Composition of axolemma-enriched fractions isolated from bovine CNS myelinated axons

Axolemma-enriched fractions were isolated from the white matter of bovine corpus callosum via a purified preparation of myelinated axons which were osmotically shocked and fractionated on a discontinuous density gradient. Two membrane fractions of differing density were obtained; both were somewhat enriched over white matter whole homogenate in specific activity of acetylcholinesterase and 5-nucleotidase and maximal binding capacity for saxitoxin. Both membrane fractions contained appreciable amounts of 2, 3-cyclic nucleotide 3-phospho-hydrolase; the specific activity of antimycin-sensitive NAPH-cytochromec reductase and cytochromec oxidase indicated low levels of contamination by microsomal and mitochondrial membrane. The myelin which is concomitantly isolated with the axolemma-enriched fractions has a lipid and protein composition comparable to that of myelin isolated by other procedures. Both axolemma-enriched fractions contain about one half of their dry weight as lipid comprised of approximately 25% cholesterol, 25% galactolipid (cerebrosides and sulfatides in a molar ratio of about 4:1) and 50% phospholipid, mostly choline phosphatides and ethanolamine phospholes in an equimolar ratio. The axolemma fractions are also enriched in ganglioside content relative to the myelin fraction. The polypeptides of the axolemma-enriched fractions range from 20,000 to over 200,000 in molecular weight; the predominant proteins are in the range from 50,000 to 69,000. The most dense axolemma-enriched fraction is over fourfold enriched in glyco-protein content compared with myelin, with at least 10 different molecular-weight classes of glycoproteins as identified by Schiff stain of polyacrylamide gel protein profiles. The differences and similarities in the molecular composition of axolemma-enriched preparations which have been characterized to date are discussed.     

The role of fast and slow potassium currents in electrical activity of amphibian myelinated nerve fibres

The paper reviews the information about the role of fast and slow potassium currents in electrical activity of amphibian myelinated nerve fibres. It demonstrates the importance of discovering of fast and slow potassium currents and their following pharmacological separation (by potassium channels blockers 4-aminopyridine and tetraethylammonium) in investigation of mechanisms of biological potentials generation. The information about the existence of fast and slow potassium channels in the nerve membrane and about the properties of 4-aminopyridine and tetraethylammonium action served as a base for determination the nature of biological potentials and discovering the mechanism of potential-dependent action of 4-aminopyridine that for tens of years suffered from the lack of adequate explanation.     

Effects of MK-771 on the isolated amphibian spinal cord: comparison with thyrotropin-releasing hormone.

Topically applied MK-771 (pyro-2-aminoadipyl-histidyl-thiazolidine-4-carboxamide), a novel thyrotropin-releasing hormone (TRH) analog, was found to be equipotent with TRH in depolarizing the ventral roots of the isolated, hemisected amphibian (Bufo marinus) spinal cord. The 3-methyl-histidyl analog of TRH was approximately 10 times more potent than MK-771 and TRH. MK-771 is known to be equiactive with TRH in their actions on the pituitary gland. Taken together these findings suggest that the previously observed enhanced potency of systemically administered MK-771 over TRH in in vivo central nervous system (CNS) test paradigms is not likely to be due to a difference in the agonist requirements of CNS as compared with pituitary receptors for TRH.     

Development of a high-affinity GABA uptake system in embryonic amphibian spinal neurons

High-affinity uptake systems for amino acid neurotransmitter precursors have been highly correlated with the use of the particular amino acid or its derivative as a transmitter. We have found interneurons in the Xenopus embryo spinal cord which accumulate GABA by a high-affinity uptake system. They originate near the end of gastrulation and their ability to accumulate GABA first appears at the early tail bud stage. By position and appearance they are comparable to some of the embryonic interneurons described by A. Roberts and J. D. W. Clarke (1982, Phil. Trans. R. Soc. London Ser. B 296, 195-212). GABA-accumulating neurons also develop in dissociated cell cultures made from the presumptive spinal cord of neural plate stage Xenopus embryos. GABA accumulation in cultured neurons, as in cells in vivo, occurs via a high-affinity uptake system; GABA-accumulating cells have the same time of origin as the cells in vivo, and the ability to accumulate GABA in the population of cultured neurons appears at a time equivalent to that observed in intact sibling embryos. Thus it seems likely that the population of GABA-accumulating neurons developing in cell culture corresponds to the GABA-accumulating interneurons in vivo. The development of these neurons in dissociated cell cultures permits perturbation experiments that would be difficult to perform in vivo. We have examined the development of high-affinity GABA uptake in conditions that permit no electrical impulse activity in the cultures. The onset and extent of development of GABA accumulation in the neuronal population are normal under these conditions.     

