Action of colchicine on membrane currents and synaptic transmission in Aplysia ganglion cells

Chronic Sustained Hypoxia Leads to Brainstem Tauopathy and Declines the Power of Rhythms in the Ventrolateral Medulla: Shedding Light on a Possible Mechanism

Hypoxia, especially the chronic type, leads to disruptive results in the brain that may contribute to the pathogenesis of some neurodegenerative diseases such as Alzheimer's disease (AD). The ventrolateral medulla (VLM) contains clusters of interneurons, such as the pre-Bötzinger complex (preBötC), that generate the main respiratory rhythm drive. We hypothesized that exposing animals to chronic sustained hypoxia (CSH) might develop tauopathy in the brainstem, consequently changing the rhythmic manifestations of respiratory neurons. In this study, old (20-22 months) and young (2-3 months) male rats were subjected to CSH (10 ± 0.5% O2) for ten consecutive days. Western blotting and immunofluorescence (IF) staining were used to evaluate phosphorylated tau. Mitochondrial membrane potential (MMP or ∆ψm) and reactive oxygen species (ROS) production were measured to assess mitochondrial function. In vivo diaphragm's electromyography (dEMG) and local field potential (LFP) recordings from preBötC were employed to assess the respiratory factors and rhythmic representation of preBötC, respectively. Findings showed that ROS production increased significantly in hypoxic groups, associated with a significant decline in ∆ψm. In addition, tau phosphorylation elevated in the brainstem of hypoxic groups. On the other hand, the power of rhythms declined significantly in the preBötC of hypoxic rats, parallel with changes in the respiratory rate, total respiration time, and expiration time. Moreover, there was a positive and statistically significant correlation between LFP rhythm's power and inspiration time. Our data showed that besides CSH, aging also contributed to mitochondrial dysfunction, tau hyperphosphorylation, LFP rhythms' power decline, and changes in respiratory factors.

Cytoskeletal stability and heat shock-mediated thermoprotection of central pattern generation in Locusta migratoria

Prior exposure to extreme temperatures can induce thermoprotection in migratory locusts, which is important for survival in their natural environment. An important motor activity that needs to be protected is ventilation. The mechanism underlying heat shock is not fully understood, and our goal was to test the idea that cytoskeletal stability is critical for such thermoprotection. Cytoskeletal stabilizers (concanavalin A) and destabilizers (colchicine) were bath-applied in semi-intact locust preparations in both control (C) and pre-treated heat-shocked (3 h, 45 degrees C) animals. We measured parameters of the ventilatory motor pattern during maintained high temperature (43 degrees C) and recorded the times taken for motor pattern generation to fail and then recover on returning to room temperature. We found that concanavalin A mimicked the effects of a prior heat stress in control animals by increasing time to failure and decreasing time to recovery of motor pattern generation. However, colchicine destroyed protection in heat-shocked animals by decreasing time to failure and increasing time to recovery. Our findings confirm that the cytoskeleton has a mechanistic role in preserving neural function at high temperatures, possibly through stabilizing ion channels and other integral membrane proteins (e.g. Na(+)/K(+) ATPase) and their interactions with heat shock proteins.

In vitro modulation of somatic glycine-like immunoreactivity in presumed glycinergic neurons

