Intrafimbrial colchicine produces transient impairment of radial-arm maze performance correlated with morphologic abnormalities of septohippocampal neurons expressing cholinergic markers and nerve growth factor receptor

Microtubules as Regulators of Neural Network Shape and Function: Focus on Excitability, Plasticity and Memory

Neuronal microtubules (MTs) are complex cytoskeletal protein arrays that undergo activity-dependent changes in their structure and function as a response to physiological demands throughout the lifespan of neurons. Many factors shape the allostatic dynamics of MTs and tubulin dimers in the cytosolic microenvironment, such as protein–protein interactions and activity-dependent shifts in these interactions that are responsible for their plastic capabilities. Recently, several findings have reinforced the role of MTs in behavioral and cognitive processes in normal and pathological conditions. In this review, we summarize the bidirectional relationships between MTs dynamics, neuronal processes, and brain and behavioral states. The outcomes of manipulating the dynamicity of MTs by genetic or pharmacological approaches on neuronal morphology, intrinsic and synaptic excitability, the state of the network, and behaviors are heterogeneous. We discuss the critical position of MTs as responders and adaptative elements of basic neuronal function whose impact on brain function is not fully understood, and we highlight the dilemma of artificially modulating MT dynamics for therapeutic purposes.

Insights into plant consciousness from neuroscience, physics and mathematics: a role for quasicrystals?

There is considerable debate over whether plants are conscious and this, indeed, is an important question. Here I look at developments in neuroscience, physics and mathematics that may impact on this question. Two major concomitants of consciousness in animals are microtubule function and electrical gamma wave synchrony. Both these factors may also play a role in plant consciousness. I show that plants possess aperiodic quasicrystal structures composed of ribosomes that may enable quantum computing, which has been suggested to lie at the core of animal consciousness. Finally I look at whether a microtubule fractal suggests that electric current plays a part in conventional neurocomputing processes in plants.

Nicotine evoked improvement in learning and memory is mediated through NPY Y1 receptors in rat model of Alzheimer's disease

We investigated the role of endogenous neuropeptide Y (NPY) system in nicotine-mediated improvement of learning and memory in rat model of Alzheimer's disease (AD). Intracerebroventricular (icv) colchicine treatment induced AD-like condition in rats and showed increased escape latency (decreased learning), and amnesic condition in probe test in Morris water maze. In these rats, nicotine (0.5mg/kg, intraperitoneal), NPY (100 ng/rat, icv) or NPY Y1 receptor agonist [Leu(31), Pro(34)]-NPY (0.04 ng/rat, icv) decreased escape latency by 54.76%, 55.81% and 44.18%, respectively, on day 4 of the acquisition. On the other hand, selective NPY Y1 receptor antagonist, BIBP3226 (icv) produced opposite effect (44.18%). In the probe test conducted at 24h time point, nicotine, NPY or [Leu(31), Pro(34)]-NPY increased the time spent by 72.72%, 44.11% and 26.47%, respectively; while BIBP3226 caused reduction (8.82%). It seems that while NPY or [Leu(31), Pro(34)]-NPY potentiated, BIBP3226 attenuated the learning and memory enhancing effects of nicotine. Brains of colchicine treated rats showed significant reduction in NPY-immunoreactivity in the nucleus accumbens shell (cells 62.23% and fibers 50%), bed nucleus of stria terminalis (fibers 71.58%), central nucleus of amygdala (cells 74.33%), arcuate nucleus (cells 70.97% and fibers 69.65%) and dentate gyrus (cells 58.54%). However, in these rats nicotine treatment for 4 days restored NPY-immunoreactivity to the control level. We suggest that NPY, perhaps acting via NPY Y1 receptors, might interact with the endogenous cholinergic system and play a role in improving the learning and memory processes in the rats with AD-like condition.

