Enhancement of low-threshold A-current of the neuronal membrane by vinpocetine

A low-threshold fast inactivating K+ current (I(Alth)) was recorded in isolated land snail neurons using the two-microelectrode voltage clamp method. A nootropic drug, vinpocetine, applied to the extracellular medium at a concentration of 1-100 microM potentiated I(Alth). The potentiation consisted in a rise of its peak amplitude and an increase of the half-decay time. Vinpocetine did not cause a shift of the steady-state activation and inactivation curves along the potential axis. Dibutyryl cyclic GMP (dcGMP) also increased the peak amplitude but did not change the time of current half-decay. dcAMP did not potentiate I(Alth). The possible role of K+-current potentiation in neuronal membranes in therapy of dementia is discussed.     

Donepezil in a Narrow Concentration Range Augments Control and Impaired by Beta-Amyloid Peptide Hippocampal LTP in NMDAR-Independent Manner

Acetylcholinesterase (AChE) inhibitor donepezil is widely used for the treatment of Alzheimer’s disease (AD). The mechanisms of therapeutic effects of the drug are not well understood. The ability of donepezil to reverse a known pathogenic effect of β-amyloid peptide (Abeta), namely, the impairment of hippocampal long-term potentiation (LTP), was not studied yet. The goal of the present study was to study the influence of donepezil in 0.1–10 μM concentrations on control and Abeta-impaired hippocampal LTP. Possible involvement of N-methyl-d-aspartate receptors (NMDARs) into mechanisms of donepezil action was also studied. LTP of population spike (PS) was studied in the CA1 region of rat hippocampal slices. Change of LTP by donepezil treatment had a bell-shaped dose–response curve. The drug in concentrations of 0.1 and 1 μM did not change LTP while in concentration of 0.5 μM significantly increased it, and in concentration of 5 and 10 μM suppressed LTP partially or completely. Abeta (200 nM) markedly suppressed LTP. Addition of 0.1, 0.5 or 1 μM donepezil to Abeta solution caused a restoration of LTP. N-methyl-d-aspartate (NMDA) currents were studied in acutely isolated pyramidal neurons from CA1 region of rat hippocampus. Neither Abeta, nor 0.5 μM donepezil were found to change NMDA currents, while 10 μM donepezil rapidly and reversibly depressed it. Results suggest that donepezil augments control and impaired by Abeta hippocampal LTP in NMDAR-independent manner. In general, our findings extend the understanding of mechanisms of therapeutic action of donepezil, especially at an early stage of AD, and maybe taken into account while considering the possibility of donepezil overdose.     

Memory and potassium channels

The K(+)-channels of the surface membrane play a crucial role in the generation of electrical activity of a neuron. There is a large diversity of the K(+)-channels that depends on a great number (over 200) of genes encoding channels proteins. An evolutionary conservation of channel's proteins is determined. The K(+)-channels were found to have a great importance in the memory processes. It was shown on different model systems that K(+)-current of the surface membrane decreases during the learning. The antagonists of K(+)-channels were found to improve the learning and memory. It was revealed in electrophysiological experiments that K(+)-channels antagonists can either themselves induce a long-term synaptic potentiation or intensify the synaptic potentiation induced by a tetanization. The disfunction of K(+)-channels is believed to be an important link in the mechanisms of memory disturbances. In animal mutants with K(+)-channels disfunction, learning and memory are deficient. In behavioral experiments, the use of K(+)-channels openers make the learning worse. Amnesia caused by cerebral ischemia is explained by strong activity of K(+)-channels which not only inhibits neuronal excitement but also causes neurodegeneration. The question on the K(+)-channels involvement into pathophysiology of Alzheimer's disease is discussed. Neurotoxic peptide beta-amyloid, which is supposed to be involved into mechanisms of Alzheimer's disease, modulates K(+)-channels function. The effect of beta-amyloid depends on the subtype of K(+)-channels: A-channels are inhibited, and KDR-channels, on the contrary, become stronger. The effect of the cognitive enhancers (vinpocetine, piracetam, tacrine, linopirdine) on K(+)-current also depends on the subtype of K(+)-channels. Slow-inactivating K(+)-currents (IDR, IK(Ca), IM) are inhibited in the presence of these drugs, while fast-in-activating K(+)-current (A-current) remains unchanged or even increases.     

