Estimation of the membrane potential of cultured macrophages from the fast potential transient upon microelectrode entry

İnce, Can; Ypey, DL; Furth, R. van; Verveen, A. A.

doi:10.1083/jcb.96.3.796

Cited by 30 publications

(26 citation statements)

References 29 publications

(32 reference statements)

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“…Giant L cells and giant macrophages were obtained by exposing the two cell lines on day 3 of culture to 20-30 Gy X-irradiation (Whitmore, Till, Gwatkin, Siminovitch & Graham, 1958;Nelson & Peacock, 1973 (Ince, Ypey, Diesselhoff-Den Dulk, Visser, De Vos & Van Furth, 1983a). The experimental set-up and bathing solution were as described elsewhere (Ince et al 1983b). Glass micro-electrodes filled with 4 M-K acetate and with tip resistances ranging (Re) from 100 to 400 MO were used.…”

Section: Methodsmentioning

confidence: 99%

“…Cells were cultured on 24 mm glass cover-slips in culture medium at 37 0C in a 5 % C02 humidified atmosphere, as described elsewhere (Ince et al 1983b). L cells (a mouse fibroblast cell line), were used for experiments after 3-5 days of culture.…”

Section: Methodsmentioning

confidence: 99%

“…None the less, properties of L cells, such as phagocytosis (Okada, Tsuchiya, Yada, Yano & Yawo, 1981), cell motility (Tsuchiya, Okada, Yano, Inouye, Saski & Doida, 1981 a), and pinocytosis (Tsuchiya, Okada, Yano, Murai, Miyahara & Tanaka, 1981 b) have been associated with such hyperpolarizations, and in macrophages these hyperpolarizations have been associated with chemotaxis (Gallin & Gallin, 1977) and phagocytosis (Kouri, Noa, Diaz & Niubo, 1980). Recently, we analysed the fast potential transient seen after impalement (Lassen, Nielson, Pape & Simonsen, 1971) into macrophages and found (Ince, Ypey, Van Furth & Verveen, 1983b) that penetratation by a microelectrode induces a leakage conductance across the membrane and that the membrane potentials of macrophages (mean -40 mV) are two to three times more negative than has generally been thought on the basis of sustained potential measurements (-15 to -25 mV). In the present study we measured fast potential transients upon impalement in L cells and macrophages in order to determine the origin of spontaneous hyperpolarizations and to assess the effect of the leakage conductance induced by the micro-electrode on membrane potential measurements.…”

Section: Introductionmentioning

confidence: 99%

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Oscillatory hyperpolarizations and resting membrane potentials of mouse fibroblast and macrophage cell lines.

İnce¹,

Leijh²,

Meijer³

et al. 1984

The Journal of Physiology

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SUMMARY1. L cells (a mouse fibroblast cell line) and macrophages have been reported to exhibit slow oscillatory hyperpolarizations and relatively low membrane potentials, when measured with glass micro-electrodes. This paper describes the role of microelectrode-induced leakage in these oscillations for L cells and a mouse macrophage cell line (P388D1).2. Both L cells and macrophages showed fast negative-going peak-shaped potential transients upon micro-electrode entry. This shows that the micro-electrode introduces a leakage conductance across the membrane.3. The peak values of these fast transients were less negative for L cells (-17 mV) than for macrophages (-39 mV), although their sustained resting membrane potentials were about equal (-13 mV). This indicates that the pre-impaled membrane potential of macrophages is more negative than that of L cells.4. Ionophoretic injection of Ca2+ into the P388D1 macrophages showed the existence of a Ca2+-dependent hyperpolarizing conductance presumed to be involved in the oscillatory hyperpolarizations of L cells and macrophages.5. Cells increased in size by X-ray irradiation to reduce membrane input resistances were still found to be susceptible to micro-electrode-induced leakage.6. Impalement transients upon entry of a second electrode during a hyperpolarization evoked by a first electrode, were often step-shaped instead of peak-shaped due to the high membrane conductance associated with hyperpolarization.7. Since peak-shaped impalement transients were always seen with the first impalement both in oscillating and non-oscillating cells, oscillatory hyperpolarizations cannot be regarded as spontaneously occurring in the unperturbed cells but are induced by micro-electrode penetration.8. Since the hyperpolarizing response can be evoked by ionophoretic injection of Ca2+, and oscillatory as well as single hyperpolarizing responses are absent in a Ca2+-free medium, it is concluded that the Ca2+ needed intracellularly to activate the hyperpolarizing responses enters the cell via the leakage pathway introduced by the measuring electrode.t To whom correspondence should be addressed.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Oscillatory hyperpolarizations and resting membrane potentials of mouse fibroblast and macrophage cell lines.