Previous studies indicate that tuberculoventral and cartwheel cells in the dorsal cochlear nucleus as well as a group of stellate cells in the ventral cochlear nucleus are likely to be glycinergic. To test whether these neurons contain higher levels of free glycine than cells that are probably not glycinergic, immunocytochemical studies with antibodies against glycine conjugates were undertaken on slices of the murine cochlear nuclear complex. Present results show that the cell bodies of all three groups of neurons are immunolabeled. However, the somatic labeling of the tuberculoventral and cartwheel cells can be modulated by experimental conditions. In slices fixed immediately after cutting, many cell bodies in the deep layer of the dorsal cochlear nucleus (DCN), presumably tuberculoventral neurons, are labeled. As a slice is incubated in vitro, cell bodies in the deep layer of the DCN lose their glycine-like immunoreactivity. After 7 hours in vitro, labeled cells are absent in the deep DCN, but the immunoreactivity can be regained by electrically stimulating the auditory nerve for 20 minutes. The loss of immunoreactivity is prevented by electrical stimulation, by axotomy, and by inclusion of 0.8 microM tetrodotoxin, or 1 microM strychnine, or 50 microM colchicine or 50 microM beta-lumicolchicine in the bathing saline. Cartwheel cells retain their immunoreactivity during incubation in vitro without electrical stimulation, but lose it under two conditions. One is following a cut across the ventral cochlear nucleus (VCN) that severs most of their granule cell input, and the other is the inclusion of tetrodotoxin in the bathing saline. The labeling of cell bodies in the ventral cochlear nucleus and of puncta and processes is not changed by any of these experimental manipulations.

Dihydropyridines interact with calcium-independent potassium currents in embryonic mammalian sensory neurons

Early embryonic sensory neurons have two K currents resembling delayed rectifier and transient K currents of mature neurons. However, in contrast to those of adult neurons, the embryonic currents can hardly be separated either by electrophysiological or pharmacological methods, limiting their characterisation at these developmental stages. Using the whole-cell recording technique, we found that dihydropyridines (DHPs) inhibit the noninactivating component of the Ca-independent K currents of 13-day mouse embryo dorsal-root ganglion (DRG) cells. The inhibitory effect of nicardipine began around 0.5 microM and was nearly complete at 5 microM while Na currents were not altered. This effect was reversible and voltage-dependent. The same results were obtained using another DHP Ca antagonist, nimodipine, whereas Bay K 8644, a DHP Ca agonist, had no effect. Kinetic properties of the DHP-insensitive K current have been described and compared with those of transient K currents found in differentiated neurons. These results suggest that both Ca and K channels have DHP sites, possibly homologous, at this developmental stage. The DHP inhibition of Ca-independent K channels provides a new tool with which to study K channels both at a molecular level and during DRG development.

Comparison of the neurotoxic effects of colchicine, the vinca alkaloids, and other microtubule poisons

Previous studies have revealed that colchicine is selectively toxic to certain neuronal populations in the CNS, particularly granule cells of the dentate gyrus. The present study evaluates whether other microtubule poisons exhibit similar neurotoxic effects. Equimolar solutions of colchicine, colcemid, podophyllotoxin, vinblastine, vincristine and lumicolchine, the non-binding analog of colchicine, were injected into the dentate gyrus. Neurotoxicity was evaluated histologically. As previously reported, colchicine selectively destroyed dentate granule cells with minimal damage to other neurons including hippocampal pyramidal cells. Vincristine was very toxic and was not selective for granule cells. Vinblastine was relatively selective in destroying granule cells, but was not as potent as colchine. Colcemid and podophyllotoxin had minimal toxic effects. Lumicolchine injections caused no more damage than injections of vehicle. This ordering appears to correlate with the reversibility of binding tubulin.

Selective axonal transport in a single cholinergic axon of Aplysia--role of colchicine-resistant microtubules

