Effect of insulin on area and Na+ channel density of apical membrane of cultured toad kidney cells.

D Erlij; P De Smet; W Van Driessche

doi:10.1113/jphysiol.1994.sp020461

Electrophysiology and noise analysis of K+-depolarized epithelia of frog skin

AJP Cell Physiology ◽

10.1152/ajpcell.1985.249.5.c421 ◽

1985 ◽

Vol 249 (5) ◽

pp. C421-C429 ◽

Cited By ~ 48

Author(s):

J. Tang ◽

F. J. Abramcheck ◽

W. Van Driessche ◽

S. I. Helman

Keyword(s):

Frog Skin ◽

Single Channel ◽

Apical Membrane ◽

Short Circuit ◽

Noise Analysis ◽

Basolateral Membrane ◽

Short Circuit Current ◽

Membrane Resistance ◽

Na Channel ◽

Channel Density

Epithelia of frog skin bathed either symmetrically with a sulfate-Ringer solution or bathed asymmetrically and depolarized with a 112 mM K+ basolateral solution (Kb+) were studied with intracellular microelectrode techniques. Kb+ depolarization caused an initial decrease of the short-circuit current (Isc) with a subsequent return of the Isc toward control values in 60-90 min. Whereas basolateral membrane resistance (Rb) and voltage were decreased markedly by high [Kb+], apical membrane electrical resistance (Ra) was decreased also. After 60 min, intracellular voltage averaged -27.3 mV, transcellular fractional resistance (fRa) was 86.8%, and Ra and Rb were decreased to 36.1 and 13.0%, of their control values, respectively. Amiloride-induced noise analysis of the apical membrane Na+ channels revealed that Na+ channel density was increased approximately 72% while single-channel Na+ current was decreased to 39.9% of control, roughly proportional to the decrease of apical membrane voltage (34.0% of control). In control and Kb+-depolarized epithelia, the Na+ channel density exhibited a phenomenon of autoregulation. Inhibition of Na+ entry (by amiloride) caused large increases of Na+ channel density toward saturating values of approximately 520 X 10(6) channels/cm2 in Kb+-depolarized tissues.

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Autoregulation of apical membrane Na+ permeability of tight epithelia. Noise analysis with amiloride and CGS 4270.

The Journal of General Physiology ◽

10.1085/jgp.85.4.555 ◽

1985 ◽

Vol 85 (4) ◽

pp. 555-582 ◽

Cited By ~ 39

Author(s):

F J Abramcheck ◽

W Van Driessche ◽

S I Helman

Keyword(s):

Single Channel ◽

Apical Membrane ◽

Noise Analysis ◽

Ringer Solution ◽

Critical Examination ◽

Na Channel ◽

Channel Density ◽

Na Permeability ◽

Na Currents ◽

Tight Epithelia

Noise analysis of the Na+ channels of the apical membranes of frog skin bathed symmetrically in a Cl-HCO3 Ringer solution was done with amiloride and CGS 4270. Tissues were studied in their control states and after inhibition of transepithelial Na+ transport (Isc) by addition of quinine or quinidine to the apical solution. A critical examination of the amiloride-induced noise indicated that the single channel Na+ currents (iNa) were decreased by quinine and quinidine, probably because of depolarization of apical membrane voltage. Despite considerable statistical uncertainty in the methods of estimation of the Na+ channel density with amiloride-induced noise (NA, see text), the striking observation was a large increase of NA with amiloride inhibition of the rate of Na+ entry into the cells. NA was increased to 406% of control, whereas Isc was inhibited to 8.6% of control by 6 microM amiloride. Studies were done also with the Na+ channel blocker CGS 4270. Noise analysis with this compound was advantageous, permitting iCGSNa and NCGS to be measured in individual tissues with a relatively small inhibition of Isc. As with amiloride, inhibition of Isc with CGS 4270 caused large increases of the Na+ channel density (approximately 200% at approximately 35% inhibition of the Isc). Quinine and quinidine caused an approximately 50% increase of Na+ channel density while inhibiting iNa by approximately 60-70%. As inhibition of Na+ entry leads to an increase of Na+ channel density, a mechanism of autoregulation appears to be a major factor in adjusting the apical membrane Na+ permeability of the cells.

