乙酰胆碱对蟾蜍背根神经节神经元膜电位的影响及离子机制

在离体灌流的蟾蜍背根神经节(DRG)标本上,用微电极进行胞内记录。在73个神经元中,依神经纤维的传导速度将神经元分为 A 型及 C 型,其中 A 型细胞67个,C 型6个,静息膜电位为-67.5±1.3mV((?)±SE)。当加4×10~(-4)—6×10~(-4)mol/L 乙酰胆碱(ACh),可观察到如下四种膜电位变化:1.超极化:幅值9.1±3.0mV((?)±SE,n=23);(2)去极化:幅值12.9±2.2mV((?)+SE,n=20);(3)双相反应(n=24):先超极化,后去极化,超极化幅值8.0±2.4mV((?)+SE),去极化幅值10.9±3.1mV((?)±SE);(4)无反应(n=6)。用阿托品(1.3×10~(-5)mol/L,n=23),或同时应用筒箭毒与六甲双铵(浓度均为1.4×10~(-5)mol/L,n=8)灌流,能分别阻断 ACh 引起的膜的超极化或去极化。ACh 引起超极化反应时膜电导平均增加13.8%,翻转电位值大约-96mV。四乙铵(TEA,20mmol/L)能使 ACh 的去极化幅值增加48.2±3.2%((?)±SE,n=6),超极化幅值减小79.4±4.3%((?)±SE,n=8)。MnCl_2(4mmol/L)使 ACh 的去极化及超极化幅值分别减小54.2±7.2%((?)±SE,n=5)及69.2±6.4%((?)±SE,n=14)。以上结果提示:ACh 引起的 DRG 神经细胞膜去极化反应由 N 型乙酰胆碱受体介导,而超极化反应由 Μ 型乙酰胆碱受体介导,前者可能包含了多种离子电导的改变,后者则可能与钾电导增加有关。     

去甲肾上腺素引起蟾蜍背根神经节神经细胞膜电位变化的离子机制

本文应用细胞内记录方法,对去甲肾上腺素(NA)引起蟾蜍背根神经节(DRG)神经细胞膜电位去极化或超极化反应时的膜电导及翻转电位值进行了测量,并观察了钾和钙离子通道阻断剂灌流DRG对NA引起膜电位反应的影响。当NA引起去极化反应时,15个细胞的膜电导减小32.6％。少数细胞膜电导开始增加,继而减小(n=4)。NA超极化反应时膜电导增加13.2％(n=8)。NA去极化反应的翻转电位值为-88.5±0.9mV((?)±SE,n=4),NA超极化反应在膜电位处于-89至-92mV时消失。 钾通道阻断剂四乙铵可使NA去极化幅值增加73.7±11.9％((?)±SE,n=7),并使NA超极化幅值减小40.5％(n=4)。细胞内注入氯化铯使苯肾上腺素去极化幅值增加34.5％(n=4)。钙通道阻断剂氯化锰使NA去极化及超极化反应分别减小50.5±9.9％((?)±SE,n=10)和89.5±4.9％((?)±SE,n=7)。结果提示,NA引起DRG神经细胞膜电位的去极化或超极化反应,可能与膜的钾及钙通道活动的改变有关。     

Electrophysiological studies on the cultured cells obtained from transplantable pancreatic carcinoma in Syrian golden hamsters

A pancreatic ductal carcinoma was established as a transplantable tumor line in an inbred strain of Syrian golden hamsters. Intracellular recordings of membrane potentials and input resistance were made from cultured cells obtained from the transplanted tumors using indwelling glass microelectrode. The mean value of the resting membrane potential was -46.5 +/- 1.8 mV (S.E.) (n = 13), while the mean resting input resistance was 21.2 +/- 4.3 M omega (S.E.) (N = 13). Dibutyryl cyclic AMP (2 X 10(-3)M) caused a marked hyperpolarization of about 30 mV accompanied by a reduction of input resistance. The transplantable tumor and its cultured cell line developed in this study have demonstrated their effectiveness as a reliable experimental model for use in pancreatic cancer research.     