Substance-specific selective axonal transport was examined in a single axon by injecting [3H]leucine and [14C]acetylcholine simultaneously into the cell body of a giant cholinergic neuron (R2) in the abdominal ganglion of Aplysia kurodai. The ganglion and attached nerves were cultured for several hours after the injection and the migration of radioactive substances along the axons of the injected neuron was examined. The substances examined were 3H labeled membrane proteins and soluble proteins synthesized in the cell body, 14C labeled bound acetylcholine formed in the cell, injected [3H]leucine and soluble [14C]acetylcholine. Membrane proteins and bound acetylcholine (plus a part of soluble acetylcholine) moved along the axon somatofugally at maximum velocities of 2.4 and 1.7 mm/h, respectively, at 25 degrees C. Soluble proteins, free leucine and most of the soluble acetylcholine did not move by fast axonal transport but diffused inside the axon of the neuron R2 at rates predicted from their expected diffusion constants in the axoplasm [Koike H. and Nagata Y. (1979) J. Physiol. 295, 397-417]. The diffusion kinetics of these substances were analysed and used for determination of true axon length, and to separate axonal transport components from diffusing components. An antimitotic drug, colchicine, selectively suppressed the axonal transport of membrane proteins but not of acetylcholine at 1-5 mM concentration, though it finally blocked the axonal transport of acetylcholine at 20 mM. When 1-5 mM colchicine was separately perfused only to the distal axon of the neuron R2, the migration of membrane proteins was stopped just proximal to the colchicine perfusion zone but acetylcholine migration was not disturbed by the drug. The moving component of acetylcholine was recovered by sucrose density centrifugation from a compartment previously reported as that of vesicular acetylcholine. As a possible mechanism of this selective axonal transport, it is proposed that there are two groups of microtubules: a colchicine-sensitive group of microtubules which may transport membrane proteins, and a colchicine-resistant group which may preferentially transport the transmitter substance acetylcholine at a slower rate.

Long-lasting potentiation of synaptic transmission requires postsynaptic modifications in the neocortex

The mechanisms of associative long-lasting potentiation (LLP) of excitatory postsynaptic potentials (EPSPs) were studied in the motor cortex of anesthetized cats. Mono- and oligosynaptic EPSPs were evoked by stimulations of thalamic VL nucleus, pyramidal tract, callosal and somatosensory system and paired with orthodromic, antidromic or current-induced action potentials. EPSP-spike stimulus pairs with 0.1-0.2 Hz frequency and 0-200 ms interstimulus intervals induced increases in the amplitudes and durations of EPSPs for 40-60 min or longer after 20-50 pairings. The LLP was prevented when postsynaptic firing was blocked by intracellular current injection or by juxtasomatic application of gamma-aminobutyric acid. LLP was also prevented when the level of intracellular free calcium was lowered by the intracellular injection of the calcium chelator EGTA or when neuronal transport was blocked by the intracellular injection of colchicine. Neither EGTA nor colchicine blocked postsynaptic firing. Thus, these findings show that LLP in the neocortex is a postsynaptic phenomenon which requires conjunctive pre- and postsynaptic activity, adequate levels of intracellular free calcium, and functional intracellular transport.

Newly synthesized and preformed acetylcholine are released from Torpedo synaptosomes by different pathways

In this study, we investigated the mechanisms underlying the release of preformed and of newly synthesized acetylcholine (ACh) from isolated Torpedo nerve terminals (synaptosomes). This was pursued by examining and comparing the effects of anticytoskeletal and anticalmodulin drugs and of activating the presynaptic muscarinic ACh receptors on the release of preformed endogenous ACh and of newly synthesized radiolabeled ACh. The anticytoskeletal drugs vinblastine, cytochalasin B, and colchicine inhibit the Ca2+-dependent K+-mediated release of newly synthesized radiolabeled ACh, but have no effect on the release of preformed ACh. By contrast, the muscarinic agonist oxotremorine markedly inhibits the release of preformed ACh, but has little effect on the release of newly formed ACh. Treatment of the synaptosomes with the calmodulin antagonist trifluoperazine inhibits the release of both ACh pools concomitantly. These findings show that preformed and newly synthesized ACh are released by different routes and suggest that their secretion is mediated by converging pathways. The significance of these results in view of the previously demonstrated preferential release of newly synthesized ACh is discussed.

Are axoplasmic microtubules necessary for membrane excitation?

The excitability of the squid giant axon was studied as a function of transmembrane hydrostatic pressure differences, the latter being altered by the technique of intracellular perfusion. When a KF solution was used as the internal medium, a pressure difference of about 15 cm water had very little effect on either the membrane potential or excitability. However, within a few minutes after introducing either a KCl-containing, a KBr-containing, or a colchicine-containing solution as the internal medium, with the same pressure difference across the membrane, the axon excitability was suppressed. In these cases, removal of the pressure difference restored the excitability, indicating that the structure of membrane was not irreversibly damaged. Electron-microscopic observations of these axons revealed that the perfusion with a KF solution or colchicine-containing solution preserves the submembranous cytoskeletal layer, whereas perfusion with a KCl or KBr solution dissolves it. These results suggest that the submembranous cytoskeletons including microtubules provide an important mechanical support to the excitable membrane but are not essential elements in channel activities.