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Time-dependent apical membrane K+ and Na+ selectivity in cultured kidney cells

AJP Cell Physiology ◽

10.1152/ajpcell.1987.253.1.c1 ◽

1987 ◽

Vol 253 (1) ◽

pp. C1-C6 ◽

Cited By ~ 15

Author(s):

S. R. Thomas ◽

E. Mintz

Keyword(s):

Apical Membrane ◽

Time Dependent ◽

Kidney Cells ◽

K Channels ◽

Membrane Selectivity ◽

Conductive Pathway ◽

Group I ◽

A6 Epithelia ◽

Group Ii ◽

Apical Membranes

Intracellular microelectrodes were used to study apical membrane selectivity to Na+ and K+ of cultured toad kidney cells (A6) grown on permeable supports. Membrane selectivity was tested by responses of apical membrane potential to replacement of Na+ by K+ or tetraethylammonium and by addition of amiloride to perfusion solutions. The A6 epithelia fell into two groups: those with K+-selective apical membranes, lack of amiloride sensitivity, and near-zero transepithelial potential (group I); and those with Na+-selective apical membranes and a serosa-positive, amiloride-sensitive transepithelial potential (Vm----s; group II). The transition from group I to group II behavior appeared definitive and time dependent, occurring approximately 10 days after plating onto filters. Transepithelial measurements under sterile conditions showed that overnight incubation with aldosterone (10(-7) M), after development of tight junctions (transepithelial resistance elevated) but before development of significant Vm----s, induced the switch from group I to group II behavior. Apical addition of Ba2+, a known blocker of K+ channels, unexpectedly reduced transepithelial resistance (Rm----s) in group I and group II A6, suggesting that it not only blocked K+ channels (when they are present) but may also open a parallel conductive pathway. In summary, after approximately 10 days in culture, apical membranes of A6 epithelia undergo a switch from K+ to Na+ selectivity, overnight incubation with aldosterone can trigger this change, and finally, Ba2+ may open a paracellular conductive pathway.

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Apical nonspecific cation conductances in rabbit cecum

AJP Gastrointestinal and Liver Physiology ◽

10.1152/ajpgi.1994.266.3.g475 ◽

1994 ◽

Vol 266 (3) ◽

pp. G475-G484 ◽

Cited By ~ 2

Author(s):

J. H. Sellin ◽

W. P. Dubinsky

Keyword(s):

Epithelial Transport ◽

Apical Membrane ◽

Divalent Cations ◽

Short Circuit ◽

Short Circuit Current ◽

Distal Colon ◽

Na Channel ◽

Similar Response ◽

Electrogenic Transport

Rabbit cecum exhibits electrogenic Na absorption in vitro. However, because this transport process is not inhibited by amiloride nor does it demonstrate saturation kinetics typical of the amiloride-inhibitable Na channel, we considered whether the cecal transporter represented one of a recently described family of nonselective cation conductances or channels (NSCC). Both transepithelial and vesicle studies demonstrated that K, Cs, and Rb were transported via an apical conductance. Electrogenic transport was inhibited by divalent cations including Ca, Mg, and Ba but was unaffected by either lanthanum or gadolinium. Parallel studies in distal colon did not exhibit a similar response to either K substitution or Ba inhibition. Phenamil, verapamil, and nicardipine significantly inhibited the short-circuit current (Isc). stimulated by nominal Ca- and Mg-free conditions. Flux studies demonstrated a correlation between changes in Isc and Na transport. Microelectrode impalement studies suggested that there may be both NSCC and K conductance in the apical membrane. Planar bilayer studies identified a 190-pS cation channel that may correlate with the macroscopic transport properties of this epithelium. These studies are consistent with a model of cecal Na absorption mediated by a NSCC in the apical membrane; this may be the mechanism underlying the distinct epithelial transport characteristics of this intestinal segment.