Aza-THIP and related analogues of THIP as GABA C antagonists

The potency of a series of eight compounds structurally related with 4,5,6,7-tetrahydroisoxazolo[5,4-c]pyridin-3-ol (THIP), a potent GABA(A) partial agonist exhibiting GABA(C) rho(1) antagonist effect (K(i)=25 microM), was determined electrophysiologically using homomeric human GABA(C) rho(1) receptors expressed in Xenopus oocytes. Protolytic properties (pK(a) values for the acidic bioisosteric groups) and the presence of steric bulk in the molecules appear to be structural parameters of importance for blockade of the GABA(C) rho(1) receptor. Within this series of moderately potent GABA(C) antagonists, only 4,5,6,7-tetrahydropyrazolo[5,4-c]pyridin-3-ol (Aza-THIP) does not interact detectably with GABA(A) receptors, and Aza-THIP has the potential of being a useful tool for molecular and behavioural pharmacological studies.     

Effects of N-alcohols on potassium conductance in squid giant axons

The effect of bath application of several short chain N-alcohols on voltage-dependent potassium conductance has been studied in intact giant axons of Loligo forbesi under voltage-clamp conditions. All tested alcohols (methanol, ethanol, propanol, butanol, heptanol and octanol) were found to depress potassium conductance only at concentrations much larger than those necessary to reduce sodium conductance. The efficacy of the different molecules was correlated with the carbon-chain length. In all cases the effects were found to be at least partly reversible. Low concentrations of propanol (100 mM) or heptanol (1 mM) were found to increase potassium conductance whereas higher concentrations had the usual depressing effect. The two alcohols were found to induce a slow inactivation of the potassium conductance. A detailed analysis of the time course of the turning-on of the potassium current for various pulse potentials in the presence of TTX revealed that, for membrane potential values more positive than -20 mV, the time constant of activation was reduced in the presence of propanol or heptanol. The delay which separates the change in potential and the turning-on of the potassium current, which was systematically analysed for different pulse and prepulse potential values, was increased by the two alcohols, the curve relating this delay to prepulse potential being shifted towards larger (positive) delays. This high degree of complexity in the effects on potassium conductance suggests that the alcohol molecules modify several more or less independent mechanisms associated with the turning-on of the potassium current.     

Effects of mono- and multi-valent cations on the inward-rectifying potassium channel in isolated protoplasts from maize roots

Transport properties mediated by ionic channels were studied by the patch-clamp technique in protoplasts from cortical parenchyma cells of maize roots (CPMR). While outward currents could be seen only occasionally, macroscopic voltage- and time-dependent potassium-selective inward currents (I_K+in) were frequently observed in the whole-cell configuration. These currents increased continuously as a function of K⁺ concentration (in the range 3 – 200 mm) and the slow-saturating macroscopic chord-conductance was fitted by a Michaelis-Menten function with K_m = 195 ± 39 mm. Other ions, like sodium and lithium, did not permeate at all through the maize root inward-channel, or like ammonium (P_NH4+/ P_K+ = 0.16 0.25) and rubidium (P_Rb+/P_K+≈ 0.10) displayed a very low permeability ratio. Up to 5 mm Rb⁺ did not induce any inhibition of the K⁺ inward current, whereas submillimolar concentrations of Cs⁺ were sufficient to block, in a voltage-dependent manner, the inward currents. A decrease of the external potassium concentration favoured Cs⁺ inhibition (K_m = 89 ± 6 μm and 26 ± 2 μm in 200 and 100 mm KCl, respectively). The potassium inward-currents were reversibly and consistently inhibited by submillimolar external concentrations of the metal ions Ni²⁺, Zn²⁺ and Co²⁺, while 1 mm La³⁺ only slightly decreased (≈10%) both the single channel conductance (9.2 ± 1.2 pS in 100 mm potassium) and the macroscopic current. In contrast to the case with Cs⁺, inhibition induced by other metal ions did not show any voltage dependence. These results suggest that, as with animal potassium channels, the inward channel of maize-root cortical cells has a narrow pore of permeation and metal ions decrease the K⁺ current, possibly by acting on binding sites located outside the pore. Received: 21 February 1997 / Accepted: 27 May 1997     

Actions of various gastrointestinal peptides on the isolated amphibian spinal cord.