The effects of microtubule dissociating agents on the physiology and cytology of the sensory neuron in the femoral tactile spine of the cockroach, periplaneta americana L

Microtubules are prominent cellular components of the mechanosensory and chemosensory sensilla associated with the insect cuticle, and a range of hypotheses have been proposed to account for their role in sensory transduction. Chemical agents such as colchicine and vinblastine, which dissociate microtubules, also interfere with transduction in these sensilla, and this has been attributed to their anti-microtubule activity. We have now examined the dynamic properties of sensory transduction in the mechanosensitive neuron of the cockroach femoral tactile spine, after the application of colchicine, vinblastine and lumicolchicine. Concurrently we have examined the ultrastructure of the same sensory ending by transmission electron microscopy. All of the drugs reduced the mechanical sensitivity o the receptor. Colchicine and vinblastine achieved this reduction without altering the dynamic properties of the receptor but lumicolchicine changed the dynamic response, and increased the relative sensitivity to rapid movements. Conduction velocity, another measure of neuronal function, which relies upon ionic currents flowing through the membrane, was reduced by all three drugs. The effects of the drugs upon the ultrastructure of the sensory ending were also disparate. In the case of colchicine there was complete dissociation of microtubules in the tubular body and distal dendrite before a total loss of mechanical sensitivity. Vinblastine was less effective in dissociating microtubules, although more effective in the reduction of mechanical sensitivity. With lumicolchicine the dominant morphological effect was a severe disruption of the dendritic membrane. We conclude from these experiments that microtubules are not essential in the transduction of mechanical stimuli by cuticular receptors and that the effects of these drugs upon mechanosensitivity are not directly related to their dissociation of the microtubules in the tubular body, but are more likely to arise from actions upon the cell membrane. These actions could include effects upon tubulin in the membrane or upon other membrane components.

Mechanisms of colchicine neurotoxicity in the dentate gyrus: dissociation of seizures and cell death

Extracellular field potentials and the EEG were studied in the dentate gyrus of the rat after intrahippocampal injections of colchicine, which is a relatively selective neurotoxin for dentate granule cells. Injection of colchicine (0.5 microliters of a 5-mg/ml solution of colchicine in deionized water) resulted in granule cell hyperexcitability manifested by multispike field potentials in response to stimulation of the excitatory projections from the entorhinal cortex. In anesthetized rats, this state of granule cell hyperexcitability was occasionally accompanied by interictal epileptic spiking or brief electrographic seizures, but granule cell death was observed even in the absence of epileptic activity. Injection of colchicine into the CA1 area of the hippocampus also resulted in multispike field potentials in response to stimulation of the CA3 commissural pathway, but CA1 pyramidal cells were not destroyed by colchicine. Colchicine has been reported to act as a convulsant agent in the dentate gyrus, but it is a relatively selective neurotoxin for dentate granule cells even in the absence of epileptic activity.

Subcellular localization of tubulin in chick retina

Tubulin was measured through [3H]colchicine-binding in membrane and soluble components of chick retinal subcellular fractions. Total tubulin content was concentrated in the synaptosomal and rod outer segment fractions. Although in total retinal homogenate only 20% of total tubulin was associated to the membrane, in synaptosomes and photoreceptor outer segments, up to 50% of tubulin was bound to the membrane fraction. Results raise the possibility of tubulin participation in transmembrane phenomena which are common to transmitter release and photoexcitation.

Axoplasmic transport block reduces ectopic impulse generation in injured peripheral nerves

Afferent fibers ending in nerve end neuromas in rats generate a substantial ectopic discharge and are sensitive to light pressure and to circulating adrenaline. Treatment of the nerve with colchicine or vinblastine at the time of the nerve section resulted in a dose-dependent reduction in the extent of this discharge. Such treatment also reduced neuroma discharge that had already gotten underway.