Microtubule ionic conduction and its implications for higher cognitive functions

The neuronal cytoskeleton has been hypothesized to play a role in higher cognitive functions including learning, memory and consciousness. Experimental evidence suggests that both microtubules and actin filaments act as biological electrical wires that can transmit and amplify electric signals via the flow of condensed ion clouds. The potential transmission of electrical signals via the cytoskeleton is of extreme importance to the electrical activity of neurons in general. In this regard, the unique structure, geometry and electrostatics of microtubules are discussed with the expected impact on their specific functions within the neuron. Electric circuit models of ionic flow along microtubules are discussed in the context of experimental data, and the specific importance of both the tubulin C-terminal tail regions, and the nano-pore openings lining the microtubule wall is elucidated. Overall, these recent results suggest that ions, condensed around the surface of the major filaments of the cytoskeleton, flow along and through microtubules in the presence of potential differences, thus acting as transmission lines propagating intracellular signals in a given cell. The significance of this conductance to the functioning of the electrically active neuron, and to higher cognitive function is also discussed.

Neural cytoskeleton capabilities for learning and memory

This paper proposes a physical model involving the key structures within the neural cytoskeleton as major players in molecular-level processing of information required for learning and memory storage. In particular, actin filaments and microtubules are macromolecules having highly charged surfaces that enable them to conduct electric signals. The biophysical properties of these filaments relevant to the conduction of ionic current include a condensation of counterions on the filament surface and a nonlinear complex physical structure conducive to the generation of modulated waves. Cytoskeletal filaments are often directly connected with both ionotropic and metabotropic types of membrane-embedded receptors, thereby linking synaptic inputs to intracellular functions. Possible roles for cable-like, conductive filaments in neurons include intracellular information processing, regulating developmental plasticity, and mediating transport. The cytoskeletal proteins form a complex network capable of emergent information processing, and they stand to intervene between inputs to and outputs from neurons. In this manner, the cytoskeletal matrix is proposed to work with neuronal membrane and its intrinsic components (e.g., ion channels, scaffolding proteins, and adaptor proteins), especially at sites of synaptic contacts and spines. An information processing model based on cytoskeletal networks is proposed that may underlie certain types of learning and memory.

Model of ionic currents through microtubule nanopores and the lumen

It has been suggested that microtubules and other cytoskeletal filaments may act as electrical transmission lines. An electrical circuit model of the microtubule is constructed incorporating features of its cylindrical structure with nanopores in its walls. This model is used to study how ionic conductance along the lumen is affected by flux through the nanopores, both with and without an external potential applied across its two ends. Based on the results of Brownian dynamics simulations, the nanopores were found to have asymmetric inner and outer conductances, manifested as nonlinear IV curves. Our simulations indicate that a combination of this asymmetry and an internal voltage source arising from the motion of the C-terminal tails causes cations to be pumped across the microtubule wall and propagate in both directions down the microtubule through the lumen, returning to the bulk solution through its open ends. This effect is demonstrated to add directly to the longitudinal current through the lumen resulting from an external voltage source applied across the two ends of the microtubule. The predicted persistent currents directed through the microtubule wall and along the lumen could be significant in directing the dissipation of weak, endogenous potential gradients toward one end of the microtubule within the cellular environment.

A long-term stress exposure impairs maze learning performance in rats

To elucidate hippocampal dysfunctions following chronic stress exposure, we evaluated the effect of chronic stress on maze learning performance, as assessed by a radial eight-arm maze task. In the 12-week stress sessions, male rats in the stress group were exposed to the stress of a 15-min immersion in cold water once a day and, rats in the control group were slightly handled. Rats in the stress group performed significantly poorly during the acquisition period (P < 0.01) and required more trials to attain at least seven correct choices in the first eight choices for five consecutive trials (P < 0.05). Together with our previous findings that chronic stress exposure damages the hippocampus histologically, we concluded that chronic stress exposure resulted in an impairment of maze learning performance, probably due to hippocampal damages.

