. 2004

Journal Cellular Physiology

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Gap junction intercellular communication (GJIC) plays a significant role in the vascular system. Regulation of GJIC is a dynamic process, with alterations in connexin (Cx) protein expression and post-translational modification as contributing mechanisms. We hypothesized that the endothelial autacoid nitric oxide (NO) would reduce dye coupling in human umbilical vein endothelial cells (HUVECs). In our subsequent experiments, we sought to isolate the specific Cx isoform(s) targeted by NO or NO-activated signaling pathways. Since HUVEC cells variably express three Cx (Cx37, Cx40, and Cx43), this latter aim required the use of transfected HeLa cells (HeLaCx37, HeLaCx43), which do not express Cx proteins in their wild type form. Dye coupling was measured by injecting fluorescent dye (e.g., Alexa Fluor 488) into a single cell and determining the number of stained adjacent cells. Application of the NO donor SNAP (2 mM, 20 min) reduced dye coupling in HUVEC by 30%. In HeLa cells, SNAP did not reduce dye transfer of cells expressing Cx43, but decreased the dye transfer from Cx37-expressing cells to Cx43-expressing cells by 76%. The effect of SNAP on dye coupling was not mediated via cGMP. In contrast to its effect on dye coupling, SNAP had no effect on electrical coupling, measured by a double patch clamp in whole cell mode. Our results demonstrate that NO inhibits the intercellular transfer of small molecules by a specific influence on Cx37, suggesting a potential role of NO in controlling certain aspects of vascular GJIC.

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Wolfram Nagel

The intracellular electrical potential profile of the frog skin epithelium

Inhibition of potassium conductance by barium in frog skin epithelium

Voltage clamping single cells in intact Malpighian tubules of mosquitoes

Effects of antidiuretic hormone upon electrical potential and resistance of apical and basolateral membranes of frog skin

Nitric oxide specifically reduces the permeability of Cx37‐containing gap junctions to small molecules

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