Effect of colchicine on 45Ca and choline uptake, and acetylcholine release in rat brain synaptosomes

The effects of 1 and 10 mM colchicine on the K+-evoked release of preformed and newly synthesized acetylcholine and on the K+-depolarization-stimulated uptake of 45Ca were compared in rat brain synaptosomes. Preincubation of synaptosomes with 1 mM colchicine had little effect on transmitter release and on uptake of 45Ca; 10 mM colchicine inhibited both the release of transmitter and uptake of 45Ca by 58%. Since 1 mM colchicine has been shown to disaggregate intrasynaptosomal microtubules almost completely, but to be without effect on release of either preformed or newly synthesized acetylcholine in our experiments, it is concluded that colchicine modifies transmitter release by reducing Ca2+ influx, rather than by its postulated intracellular action on microtubule-mediated transmitter mobilization. In addition, 1 and 10 mM cholchicine significantly inhibited the high-affinity choline uptake in synaptosomes. This hemicholinium-like action of colchicine may contribute to the reduction of transmitter release.

Side effects of phosphorylated acetylcholinesterase reactivators on neuronal membrane and synaptic transmission

The side effects of four phosphorylated cholinesterase reactivators (oximes): contrathion, TMB4, toxogonine and 1574 SEBC on membrane properties and synaptic transmission of Aplysia central neurons were investigated. Applied in the bath at 10(-3) mol X 1(-1) to 10(-2) mol X 1(-1) concentrations, all these oximes had a depressive action on cholinergic transmission exerting a curare-like effect on the postsynaptic receptors. In addition, Toxogonin and TMB4 affected the presynaptic voltage dependent sodium conductance. None of these oximes interfered with the voltage dependent potassium or calcium conductances. The oximes had a transient facilitatory action on amplitude of the response to ionophoretically applied acetylcholine (ACh) on H-type ACh receptors, but not on cells with D-type ACh receptors. The K+ dependent response to ACh injection on pleural ganglion cells was selectively blocked by 5 X 10(-6) mol X 1(-1) contrathion. All oximes at 10(-2) mol X 1(-1) to 10(-3) mol X 1(-1) similarly depressed serotonin receptors in buccal ganglion cells. All the effects of oximes were reversible by washing. It was concluded that oximes can act as 1) inhibitors of Na+ conductance, 2) antagonists for various synaptic receptors, 3) reversible inhibitors of acetylcholinesterase.

The effect of colchicine on neuromuscular transmission in the frog during repetitive stimulation

When colchicine 10(-4) mol . l-1 was applied at the beginning of repetitive stimulation of the nerve at 10 s-1, the facilitation was markedly inhibited. The quantal content showed a very slight increase and its maximum value was reached later. The maximum frequency of spontaneous release was also reached later in the presence of colchicine than in the absence of the drug. In addition, the synaptic delay was much more pronounced in the presence of colchicine than in the control experiment. The results suggest that a partial block by colchicine of the release process in the nerve terminal occurs. This effect may be due to the action of the drug on the nerve terminal membrane. The results cannot exclude the possibility that colchicine interferes with the transport of vesicles towards the sites of release located on the membrane.

Intradentate colchicine retards the development of amygdala kindling

The mechanisms underlying the kindling model of epilepsy are unknown. Presumably, an altered network of neural circuits underlie amygdala kindling. Biochemical and radiohistochemical studies have pointed to the dentate granule cells (DGC) of the hippocampal formation as a member of this altered circuit. To test the role of these cells, colchicine, a neurotoxin of DGC, was directly injected into the dentate gyrus. Prior destruction of DGC retarded the development of amygdala kindling. Destruction of DGC after kindling was completed did not reverse the kindling effect. We conclude that DGC play a key role in the development, but not the permanence, of amygdala kindling. We propose a model whereby the greater the input to the hippocampal formation, the faster limbic kindling will proceed.