Phase II trial of intravenous CI-980 (NSC 370147) in patients with metastatic colorectal carcinoma. Model for prospective evaluation of neurotoxicity

CI-980 (NSC 370147)--a synthetic mitotic inhibitor that binds to tubulin at the colchicine binding site--has significant activity against a broad spectrum of tumor models and greater in vitro cytotoxicity when given over > 24 hours than 4 hours or less. Phase I studies demonstrated central nervous system (CNS) toxicity to be dose-limiting when CI-980 was administered as a 24-hour infusion. When a 72-hour infusion was given, CNS toxicity was reduced and granulocytopenia became the dose-limiting toxicity. In this phase II study, CI-980, 4.5 mg/m2, was administered as a 24-hour continuous intravenous infusion for 3 consecutive days and repeated every 21 days. Fourteen patients who had measurable metastatic colorectal cancer were entered in the trial. Eight patients had received one prior chemotherapy regimen for metastatic disease. Patients were prospectively monitored by neurologic examinations and neuropsychologic assessment of cognitive functioning. No complete or partial responses were observed. Grade 4 granulocytopenia was the dose-limiting toxicity. Reversible declines in recent memory function were noted in all patients. After each course of CI-980, there were also transient non-significant declines in motor coordination, compared with the preinfusion assessment. At the stated dose and schedule, CI-980 lacks activity in metastatic colorectal carcinoma. The agent's toxicity profile (granulocytopenia and CNS effects) was comparable with previously described effects of this agent.

Impairment of maze learning in rats following long-term glucocorticoid treatments

The present study examined the influence of long-term glucocorticoid treatment on a maze learning task on a radial 8-arm maze in rats. Either 100 mg cholesterol (as a control), or corticosterone, bead was implanted in rats for a period of 3 months, beginning at 12 weeks of age. The effect of this treatment on the maze learning task was evaluated during or 4 weeks after the treatments. In both experiments, corticosterone-implanted rats showed an increase in number of trials to attain at least seven correct choices in the first eight choices in five consecutive trials (P < 0.05). We concluded that long-term glucocorticoid exposure resulted in an impairment of the hippocampal functions, i.e. learning and memory, similar to that found in aged hippocampus.

Functional consequences of a single nerve growth factor administration following septal damage in rats

This study examined how possible nerve growth factor (NGF)-induced behaviour changes after septal damage might be modulated by the lesion extent, the dose of NGF administered and the delay between surgery and the onset of testing. In a first experiment, young rats which received electrolytic septal lesions of high or low intensity (inducing respectively large and mild lesions) were treated with 10 or 30 micrograms NGF administered intrahippocampally in a single injection. They were tested 4 months postoperatively for open field ambulation, spontaneous alternation and radial maze performance. It was observed that irrespective of the severity of the lesions rats were impaired in the spontaneous alternation and radial maze tests; however, no obvious changes appeared in the open field test. While an NGF injection did not affect behavioural performances in rats with large lesions, it was capable of ameliorating behavioural deficits in the spontaneous alternation and radial maze tests of rats with mild lesions in both NGF dosage groups. It was also seen that lesions produced a general decrease in hippocampal choline acetyltransferase (ChAT) activity, which was not significantly affected by an NGF administration. There was no significant correlation between ChAT activity and behavioural performance of NGF-treated rats. In a second experiment, young rats received mild septal lesions and were treated with 10 micrograms NGF. These rats were tested 2 weeks postoperatively for radial maze performance. NGF rats exhibited similar behaviour to controls with regard to all of the variables measured. The present results suggest that a single NGF administration spares some abilities to use spatial information efficiently providing lesions are partial.

Fate of septohippocampal neurons following intracerebroventricular injections of colchicine

Injection of colchicine into the lateral ventricles (ICV) of rats results in a selective loss of neurons immunoreactive for choline acetyltransferase (ChAT) in the medial septum (MS) and a concomitant loss of acetylcholinesterase (AChE) positive fibers in the hippocampus. To determine if this loss of cholinergic cells is due to neuronal death, septohippocampal neurons were retrogradely labeled with fluoro-gold (FG) 1 week prior to the injection of colchicine. Numbers and sizes of FG-labeled and ChAT-immunoreactive neurons were assessed 3, 6, and 10 weeks after ICV colchicine. In line with previous observations, numbers of ChAT-immunoreactive cells were reduced to fewer than 50% of control in the MS and to fewer than 60% of control in the vertical limb of the diagonal band (vDB). Three weeks after ICV colchicine, numbers of FG-labeled neurons were reduced to 48% in the MS and 24% in the vDB. By 6 weeks, the number in the MS decreased further to 31% of control, whereas the number remained at 24% in the vDB. Ten weeks after colchicine, the numbers of retrogradely labeled cells in both the MS and vDB had decreased to 11% of control. The cells which remained were not reduced in cross-sectional area or in diameter. These data suggest that the selective loss of cholinergic neurons in the MS which occurs following ICV colchicine is due to neuronal death and not just loss of ChAT expression.