The effects of a number of peptides which are found in the gastrointestinal tract have been ascertained on the direct current recorded dorsal and ventral root responses of the isolated hemisected toad spinal cord. Motilin, substance P, bombesin, neurotensin, and thyrotropin releasing hormone had potent depolarizing actions on dorsal root terminals and motoneurons. These substances evoked discernable effects at concentrations as low as 10--7 M, or even lower with motilin. The effects of motilin, neurotensin, and thyrotropin-releasing hormone were greatly reduced or abolished by perfusion of the preparation with tetrodotoxin. Adrenocorticotrophic hormone, secretin, and pancreozymin (cholecystokinin) also depolarized dorsal root terminals and motoneurons. The effects of secretin and cholecystokinin were not abolished by tetrodotoxin. Leu- and Met-enkephalin had weak hyperpolarizing actions on the dorsal and ventral root potentials of repetitively stimulated preparations. Gastrin, gastric inhibitory peptide, glucagon, and somatostatin had no apparent effects on the responses of the preparation. Angiotensin and vasopressin both had rather weak depolarizing effects on the dorsal and ventral roots.     

Composition, assembly, and maintenance of excitable membrane domains in myelinated axons

Neurons have many specialized membrane domains with diverse functions responsible for receiving, integrating, and transmitting electrical signals between cells in a circuit. Both the locations and protein compositions of these domains defines their functions. In axons, two of the most important membrane domains are the axon initial segment and the nodes of Ranvier. Proper assembly and maintenance of these domains is necessary for action potential generation and propagation, and the overall function of the neuron.     

Development of the axon membrane during differentiation of myelinated fibres in spinal nerve roots

Previous studies by a number of workers have shown that the axon membrane in normal mature myelinated fibres is highly differentiated, with the nodal axolemma exhibiting characteristics different to those of the internodal axolemma. However, the development of this axolemmal heterogeneity has not been previously explored. In the present study we used cytochemical methods to examine the development of nodal axolemma during the differentiation of myelinated fibres in rat spinal roots. The staining properties characteristic of normal nodal membrane appear in the axon, at gaps between Schwann cells, before the development of mature compact myelin or well defined paranodal axon--Schwann cell specializations close to the region of nodal axolemmal differentiation. These results are consistent with the hypothesis that the axon membrane differentiates into nodal and internodal regions before, or early in the process of, myelination, and suggest that the differentiation of the axon membrane may provide a signal demarcating the region to be covered by the myelin-forming cell.     

Effects of some potassium channel blockers on the ionic currents in myelinated nerve

The effects of some potassium channel blockers on the ionic currents and on the so-called K(+)-depolarization in intact myelinated nerve fibres were studied. 4-AP, and in particular, Flaxedil, proved to be selective K(+)-current blockers. However, TEA, a crown ether (DCH18C6), a longchained triethylammonium compound (C10-TriEA), capsaicin, and the extract from the medicinal herb Ruta graveolens proved not to be selective K(+)-current blockers; they all block Na(+)-currents as well, although to a lesser extent. The sodium inactivation curve did not change under TEA and Flaxedil but was shifted on the potential axis in negative direction by DCH18C6, 4-AP, capsaicin and the Ruta extract whereas C10-TriEA caused a shift of both sodium inactivation and activation parameters in positive direction. Regarding to the kinetics of the persisting K(+)-current fraction, two different kinds of blockade were found: 1. Unchanged K(+)-kinetic which is typical for the effects of TEA, 4-AP, Flaxedil, and C10-TriEA. 2. Clearly changed K(+)-kinetic, characterized by K(+)-transients; which is typical for the effects of capsaicin and in particular, for those of DCH18C6 and of the Ruta extract. The possibly different modes of action of both groups of blockers are discussed in terms of current models for the action of potassium channel blockers.     

Effects of external cesium and rubidium on outward potassium currents in squid axons

We have studied the effects of external cesium and rubidium on potassium conductance of voltage clamped squid axons over a broad range of concentrations of these ions relative to the external potassium concentration. Our primary novel finding concerning cesium is that relatively large concentrations of this ion are able to block a small, but statistically significant fraction of outward potassium current for potentials less than approximately 50 mV positive to reversal potential. This effect is relieved at more positive potentials. We have also found that external rubidium blocks outward current with a qualitatively similar voltage dependence. This effect is more readily apparent than the cesium blockade, occurring even for concentrations less than that of external potassium. Rubidium also has a blocking effect on inward current, which is relieved for potentials more than 20-40 mV negative to reversal, thereby allowing both potassium and rubidium ions to cross the membrane. We have described these results with a single-file diffusion model of ion permeation through potassium channels. The model analysis suggests that both rubidium and cesium ions exert their blocking effects at the innermost site of a two-site channel, and that rubidium competes with potassium ions for entry into the channel more effectively than does cesium under comparable conditions.     

