[Activation of mechanosensitive ion channels in plasma membrane of K562 cells]. / Aktivatsiia mekhanochuvstvitel'nykh ionnykh kanalov v plazmaticheskoi membrane kletok K562.

Patch clamp method in cell-attached configuration was used to search for mechanogated ion channels in plasma membrane of human myeloid leukemia K562 cells. A reversible activation of transmembrane currents in response to negative pressure applied to membrane patch was observed. Four types of mechanosensitive channels were identified in K562 cells: two main types were characterized with conductance values of 16 and 25 pS; while two others, showing higher conductance values (about 35 and 50 pS), were rarely met. In terms of gating, all channels described here could be assigned to the stretch-activated type. No inactivation of mechanosensitive channels at the sustained stimulation was observed. The activation of mechanosensitive channels in K562 cells was not dependent upon the presence of bivalent cations in the extracellular solution.

Miniature Ca2+ channels in excised plasma-membrane patches: activation by IP3.

In the present work, we characterized the receptor properties and the conductive features of the inositol (1,4,5)-trisphosphate (IP3)-activated Ca2+ channels present in excised plasma-membrane patches obtained from mouse macrophages and A431 cells. We found that the receptor properties of the channels tested were similar to those of the IP3 receptor (IP3R) expressed in the endoplasmic reticulum (ER) membrane. These properties include activation by IP3, inhibition by heparin, time-dependent inactivation by high IP3 concentrations, activation by guanosine 5'o-thiotriphosphate and regulation by arachidonic acid. On the other hand, in terms of conductive properties, the channel closely resembles Ca2+-release-activated Ca2+ channels (Icrac). These conductive properties include extremely low conductance (approximately 1 pS), very high selectivity for Ca2+ over K+ (PCa/PK>1000), inactivation by high intracellular Ca2+ concentration and, importantly, strong inward rectification. Notably, the same channel was activated by: (1) agonists in the cell-attached mode of channel recording, and (2) cytosolic IP3 after patch excision. Although the possibility cannot be completely excluded that a novel type of IP3R is expressed exclusively in the plasma membrane, in their entirety our findings suggest that the plasma membrane of mouse macrophages and A431 cells contains Icrac-like Ca2+ channels coupled to an IP3-responsive protein which displays properties similar to those of the IP3R expressed in the ER membrane.

Low-conductance high selective inositol (1,4,5)-trisphosphate activated Ca2+ channels in plasma membrane of A431 carcinoma cells.

In many cells, activation of receptors coupled to PIP2 turnover results in Ca2+ release from the intracellular stores accompanied by Ca2+ influx across the PM. It is not well established yet whether Ca2+ influx is activated by IP3 or by an unknown signal generated upon Ca2+ store depletion. We report here a single-channel study of low-conductance IP3-activated channels of very high selectivity for Ca2+ in the PM of A431 carcinoma cells. The channels are strongly potential dependent and sensitive to [Ca2+]i within the physiological range. The data obtained argues for IP3 acting directly on plasma membrane Ca2+ channels.

[A new type of IP3-sensitive highly selective calcium channels of low conductance in the plasma membrane of carcinoma A 431 cells]. / Novyi tip IP3-chuvstvitel'nykh vysokoselektivnykh kal'tsievykh kanalov nizkoi provodimosti v plazmaticheskoi membrane kletok kartsinomy A 431.

Application of 0.2-15.0 mM inositol 1,4,5-trisphosphate (IP3) to excised plasma membrane patches from A 431 cells induced activity of low conductance channels that were highly selective for Ca2+ and Ba2+. With 100 mM Ca2+ or 105 mM Ba2+, the channel conductance was 1.1 pS for the minor conductance substrate. The dose response curve gave an apparent binding constant of 0.18 microM IP3. The channel open probability displayed a strong potential dependence: it decreased markedly upon depolarization, and the half-maximum value was achieved at 73 mV. The dependence of channel activity on the intracellular free Ca2+ concentration was bell shaped, but markedly different from that reported for endoplasmic IP3 receptor. The same channels were detected in intact cells upon application of calcium mobilizing reagents. The activity induced in cell attached mode disappeared after patch excision but could be resumed by application of IP3. The data obtained argue for IP3 acting directly on plasma membrane Ca2+ channels.

Effect of intracellular calcium on ATP-activated, GTP-dependent calcium channels in rat macrophages.

