Gerald Ehrenstein

Electrically gated ionic channels in lipid bilayers

The generation of action potentials in nerve and muscle requires cell membranes with steeply voltage-dependent ionic permeabilities. The voltage-dependent, ion-selective pathways responsible for excitation have been characterized for numerous excitable tissues such as nerve axon, muscle, electric organ, algae and epithelia (Aidley, 1971; Hodgkin, 1964; Cole, 1968). The process of activating ionic pathways by some stimulus, such as a change in membrane potential, is called gating.

Effect of Divalent Cations on Potassium Conductance of Squid Axons: Determination of Surface Charge

Potassium conductance-voltage curves have been determined for a squid axon in high external potassium solution for a wide range of divalent cation concentrations. A decrease in divalent ion concentration shifts the conductance-voltage curve along the voltage axis in the direction of more hyperpolarized voltages by as much as 9 mv for an e-fold change in concentration. When the divalent ion concentration is less than about 5 mM, a further decrease does not cause a significant shift of the conductance-voltage curve. These results can be explained by assuming that on the outer surface of the membrane there is a negative fixed charge which can bind calcium ions, and that the axon is sensitive to the resulting double-layer potential. From our data, the best value for charge density was found to be one electronic charge per 120 square angstroms, and a lower limit to be one electronic charge per 280 square angstroms.

Slow Changes of Potassium Permeability in the Squid Giant Axon

A slow potassium inactivation i.e. decrease of conductance when the inside of the membrane is made more positive with respect to the outside, has been observed for the squid axon. The conductance-potential curve is sigmoid shaped, and the ratio between maximum and minimum potassium conductance is at least 3. The time constant for the change of potassium conductance with potential is independent of the concentration of potassium in the external solution, but dependent upon potential and temperature. At 9 degrees C and at the normal sea water resting potential, the time constant is 11 sec. For lower temperature or more depolarizing potentials, the time constant is greater. The inactivation can be described by modifying the Hodgkin-Huxley equation for potassium current, using one additional parameter. The modified equation is similar in form to the Hodgkin-Huxley equation for sodium current, suggesting that the mechanism for the passive transport of potassium through the axon membrane is similar to that for sodium.

β-amyloid increases choline conductance of PC12 cells: possible mechanism of toxicity in Alzheimer's disease

Abstract When β-amyloid-(1–40) is added to PC12 cells, there is an increase in choline conductance that is proportional to the β-amyloid concentration. If a similar effect occurs in cholinergic brain cells of Alzheimers disease patients, the intracellular choline concentration would be reduced, leading to a decrease in the production of acetylcholine. This could explain the reduced level of acetylcholine that has been found in post-mortem brain tissue of Alzheimers disease patients.

High concentration of inositol 1,4,5-trisphosphate in sea urchin sperm

We measured inositol 1,4,5-trisphosphate (InsP3) content of sea urchin gametes by using a specific protein binding assay, and found that a spermatozoon contains 4 x 10(-19) to 1 x 10(-18) moles of InsP3 before the acrosome reaction. Since the acrosome reaction has previously been shown to increase the InsP3 content of sperm severalfold, our measurement indicates that a spermatozoon contains at least 2 x 10(-18) moles of InsP3 at fertilization, corresponding to a concentration in the spermatozoon of about 1 mM. The threshold for activation of eggs by injection of InsP3 dissolved in a much larger volume of solution has been found to be about 3 x 10(-18) moles, corresponding to a concentration in the injectate of 1 microM. This suggests that sea urchin sperm may contain enough InsP3 to activate eggs. With an electroporation method, we also showed that sperm extract acts on eggs only from inside, consistent with a primary messenger role for InsP3.