Microtubules in myelinated and unmyelinated axons of rat sciatic nerve

Summary Tannic acid in glutaraldehyde was used to stain microtubules in myelinated and unmyelinated axons of rat sciatic nerve. In the majority of areas the tannic acid failed to penetrate the unmyelinated axons whilst penetrating neighbouring myelinated axons, suggesting a difference in the ability of the two types of nerves to exclude tannic acid. Where tannic acid had penetrated the unmyelinated axons the 13 protofilament substructure and size of the microtubules appeared identical to those seen in the myelinated axons.     

The role of slow potassium current in phenomena of voltage-dependent action of 4-aminopyridine in amphibian myelinated nerve fibres

The mechanism underlying the voltage-dependent action of 4-aminopyridine (4-AP) is investigated in experiments on amphibian myelinated nerve fibres (Rana ridibunda Pallas) by way of extracellular recording of electrical activity and using activators of potassium current (potassium-free solution and nitric oxide NO) and inhibitors of sodium current (tetrodotoxin). Measurement of action potential (AP) areas was used to evaluate the extent of general membrane depolarization during the activity of nerve fibres. Tetrodotoxin-induced decrease in general membrane depolarization (when the action potential amplitude was reduced by less than 20%) leads to an increase in the duration of depolarizing after-potential (DAP). This supports the dependence of time course of DAP in the presence of 4-AP on ratio of fast and slow potassium channels. In the absence of 4-AP, potassium-free solution and NO increase the potassium current through fast potassium channels (decreasing AP duration, reducing DAP and sometimes producing fast hyperpolarizing after-potential (HAP) after shortened AP), and in the presence of 4-AP these activators increase potassium current through unblocked slow potassium channels (making the development of slow HAP induced by 4-AP more rapid). The increase of slow HAP induced by 4-AP under the influence of potassium-free solution with NO supports the idea that slow HAP is due to activation of slow potassium channels and argues against the notion of removal of block of fast potassium channels. All analyzed phenomena of voltage-dependent action of 4-AP in amphibian myelinated nerve fibers can be accounted for by the activation of slow potassium current produced by membrane depolarization and a decrease of the amount of fast potassium channels involved in the membrane repolarization.     

Rapid conduction and the evolution of giant axons and myelinated fibers

Nervous systems have evolved two basic mechanisms for increasing the conduction speed of the electrical impulse. The first is through axon gigantism: using axons several times larger in diameter than the norm for other large axons, as for example in the well-known case of the squid giant axon. The second is through encasing axons in helical or concentrically wrapped multilamellar sheets of insulating plasma membrane--the myelin sheath. Each mechanism, alone or in combination, is employed in nervous systems of many taxa, both vertebrate and invertebrate. Myelin is a unique way to increase conduction speeds along axons of relatively small caliber. It seems to have arisen independently in evolution several times in vertebrates, annelids and crustacea. Myelinated nerves, regardless of their source, have in common a multilamellar membrane wrapping, and long myelinated segments interspersed with 'nodal' loci where the myelin terminates and the nerve impulse propagates along the axon by 'saltatory' conduction. For all of the differences in detail among the morphologies and biochemistries of the sheath in the different myelinated animal classes, the function is remarkably universal.     

Effects of barium on isolated frog spinal cord

The effects of Ba2+ were studied in vitro on the isolated frog spinal cord. Ba2+ (25 microM-5 mM) caused a concentration-dependent depolarization of ventral (VR) and dorsal (DR) roots. TTX and Mg2+ substantially reduced the depolarization suggesting that interneuronal effects were involved. Ba2+ (25-500 microM) markedly increased the frequency and duration of spontaneous VR and DR potentials and substantially enhanced the duration (and frequently the amplitude) of VR and DR potentials evoked by DR stimulation. Higher concentrations of Ba2+ (1-5 mM) reduced both spontaneous and evoked potentials. Ba2+ (25-500 microM) enhanced the amount of K+ released by a DR volley and by application of L-glutamate and L-aspartate. The cation reduced VR and DR root depolarizations produced by elevated [K+]0. VR potentials induced by L-glutamate, L-aspartate, GABA and glycine and DR depolarizations caused by GABA were reduced by Ba2+. These results show that Ba2+ has complex actions on reflex transmission, interneuronal activity, the postsynaptic actions of excitatory and inhibitory amino acids and the evoked release of K+.