The Binding of Donepezil with External Mouth of K+-Channels of Molluscan Neurons

Earlier, we have shown a strong inhibitory effect of donepezil on K⁺-current of molluscan neurons (Solntseva et al., Comp Biochem Physiol 144, 319–326, 2007). In the present work, a possible interaction of donepezil with the external mouth of the channel was examined using, as a tool, tetraethylammonium (TEA), a classical antagonist of potassium channels. Experiments were conducted in isolated neurons of snail Helix aspersa using the two-microelectrode voltage-clamp technique. A high-threshold slow-inactivating K⁺-current involving Ca²⁺-dependent (I _C) and Ca²⁺-independent (I _K) components was recorded. The I _C was estimated at 30 mV, and I _K at 100 mV. The IC₅₀ values for blocking effect of donepezil on I _C varied from 5.0 to 8.9 μM in different cells. Corresponding values for I _K varied from 4.9 to 9.9 μM. The IC₅₀ values for blocking effect of TEA on I _C lied in the range of 200 to 910 μM, and on I _K lied in the range of 100 to 990 μM. The comparison of the effects of donepezil and TEA on the same cells revealed significant correlation between IC₅₀ values of these effects. The value of Spearman coefficient of correlation (r) was 0.77 for I _C (P < 0.05), and 0.82 for I _K (P < 0.05). In the presence of TEA, the effect of donepezil, both on I _C and I _K, appears significantly weaker than in control solution. Dose–response curves of donepezil effect both on I _C and I _K were shifted right along horizontal axis when donepezil was applied in combination with TEA. Results suggest that TEA interferes with donepezil and precludes the occupation by donepezil of its own site. We suppose that the site for donepezil is situated near the TEA site with possible overlap.     

Interaction of galantamine with ionic channels in molluscan neurons

Galantamine is widely used for the treatment of Alzheimer’s disease. According to the generally accepted viewpoint, its therapeutic effect is based on inhibition of acetylcholinesterase (AChE) and potentiation of nicotinic receptors. Alternative molecular targets for galanatamine, namely, voltage-gated Ca²⁺ and K⁺ channels of the neuronal membrane, are also widely discussed in the current literature. The present study is devoted to the analysis of effects of galantamine on high-threshold Ca²⁺ currents (I _Ca) and three different kinds of highthreshold K⁺ current, viz.: Ca²⁺-dependent K⁺ current (I _C), delayed rectifier (I _DR), and fast-inactivating K₊ current (I _Adepol). Experiments were conducted on molluscan neurons with the help of two-microelectrode voltageclamp technique. It was found that galantamine caused a fast, reversible and dose-dependent suppression of all types of high-threshold ionic currents. The maximal blocking effect of the alkaloid for I _Ca, I _C, and I _DR, was 100%, while for I Adepol the maximal suppression was only 60%. The mean values of IC ₅₀ for I _C, I _DR, I _Adepol, and I _Ca were 109, 237, 66, and 515 μ M, respectively, i.e., substantially higher than the corresponding values for the alkaloid-induced inhibition of AChE and potentiation of nicotinic receptors. It is concluded that the blockade of Ca₂₊ and K₊ channels has little or no contribution to the therapeutic activity of galantamine.     

Donepezil is a strong antagonist of voltage-gated calcium and potassium channels in molluscan neurons

Donepezil is an acetylcholinesterase inhibitor used in Alzheimer's disease therapy. The neuroprotective effect of donepezil has been demonstrated in a number of different models of neurodegeneration including beta-amyloid toxicity. Since the mechanisms of neurodegeneration involve the activation of both Ca(2+)- and K(+)-channels, the study of donepezil action on voltage-gated ionic currents looked advisable. In the present study, the action of donepezil on voltage-gated Ca(2+)- and K(+)-channels was investigated on isolated neurons of the edible snail (Helix pomatia) using the two-microelectrodes voltage-clamp technique. Donepezil rapidly and reversibly inhibited voltage activated Ca(2+)-current (I(Ca)) (IC(50)=7.9 microM) and three types of high threshold K(+)-current: Ca(2+)-dependent K(+)-current (I(C)) (IC(50)=6.4 microM), delayed rectifier K(+)-current (I(DR)) (IC(50)=8.0 microM) and fast transient K(+)-current (I(Adepol)) (IC(50)=9.1 microM). The drug caused a dual effect on low-threshold fast transient K(+)-current (I(A)), potentiating it at low (5 microM) concentration, but inhibiting at higher (7 microM and above) concentration. Donepezil also caused a significant hyperpolarizing shift of the voltage-current relationship of I(Ca) (but not of any type of K(+)-current). Results suggest the possible contribution of the blocking effect of donepezil on the voltage-gated Ca(2+)- and K(+)-channels to the neuroprotective effect of the drug.