Studies related to the use of colchicine as a neurotoxin in the septohippocampal cholinergic system

Colchicine has been shown to be neurotoxic to cholinergic neurons in the medial septum 1 week following intracerebroventricular injections. The experiments described here were designed to examine the selectivity of this effect over a longer time course, and to examine the role of axoplasmic transport in the neurotoxic effect. As previously reported, 1 week after intracerebroventricular injections of colchicine, the numbers of choline acetyltransferase (ChAT)-immunoreactive neurons in the medial septum-diagonal band complex (MSDB) were reduced to 38% of control; this reduction was stable 2 and 3 weeks post injection. Injections of colchicine placed into the body of the fornix produced similar results. GAD-immunoreactive somata, the other major population of neurons in the MSDB, were unaffected 3 weeks following colchicine, as previously reported 1 week following similar injections. The normal AChE staining pattern in the hippocampus, particularly the dentate gyrus, was depleted following either ICV or intrafornical injections of colchicine. This depletion was more severe with longer survival times. Injections of lumicolchicine, an isomer of colchicine which does not bind tubulin, had no effect on ChAT-immunoreactive neurons in the MSDB or on AChE staining in the hippocampus. Injections of colchicine, but not of lumicolchicine, partially blocked the retrograde transport of the fluorescent dye Fluoro-Gold from the hippocampus to the MSDB. In addition, the content of NGF in the hippocampus rose 84% above control values 2 weeks following colchicine and remained elevated at three weeks. Together these results indicate that colchicine is selectively toxic for cholinergic neurons in the septohippocampal system, and suggest that the alkaloid's neurotoxic effects work via the blockade of axoplasmic transport.

Colchicine-induced deafferentation of the hippocampus selectively disrupts cholinergic rhythmical slow wave activity

It has been proposed that hippocampal rhythmical slow wave activity (RSA or theta-rhythm) induced by sensory stimulation (atropine-sensitive theta) is generated by the cholinergic septo-hippocampal system. Although ablations of the septum or its projections to the hippocampus disrupt hippocampal RSA, such non-selective lesions damage both cholinergic and non-cholinergic septo-hippocampal inputs. The present study assesses the effects of a selective septal neurotoxic lesion on hippocampal electrical activity. Colchicine, which has been reported to be selectively toxic to cholinergic neurons in the medial septum, was injected into the right lateral ventricle, and electrodes were implanted bilaterally into the dorsal hippocampus of female Sprague-Dawley rats. Hippocampal electrical activity was recorded 10-14 days later from the ipsilateral (colchicine-treated) and contralateral (control) hemispheres during locomotor activity or immobility. RSA ranging from 6.3 to 8.7 Hz was evoked in both hippocampi during mobility. Following i.p. administration of an anesthetic dose of urethane, hippocampal RSA at a frequency of 4 Hz could be elicited in the control hemisphere (n = 12) of all animals by pinching the tail. RSA was absent in 6 of 9 animals in the colchicine-treated hemisphere. RSA from control and treated hemispheres persisting after urethane administration was abolished by 5 mg/kg of scopolamine, thus verifying its cholinergic nature. A decrease in the number of choline acetyltransferase (ChAT)-immunoreactive neurons in the medial septum and a depletion of acetylcholinesterase (AChE)-staining in the hippocampus were evident in the hemisphere ipsilateral to colchicine administration. These data support the septal pacemaker hypothesis of hippocampal theta-rhythm and further demonstrate the neurotoxic effect of colchicine on septo-hippocampal cholinergic neurons by the induction of a functional alteration. The selective disruption of cholinergic neurons in the medial septum by colchicine provides a means to dissociate the contribution of septal cholinergic and non-cholinergic components to hippocampal electrical activity.