Membrane potential of rat calvaria bone cells: dependence on temperature

The membrane potentials of bone cells derived from calvaria of new born rats was shown to be strongly dependent on temperature. When we lowered the temperature from 36 degrees C to 26 degrees C, cells with spontaneous resting membrane potentials (MP) of -80 to -50 mV depolarized (mean amplitude 8 mV; n = 33), and the membrane resistance increased by approximately 80% (n = 20). The temperature response depended on the actual MP, the reversal potential being in the range of -80 to -90 mV. With the application of ouabain (0.1-1 mmol/liter; n = 12), cells depolarized. Simultaneously, the reversal potential of the temperature response was shifted towards more positive values and approached the actual MP level of the cells. Consequently, the depolarization amplitudes induced by lowering temperature were reduced at spontaneous MP levels. The rise of the membrane resistance during cooling was unaffected. When the extracellular chloride concentration was reduced from 133 to 9 mmol/liter, temperature-dependent depolarizations persisted at spontaneous MP values (n = 5). The findings indicate that the marked effects of temperature changes on the MP of bone-derived cells are mainly determined by changes of the potassium conductance.     

Change in the electrophysiological parameters of rat oocytes maturing in vivo

The membrane potential (MP) and input membrane resistance (R) were measured in the immature (1) and mature ovulated (2) rat eggs. The population 1 is homogeneous enough: in 78.3% of all oocytes MP equaled --18 +/- 0.3 mV and R = 3 +/- 0.6 mO; 21.7% of cells had MP = --2 +/- 0.9 MV and R = 3.5 +/- 0.6 mO. The population 2 was divided by the indices under study into 4 groups. The respective values of MP and R in each of 4 groupd 5.5 +/- 0.5 mO, c) --15 +/- 0.6 mV and 7 +/- 1.0 mO, d) --3 +/- 0.4 mV and 9 +/- 0.5 mO. A suggestion is put forward that MP and R of the oocytes change with respect to the maturation stage.     

The Resting Potential of Mouse Leydig Cells: Role of an Electrogenic Na+/K+ Pump

Resting potentials (Vm) were measured in mouse Leydig cells, using the whole-cell patch-clamp technique. In contrast to conventional microelectrode measurements, where a biphasic potential was observed, we recorded a stable Vm around -32.2 +/- 1.2 mV (mean +/- SEM, n = 159), at 25 degrees C, and an input resistance larger than 2.7 x 109 W. Although Vm is sensitive to changes in the extracellular concentrations of potassium and chloride, the relationship between Vm and these ions' concentrations cannot be described by either the Goldman-Hodgkin-Katz or the Nernst equation. Perifusing cells with potassium-free solution or 10?3 M ouabain induced a marked depolarization averaging 20.1 +/- 3.2 mV (n = 9) and 23.1 +/- 2.8 mV, (n = 7), respectively. Removal of potassium or addition of ouabain with the cell voltage-clamped at its Vm, resulted in an inwardly directed current, due to inhibition of the Na+K+ATPase. The pump current increased with temperature with a Q10 coefficient of 2.3 and had an average value of -6.5 +/- 0.4 pA (n = 21) at 25 degrees C. Vm also varied strongly with temperature, reaching values as low as -9.2 +/- 1.2 mV (n = 22) at 15 degrees C. Taking the pump current at 25 degrees C and a minimum estimate for the membrane input resistance, we can see that the Na+K+ATPase could directly contribute with 17.7 mV to the Vm of Leydig cells, which is a major fraction of the ?32.2 +/- 1.2 mV (n = 159) observed.     

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

Analysis of membrane potential recordings upon microelectrode impalement of four types of macrophages (cell lines P388D1 and PU5-1.8, cultured mouse peritoneal macrophages, and cultured human monocytes) reveals that these cells have membrane potentials at least two times more negative than sustained potential values (E(s)) frequently reported. Upon microelectrode entry into the cell (P388D1), the recorded potential drops to a peak value (E(p)) (mean -37 mV for 50 cells, range -15 to -70 mV) within 2 ms, after which it decays to a depolarized potential (E(n)) (mean -12 mV) in about 20 ms. Thereafter, the membrane develops one or a series of slow hyperpolarizations before a final sustained membrane potential (E(s)) (mean -14 mV, range -5 to -40) is established. The mean value of the peak of the first hyperpolarization (E(h)) is -30 mV (range -10 to -55 mV). The initial fast peak transient, measured upon microelectrode entry, was first described and analyzed by Lassen et al. (Lassen, U.V., A.M. T. Nielson, L. Pape, and L. O. Simonsen, 1971, J. Membr. Biol. 6:269-288 for other change in the membrane potential from its real value before impalement to a sustained depolarized value. This was shown to be true for macrophages by two-electrode impalements of single cells. Values of E(p), E(n), E(h), E(s), and membrane resistance (R(m)) measured for the other macrophages were similar to those of P388D1. From these results we conclude that E(p) is a better estimate of the true membrane potential of macrophages than E(s), and that the slow hyperpolarizations upon impalement should be regarded as transient repolarizations back to the original membrane potentials. Thus, analysis of the initial fast impalement transient can be a valuable aid in the estimation of the membrane potential of various sorts of small isolated cells by microelectrodes.     