İnce¹,

Leijh²,

Meijer³

et al. 1984

The Journal of Physiology

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“…Cultured macrophages derived from human monocytes have an excitable membrane (1) and changes in membrane potential are among the earliest detectable events upon stimulation of phagocytosis (2). So far, direct membrane potential or current measurements have been made with the use of intracellular glass microelectrodes (1,3,4). This type of electrode, however, seriously hampers the study of ionic currents in small cells such as macrophages (3).…”

mentioning

confidence: 99%

“…So far, direct membrane potential or current measurements have been made with the use of intracellular glass microelectrodes (1,3,4). This type of electrode, however, seriously hampers the study of ionic currents in small cells such as macrophages (3). Therefore, we have applied the patch clamp technique (5), which allows high resolution of ionic currents in small cells (diameter, <20 jtm) up to high frequencies (<10 kHz).…”

mentioning

confidence: 99%

Development of a delayed outward-rectifying K+ conductance in cultured mouse peritoneal macrophages.

Ypey¹,

Clapham²

1984

Proc. Natl. Acad. Sci. U.S.A.

119

100

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Patch clamp techniques were used to study ionic currents in cultured mouse peritoneal macrophages. Whole-cell voltage clamp studies of cells 1-5 hr after isolation showed only a high-resistance linear membrane. After 1 day in culture, 82 of 85 cells studied had developed a voltage-and time-dependent potassium (K+) conductance similar to the delayed outward rectifier in nerve and muscle cells. The current activated when the membrane was depolarized above -50 mV. The sigmoidally rising current rose to a peak at a rate that increased with depolarization. Inactivation proceeded exponentially with a time constant of -450 ms. Recovery from inactivation was slow (r = 12 s). The reversal potentials for varying extracellular K+ concentrations followed the Nernst predictions for a KV-specific channel. The conductance was blocked by extracellular 4-aminopyridine and by intracellular tetraethylammonium chloride, barium, and cesium. Singlechannel K+ currents comprising this net current had a conductance of 16 pS, exhibited bursting behavior, and inactivated with time. No inward currents were ever detected in macrophages cultivated for up to 4 days. Short-term exposure to chemoattractant and transmitter agents failed to activate an inward current. Macrophages may change their membrane electrophysiological properties depending on their state of functional activation. We postulate that the K+ conductance develops prior to depolarizing conductances involved in the macrophage's immunological functions.Ionic membrane currents in macrophages may serve as signals between membrane-ligand interactions and cellular reactions such as phagocytosis of microorganisms. Cultured macrophages derived from human monocytes have an excitable membrane (1) and changes in membrane potential are among the earliest detectable events upon stimulation of phagocytosis (2). So far, direct membrane potential or current measurements have been made with the use of intracellular glass microelectrodes (1,3,4). This type of electrode, however, seriously hampers the study of ionic currents in small cells such as macrophages (3). Therefore, we have applied the patch clamp technique (5), which allows high resolution of ionic currents in small cells (diameter, <20 jtm) up to high frequencies (<10 kHz). We report here that on the first day after isolation, mouse peritoneal macrophages develop an outward-rectifying potassium (Kt) conductance, similar to the delayed rectifier in nerve (6-8) and skeletal muscle membranes (9). The single channels underlying this conductance exhibit a linear current-to-voltage relationship and have a conductance of about 16 pS. Since Nat or Ca2t currents could not be detected in these cells up to 4 days after isolation, we suggest that this conductance is the first conductance expressed in the development of macrophage excitability. MATERIALS AND METHODSResident macrophages were isolated from the peritoneal cavity of male NMRI mice of 20-22 g (Charles River Wiga GmbH, Sulzfeld, Federal Republic of Germany) as described elsewhere ...

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Application of Mathematical Models in the Membrane Electrophysiology of Macrophages

İnce

1986

Lecture Notes in Biomathematics

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Estimation of the membrane potential of cultured macrophages from the fast potential transient upon microelectrode entry

Cited by 30 publications

References 29 publications

Oscillatory hyperpolarizations and resting membrane potentials of mouse fibroblast and macrophage cell lines.

Oscillatory hyperpolarizations and resting membrane potentials of mouse fibroblast and macrophage cell lines.

Development of a delayed outward-rectifying K+ conductance in cultured mouse peritoneal macrophages.

Application of Mathematical Models in the Membrane Electrophysiology of Macrophages

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