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Voltage clamp study of stimulant-evoked currents in mouse pancreatic acinar cells (1983)

Maruyama, Y. ; Petersen, O. H.

Springer

Pflügers Archiv 399 (1983), S. 54-62

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ISSN: 1432-2013

Keywords: Pancreas ; Acinar cell ; Voltage clamp ; Current transients ; Acetylcholine

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Isolated segments of mouse pancreas were placed in a perspex bath and superfused with physiological saline solution. Acinar units were voltage-clamped with the help of two intracellular microelectrodes. Voltage homogeneity was in some experiments checked with a third microelectrode inserted into the same unit. The currents associated with hyper- or depolarizing voltage jumps were recorded in the absence or presence of sustained stimulation with acetylcholine (ACh), caerulein or bombesin nonapeptide. ACh (2×10−7−10−8 M) evoked a dose-dependent inward current and an increase in the membrane conductance. The steady state ACh-evoked current (control current subtracted from total current in presence of ACh) depended linearly on voltage within the range −100 to +20 mV and its polarity reversed at about −25 mV. The effects of caerulein and bombesin nonapeptide were indistinguishable from those of ACh. Voltage homogeneity in the acinar unit was attained earlier than 1 ms after a hyper- or depolarizing voltage jump. The current transients associated with voltage jumps decayed according to single exponential functions both in the absence and presence of ACh. The time constant of the single exponential current decay after a voltage jump was the same (1–3 ms) in the absence or presence of ACh. The amplitude of the current transient was, however, reduced by ACh. The time constant of the current decay following voltage jumps was independent of the voltage in the range +60 to −60 mV, both in the absence and presence of ACh. The ACh-evoked reduction in the amplitude of the transient current following voltage jumps dependend linearly on the voltage. In individual units, the slope of this curve was the same as the slope of the curve relating the steady state ACh-evoked increase in current to membrane potential. It is concluded that the ACh controlled pathways are not voltage sensitive. The effects of ACh on the current transients associated with the voltage jumps can best be explained by assuming that the ACh-evoked conductance increase resides predominantly in the lateral plasma membranes which border on narrow extracellular spaces.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00652522

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Patch-clamp study of rubidium and potassium conductances in single cation channels from mammalian exocrine acini (1984)

Gallacher, D. V. ; Maruyama, Y. ; Petersen, O. H.

Springer

Pflügers Archiv 401 (1984), S. 361-367

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Details

ISSN: 1432-2013

Keywords: Patch-clamp single channel recording ; K+ channel ; K+ conductance ; Rb+ conductance ; Salivary gland ; Pancreas ; Acinar cells

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Single-channel current recordings were carried out on excised inside-out patches of baso-lateral plasma membrane from exocrine acinar cells. The mouse pancreas and submandibular gland as well as the pig pancreas were investigated. In the mouse pancreas the voltage-insensitive Ca2+-activated cation channel was studied. Single-channel current-voltage (i/v) relationships were studied in symmetrical Rb+-rich solutions and in asymmetrical Rb+/Na+ and Na+/Rb+ solutions. In all cases the i/v relations were linear and had the same slope representing a single-channel conductance of about 33 pS which is identical to that previously obtained with symmetrical Na+ solutions or asymmetrical Na+/K+ solutions. In the mouse submandibular gland and the pig pancreas the voltage and Ca2+-activated K+ channel was studied. The outward currents observed after depolarization in the presence of quasi-physiological Na+/K+ gradients were immediately abolished when all the K+ in the bath fluid was replaced by Rb+ (bath fluid in contact with inside of plasma membrane). This effect was immediately and fully reversible upon return to the high K+ solution. The voltage and Ca2+-activated K+ channel was also studied in asymmetrical K+/Rb+ and Rb+/K+ solutions. In the first case inward (K+) currents could be observed but not outward (Rb+) currents, while in the other case inward (Rb+) currents could not be seen whereas outward (K+) currents were measured. The current-voltage relationships were approximately linear and the null potential was close to 0 mV in both situations. In contrast the null potential for current through the K+ channel in the presence of asymmetrical Na+/K+ or Li+/K+ solutions was about −70 mV and with reversed gradients about +60 mV. Outward K+ currents of reduced size (through the voltage and Ca2+-activated K+ channel) could be observed when the bath fluid contained 75 mM K+ and 75 mM Rb+, but not (in the same membrane patches) when 150 mM Rb+ and no K+ was present. It is concluded that the large voltage- and Ca2+-activated K+ channel has an extremely low Rb+ conductance. It is possible, however, that the permeability for Rb+ may be about the same as for K+. The voltage-insensitive Ca2+-activated cation channel does not discriminate between K+ and Rb+.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00584336

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