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Cytoskeletal control of centrioles movement during the establishment of polarity in Madin-Darby canine kidney cells.

The Journal of Cell Biology ◽

10.1083/jcb.110.4.1123 ◽

1990 ◽

Vol 110 (4) ◽

pp. 1123-1135 ◽

Cited By ~ 63

Author(s):

B Buendia ◽

M H Bré ◽

G Griffiths ◽

E Karsenti

Keyword(s):

Apical Membrane ◽

Intercellular Junctions ◽

Early Event ◽

Kidney Cells ◽

Madin Darby Canine Kidney ◽

Low Calcium ◽

Polarized Cells ◽

Cellular Junctions ◽

Darby Canine Kidney ◽

Canine Kidney

The two centrioles that are localized close to each other and to the nucleus in single Madin-Darby Canine kidney cells (MDCK) move apart by distances as large as 13 microns after the establishment of extensive cellular junctions. Microfilaments, and possibly microtubules appear to be responsible for this separation. In fully polarized cells, the centrioles are localized just beneath the apical membrane. After disruption of intercellular junctions in low calcium medium, the centrioles move back towards the cell center. This process requires intact microtubules but happens even in the absence of microfilaments. These results indicate that the position of centrioles is determined by opposing forces produced by microtubules and microfilaments and suggest that the balance between these forces is modulated by the assembly of cellular junctions. Centriole separation appears to be an early event in the process that precedes their final positioning in the apical-most region of the polarized cell.

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EGF and PGE2 inhibit rabbit CCD Na+ transport by different mechanisms: PGE2 inhibits Na(+)-K+ pump

AJP Renal Physiology ◽

10.1152/ajprenal.1993.264.4.f670 ◽

1993 ◽

Vol 264 (4) ◽

pp. F670-F677 ◽

Cited By ~ 8

Author(s):

D. H. Warden ◽

J. B. Stokes

Keyword(s):

Apical Membrane ◽

Collecting Duct ◽

Basolateral Membrane ◽

Membrane Conductance ◽

Membrane Voltage ◽

Na Channel ◽

Cortical Collecting Duct ◽

Na Transport ◽

Flux Measurements ◽

Epidermal Growth

The rabbit cortical collecting duct absorbs Na+ by a transport system comprised of an apical membrane Na+ channel and a basolateral membrane Na(+)-K(+)-adenosinetriphosphatase. The rate of Na+ absorption across this epithelium is acutely inhibited by several hormones and autacoids including epidermal growth factor (EGF) and prostaglandin E2 (PGE2). We used electrophysiological analysis to determine which Na+ transport mechanism is primarily regulated in response to EGF and PGE2. We used concentrations of EGF and PGE2 that inhibited Na+ absorption to a comparable degree. We assessed the effects of these agents on Na+ transport primarily by the calculated equivalent current; the validity of this indicator was verified using simultaneous tracer flux measurements. EGF and PGE2 had different effects on the intracellular electrophysiological parameters. EGF (in the presence of a cyclooxygenase inhibitor) hyperpolarized the apical membrane voltage in a manner analogous to the Na(+)-channel blocker amiloride, reduced the transepithelial conductance, and increased the fractional resistance of the apical membrane. In comparison, PGE2 depolarized the apical membrane voltage in a manner analogous to the Na(+)-K+ pump inhibitor ouabain, and caused no significant changes in transepithelial conductance or apical membrane conductance. The finding that EGF hyperpolarized the apical membrane indicates that this agent attenuates Na+ absorption by reducing apical Na+ entry due to a decrease in the magnitude of the apical membrane Na+ conductance. In contrast, the electrophysiological changes produced by PGE2 indicate primary inhibition of the basolateral Na(+)-K+ pump following PGE2 treatment.

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An SH3 binding region in the epithelial Na+ channel (alpha rENaC) mediates its localization at the apical membrane.

The EMBO Journal ◽

10.1002/j.1460-2075.1994.tb06766.x ◽

1994 ◽

Vol 13 (19) ◽

pp. 4440-4450 ◽

Cited By ~ 156

Author(s):

D. Rotin ◽

D. Bar-Sagi ◽

H. O'Brodovich ◽

J. Merilainen ◽

V.P. Lehto ◽

...