β-Amyloid polypeptide increases calcium-uptake in PC12 cells : a possible mechanism for its cellular toxicity in Alzheimer's disease

Calcium-uptake into PC12 cells was measured by incubation with45Ca after the cells were exposed for 24 h to β-amyloid peptide(1–40) at concentrations between 0 and 46 μM. The rate of influx of45Ca into PC12 cells was constant for the first 10 min. For 46 μM β-amyloid peptide(1–40), the rate of influx was about 1,300 ions/s/μm2 and the number of cells decreased significantly. There was no significant decrease in cell number when cells were exposed to β-amyloid in calcium-free medium. These results indicate that β-amyloid increases calcium uptake into PC12 cells, and suggest that the increased uptake is responsible for the toxicity of β-amyloid in PC12 cells.

A model for exocytosis based on the opening of calcium-activated potassium channels in vesicles

It is proposed that the role of calcium in calcium-induced exocytosis is to open Ca-activated K channels present in vesicle membranes. The opening of these channels coupled with anion transport across the vesicle membranes would result in an influx of K and anions, increasing the osmotic pressure of the vesicles. For those vesicles situated very close to the cell plasma membrane, this would lead to fusion with the membrane and exocytosis of the vesicle contents. This model can account for facilitation and other key properties of transmitter release. In addition, the model predicts that vesicles with a higher transmitter content, and hence higher initial osmotic pressure, would be preferentially discharged. The model also predicts that a faster response can be obtained for small vesicles than for large vesicles, providing a rationale as to why neurotransmitters, which must be released quickly, are packaged in small vesicles.

The choline-leakage hypothesis for the loss of acetylcholine in Alzheimer's disease.

We present a hypothesis for the loss of acetylcholine in Alzheimers disease that is based on two recent experimental results: that beta-amyloid causes leakage of choline across cell membranes and that decreased production of acetylcholine increases the production of beta-amyloid. According to the hypothesis, an increase in beta-amyloid concentration caused by proteolysis of the amyloid precursor protein results in an increase in the leakage of choline out of cells. This leads to a reduction in intracellular choline concentration and hence a reduction in acetylcholine production. The reduction in acetylcholine production, in turn, causes an increase in the concentration of beta-amyloid. The resultant positive feedback between decreased acetylcholine and increased beta-amyloid accelerates the loss of acetylcholine. We compare the predictions of the choline-leakage hypothesis with a number of experimental observations. We also approximate it with a pair of ordinary differential equations. The solutions of these equations indicate that the loss of acetylcholine is very sensitive to the initial rate of beta-amyloid production.

Membrane Surface Charge

Publisher Summary Lipids and proteins contain groups that are charged at the appropriate pH. Many biological membranes possess surface charges due to the presence of these lipids and proteins. There is experimental evidence for a surface charge present on both the outer and inner surfaces of the squid giant axon membrane. This chapter illustrates the way this surface charge relates to membrane channel proteins. One method of determining membrane surface charge is to measure the electrophoretic mobility of cells. This approach provides an estimate of the average charge density over the entire cell membrane. Another method utilizes the voltage-dependent properties of membrane ionic channels to provide the estimates of surface charge density near the channels. It is noted that the surface-charge density at ionic channels is considerably larger than the average surface-charge density over the membrane as a whole. The surface-charge density at ionic channels is also considerably larger on the external surface than on the internal surface. These generalizations apply not only to squid axon membranes, but also to a wide variety of other membranes.

Evidence for interactions between batrachotoxin-modified channels in hybrid neuroblastoma cells.

Current records from voltage-clamped membrane patches containing two batrachotoxin-modified sodium channels were analyzed to determine whether these channels are identical and independent. In most two-channel patches, the experimentally observed probabilities that zero, one, or two channels are open differ from the binomial distribution, demonstrating that the two channels are nonidentical or nonindependent or both. From the same current records, we also determined the rate for the transition from two open channels to one open channel and for the transition from one open channel to zero open channels. These data are consistent with closing rates for the two channels that are equal and independent. Both probability and closing rate data can be fit by a model wherein the channels are identical, the closing rates are independent, and the opening rate is greater when the other channel is closed than when it is open. The implications of this model for analyzing noise spectra and current variance are examined.