1. In order to study the effect of intracellular free Ca2+ concentration ([Ca2+]i) on the activity of ATP-activated, GTP-dependent Ca2+ channels in rat macrophages, experiments were performed using the inside-out configuration of the patch-clamp technique. 2. Channel activity was observed in the cell-attached mode when 100 microM ATP was added to the pipette solution containing 105 mM Ba2+, but it disappeared rapidly after patch excision. The activity could be restored by the application of 100 microM GTP or GTP gamma S onto the internal surface of the plasma membrane. 3. The properties of the GTP gamma S-evoked channels are identical to those of channels activated by extracellular application of ATP. The channels exhibited four current sublevels with conductances of about 3.5, 7, 10 and 15 pS when 105 mM Ba2+ was the only permeant cation. The extrapolated reversal potentials were similar for all the sublevels and averaged about +40 mV. 4. Elevation of [Ca2+]i within the range 0.01-1 microM resulted in a decrease in mean inward current. The half-maximal value of the mean current was about 0.08 microM. 5. This decreases in mean current resulted from a redistribution of sublevel occupancies: the 1st sublevel tended to be come more abundant with elevation of [Ca2+]i, while the relative weights of the high-conductance 3rd and 4th sublevels decreased. 6. The open-channel current fell with an increase in [Ca2+]i as quickly as the mean current did, indicating that the sublevel redistribution alone is sufficient to produce the revealed decrease in net inward current. 7. It is concluded that [Ca2+]i elevation does not fix the channel in a closed state but rather decreases the ability of the channel to operate in high-conductance states.

ATP-activated inward current and calcium-permeable channels in rat macrophage plasma membranes.

1. To study mechanisms of receptor-operated Ca2+ influx in non-excitable cells, membrane currents of rat peritoneal macrophages were recorded using whole-cell cell-attached and outside-out configurations of the patch clamp technique. Under whole-cell recording conditions, ATP applied in micromolar concentrations elicited an inward current response when the bath solution contained Ba2+, Ca2+ or Na+ as the only permeant cations. 2. Increasing the Mg2+ concentration had an inhibitory effect on the ATP-induced inward current indicating that the active form of ATP responsible for the cation entry is ATP4-. The nucleotide potency order was ATP > ATP gamma S > ADP. UTP was completely ineffective (n = 19). The data obtained are consistent with the ATP receptor being of the P2Z type. 3. The macrophage plasma membrane was impermeable to Tris+ during the ATP-induced current at ATP4- concentrations varying from 0.07 to 500 microM. At higher concentrations, ATP produced a large inward steady-state current, which could be attributed to membrane permeabilization. 4. Activity of single channels was recorded when ATP was applied to the external surface of the patch membrane both in cell-attached and outside-out experiments. A specific property of the channels appeared to be the existence of at least four conductance sublevels. With 105 mM Ba2+ as the permeant cation, the conductance sublevels were 3.5, 7, 10 and 15 pS. With 10 mM Ca2+ the sublevel conductances were equal to 4, 9, 13 and 17 pS. 5. The unitary conductance estimated from the whole-cell current noise analysis (3.5-4.5 pS for 105 mM Ba2+) was significantly lower than that obtained from single channel measurements at the main (3rd) current level, but it was very close to the conductance of the minimum (1st) level. 6. Extrapolated reversal potential values estimated from current-voltage curves for predominant conductance levels were equal to +40 and +26 mV for 105 mM Ba2+ and 10 mM Ca2+, respectively. The permeability ratios fell in the sequence: PCa:PBa:PK = 71.:29:1. Thus, ATP-activated channels in the macrophage membrane are rather selective for divalent vs. monovalent cations, with the predominant permeability being for Ca2+.

ATP-operated calcium-permeable channels activated via a guanine nucleotide-dependent mechanism in rat macrophages.

1. To elucidate the possible involvement of a G protein in ATP-evoked Ca(2+)-permeable channel activity, membrane currents of rat peritoneal macrophages were recorded using inside-out and cell-attached configurations of the patch clamp technique. 2. In inside-out experiments with a pipette solution containing 105 mM Ba2+, application of 100 microM GTP or GTP gamma S to the internal surface of the membrane elicited a rise in channel activity. This effect was observed in 49% of the patches investigated (n = 69). The mean value of NPo (N, number of open channels; Po, channel open probability) was equal to 0.49 +/- 0.27 (mean +/- S.E.M.; n = 16). The delay in the activity development was 21 +/- 8 s (n = 18) with 200 microM ATP added to the pipette solution and about 4 min (n = 5) without agonist in the pipette. Similar results were obtained with 10 mM Ca2+ as the only permeant cation. 3. Properties of GTP gamma S-evoked channels were identical to those of channels activated by extracellular application of ATP. The channels exhibited at least four conductance sublevels, the 4th one being the least frequent. With 105 mM Ba2+ as a permeant cation, sublevel conductances were 3.5, 7, 10 and 15 pS. Corresponding values for 10 mM Ca2+ were about 4, 9, 13 and 17 pS. Extrapolated reversal potential (Er) values were about +40 and +25 mV for Ba2+ and Ca2+, respectively. 4. The activity of channels with similar characteristics could be induced by the extracellular application of fluoride in cell-attached experiments without any agonist in the pipette solution.(ABSTRACT TRUNCATED AT 250 WORDS)