Keyword(s):

Apical Membrane ◽

Na Channel ◽

Binding Region ◽

Epithelial Na Channel

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Dual action of aldosterone on toad bladder: Na+ permeability and Na+ pump modulation

AJP Renal Physiology ◽

10.1152/ajprenal.1984.246.4.f517 ◽

1984 ◽

Vol 246 (4) ◽

pp. F517-F525 ◽

Cited By ~ 1

Author(s):

C. S. Park ◽

I. S. Edelman

Keyword(s):

Urinary Bladder ◽

Apical Membrane ◽

Basolateral Membrane ◽

Electrical Conductance ◽

Na Channel ◽

Metabolic State ◽

Na Pump ◽

Na Permeability ◽

Basolateral Side ◽

Dual Action

The effects of aldosterone on the functional characteristics of the Na+ entry step across the apical membrane and on the Na+ exit step across the basolateral membrane of the urinary bladder of toads were examined using amiloride and ouabain as probes of the respective surfaces of the cell. Aldosterone stimulated Na+ transport with a concurrent increase in the transepithelial electrical conductance as did two other agents, vasopressin (ADH) and p-chloromercuriphenylsulfonate (PCMPS), primarily active on the apical membrane. Unlike the effects of ADH and PCMPS, however, the effect of aldosterone on Na+ conductance was blocked by actinomycin D and was associated with a decreased sensitivity of the apical Na+ channel to amiloride. In addition, aldosterone increased the sensitivity of the Na+ pump on the basolateral side to ouabain, an effect that was dependent on the metabolic state of the urinary bladder. These results support the inference of coordinate effects on Na+ permeability of the apical membrane and the Na+ pump of the basolateral membrane. Both effects of aldosterone appear to be dependent on the metabolic state of the transporting epithelium.

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Quantification of K+ secretion through apical low-conductance K channels in the CCD

AJP Renal Physiology ◽

10.1152/ajprenal.00471.2004 ◽

2005 ◽

Vol 289 (1) ◽

pp. F117-F126 ◽

Cited By ~ 36

Author(s):

Daniel A. Gray ◽

Gustavo Frindt ◽

Lawrence G. Palmer

Keyword(s):

Single Channel ◽

Collecting Duct ◽

Reversal Potential ◽

Inward Rectification ◽

Na Channel ◽

Sk Channels ◽

Maximal Conductance ◽

Channel Density ◽

Sk Channel ◽

High K

Outward and inward currents through single small-conductance K+ (SK) channels were measured in cell-attached patches of the apical membrane of principal cells of the rat cortical collecting duct (CCD). Currents showed mild inward rectification with high [K+] in the pipette (Kp+), which decreased as Kp+ was lowered. Inward conductances had a hyperbolic dependence on Kp+ with half-maximal conductance at ∼20 mM. Outward conductances, measured near the reversal potential, also increased with Kp+ from 15 pS (Kp+ = 0) to 50 pS (Kp+ = 134 mM). SK channel density was measured as the number of conducting channels per patch in cell-attached patches. As reported previously, channel density increased when animals were on a high-K diet for 7 days. Addition of 8-cpt-cAMP to the bath at least 5 min before making a seal increased SK channel density to an even greater extent, although this increase was not additive with the effect of a high-K diet. In contrast, increases in Na channel activity, assessed as the whole cell amiloride-sensitive current, due to K loading and 8-cpt-cAMP treatment were additive. Single-channel conductances and channel densities were used as inputs to a simple mathematical model of the CCD to predict rates of transepithelial Na+ and K+ transport as a function of apical Na+ permeability and K+ conductance, basolateral pump rates and K+ conductance, and the paracellular conductance. With measured values for these parameters, the model predicted transport rates that were in good agreement with values measured in isolated, perfused tubules. The number and properties of SK channels account for K+ transport by the CCD under all physiological conditions tested.

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