Transmembrane electrical characteristics of cultured human skeletal muscle cells

Skeletal muscle explants from normal subjects were established from biopsy material on collagen. Cellular outgrowth appeared within 3-4 days, and fusion of myoblasts was observed in 5-10 days. Multinucleated myotubes were impaled under high optical magnification, at 37 degrees C, with conventional glass microelectrodes. The mean resting potential was -44.4 mV +/- 2.4 (n = 399); -33 +/- 2.3 mV at 9 days (n = 10) vs -48 +/- 2.5 mV (n = 15) at 27 days. The average input resistance (Rin) was 9.7 M omega (n = 83). Action potentials could be elicited by electrical stimulation and had a mean amplitude of 55.9 +/- 2.1 mV with a mean maximum rate of rise (Vmax) of 72.1 +/- 7.5 V/s. The mean overshoot was 13.9 +/- 2.3 mV, and the action potential duration determined at 50% of repolarization (APD50) was 8.0 msec (n = 7). The resting membrane potential showed a depolarization of 23 mV/decade for extracellular potassium ion concentration ([K]o) between 4.5-100 mM. Thus, we have established the normal resting potential and maximum rate of rise of the action potential for human myotubes in culture. We have shown that the values for these are less than those previously reported in cultured avian and rodent cells. In addition, we have shown that the response in our system of the resting potential to change in extracellular potassium concentration is blunted compared to studies using isolated muscle, suggesting an increase in ratio of sodium to potassium permeability. Cultured human muscle cells depolarized in the presence of ouabain.     

Glucose depolarizes villous but not crypt cell apical membrane potential difference: a micropuncture study of crypt-villus heterogeneity in the rat

Brush-border membrane potentials and fractional resistances have been recorded from enterocytes at different points along the crypt-villus axis of rat ileum in vitro. Microelectrode impalements were obtained under visual control and brush-border membrane potentials were higher in crypt than in villous cells (-57 +/- 1.6 against -50 +/- 1.6 mV referred to the mucosal side). Replacing mannitol with D-glucose in the mucosal perfusate resulted in a rise in transmural potential difference (0.5 +/- 0.17 to 1.0 +/- 0.21 mV (n = 37)) and apical membrane potential was depolarized. This occurred consistently only in the upper two-thirds of the villus (-54 +/- 1.7 to -47 +/- 2.3 mV (n = 17)) and not in crypt cells (-56 +/- 2.6 to -57 +/- 2.4 mV (n = 10) or at the crypt-villus junction. The glucose-induced apical membrane depolarization in villous enterocytes was blocked by phlorizin, a competitive inhibitor of sodium-dependent glucose uptake (-50 +/- 2.1 to -53 +/- 2.8 mV (n = 9) in the presence of phlorizin and glucose). Transmural resistance, Rt, and fractional resistance, FR, were unaltered by glucose (61 +/- 3.4 to 61 +/- 3.5 omega X cm2 (n = 50] and (0.60 +/- 0.06 to 0.57 +/- 0.06 (n = 17]. This micro-puncture technique provides direct evidence for functional differentiation along the crypt-villus axis and indicates that active electrogenic accumulation of glucose is confined to villous epithelium.     

An antidiuretic factor in the forest ant: purification and physiological effects on the Malpighian tubules

Formica polyctena antidiuretic factor (FopADF) was purified from a 15% trifluoroacetic acid (TFA) extract of the abdomens of 150,000 worker ants. After solid phase extraction of the crude extract and reversed-phase HPLC on two C(18) columns, an antidiuretic factor was isolated. Tested at a concentration of 1.0 ant-equivalents/μl (ant-eq/μl), the factor reversibly inhibited fluid secretion of isolated Malpighian tubules to 29+/-5% (mean+/-SE, n=24) of the control value. The same concentration of FopADF reversibly depolarized both the basolateral membrane potential (V(bl)), from -21+/-2 mV to -3+/-1 mV (n=5), and the apical membrane potential (V(ap)), from -65+/-5 mV to -20+/-5 mV (n=5). Similar effects on fluid secretion and V(ap) were caused by a TFA extract of the haemolymph of ants with non-secreting tubules. Unfortunately, further purification of FopADF on a C(4) column led to a loss of activity in the fluid secretion assay. This is the first time an endogenous antidiuretic factor acting directly on Malpighian tubules has been partially purified and shown to depolarize the tubule cell membranes.