Cytoskeletal alterations might account for the phylogenetic vulnerability of the human brain to Alzheimer's disease

A theory is presented here in the attempt to explain why Alzheimer's disease (AD) primarily affects areas of the human brain that have been acquired recently in phylogenesis. Disturbances in cytoskeletal function are proposed to play a fundamental role in triggering the sequence of pathologic events leading to the occurrence of AD-related histopathological markers and to the degeneration and death of neurons. These deficits are supposed to occur more likely in neuronal populations that possess a high degree of plasticity, the substrate of memory functions, and that constitute, in fact, the phylogenetically new telencephalic regions of the human brain.

Cholinergic fiber perturbations and neuritic outgrowth produced by intrafimbrial infusion of the neurofilament-disrupting agent 2,5-hexanedione

The compound 2,5-hexanedione (HD) produces axonopathies in peripheral nerves characterized by selective accumulation of neurofilaments. Its direct actions on neurotransmitter-specific neurons in the brain are unknown. In an attempt to address this latter issue, we infused HD into the fimbria and evaluated histochemically and immunohistochemically possible structural alterations in cholinergic neurons projecting from the basal nuclear complex to the hippocampus. Putative cholinergic fibers expressing nerve growth factor receptor and acetylcholinesterase showed increases in caliber and perturbations in trajectories 2-4 days following HD treatment. Similar morphologic changes were observed in neuronal elements processed for the 68 kDa neurofilament protein. At 7 days, short collateral ramifications appeared in many cholinergic axons that were suggestive of neurite outgrowth. Correlated with these fiber alterations was a transient reduction in the number of medial septal and diagonal band somata expressing choline acetyltransferase, which returned to control levels within 6 weeks following HD treatment. These data support the view that neurofilaments play an important, perhaps cytoarchitecturally stabilizing, role in regulating axonal morphology in certain populations of cholinergic neurons.

Impairment of radial-arm maze performance in rats following lesions involving the cholinergic medial pathway: reversal by arecoline and differential effects of muscarinic and nicotinic antagonists

Pharmacologic studies have indicated that accurate performance on the radial-arm maze depends upon the integrity of both nicotinic and muscarinic cholinergic neurotransmitter systems and that these systems interact in a complex fashion. Although numerous studies have suggested that pathways deriving from the basal nuclear complex of the forebrain are critical for the cholinergic modulation of learning and memory, most have focussed on the septohippocampal projection, and none have specifically targeted the medial or lateral systems. In Experiment 1, cortical knife cuts interrupting the medial cholinergic pathway were made at the level of the caudate-putamen nucleus. Such transections produced a robust but temporary disruption of choice accuracy performance in the radial-arm maze. Recovery of this behavior occurred within 10 days and before cholinergic fiber regeneration, suggesting that compensatory changes could have taken place in non-ablated neuronal circuits. In Experiment 2, daily postsurgical administration of arecoline, an agonist with predominantly muscarinic actions, was found to virtually eliminate the adverse behavioral effects of medial pathway transections, indicating that the deficit could be attributable, in part, to disruption of cholinergic projections. In Experiment 3, the effects of scopolamine, a muscarinic antagonist, and mecamylamine, a nicotinic antagonist, were examined in rats with medial cholinergic pathway transections after behavior had returned postsurgically to control levels. Although both drugs attenuated radial-arm maze performance before knife cuts, only scopolamine reduced choice accuracy following surgery. We conclude that the medial cholinergic pathway, particularly its nicotinic actions, plays an important role in cognitive function, at least as exemplified by radial-arm maze performance. Muscarinic mechanisms associated with other telencephalically projecting cholinergic networks, as well as possibly with the medial pathway itself, appear to operate interactively with nicotinic influences.