The effects of colchicine in mammalian brain from rodents to rhesus monkeys

Dentate gyrus and spatial behaviour

This article reviews evidence from studies employing colchicine-induced granule cell loss in the adult rat brain, and irradiation-induced hypoplasia of the neonatal dentate gyrus, on the performance of spatial and non-spatial behavioral tasks. The general picture emerging from this analysis reveals that the dentate gyrus granule cells are critically involved in spatial behavior, particularly when this requires the adoption of place strategies. This notion also provides an explanation for the behavioral effects of dentate gyrus granule cell loss seen in apparently non-spatial tasks.

Thiocolchicoside inhibits the activity of various subtypes of recombinant GABAA receptors expressed in Xenopus laevis oocytes

Thiocolchicoside is a myorelaxant drug with anti-inflammatory and analgesic properties as well as pronounced convulsant activity. To characterize the mechanisms of action of this drug at the molecular level, we examined its effects on the function of various recombinant neurotransmitter receptors expressed in Xenopus oocytes. Electrophysiological recordings from recombinant human gamma-aminobutyric acid type A (GABA(A)) receptors consisting of alpha1beta1gamma2L, alpha1beta2gamma2L, or alpha2beta2gamma2L subunit combinations revealed that thiocolchicoside inhibited GABA-evoked Cl(-) currents with similar potencies (median inhibitory concentrations of 0.13 to 0.2 microM) and in a competitive manner. Consistent with previous observations, thiocolchicoside also inhibited the binding of GABA to rat cerebral cortical membranes. Thiocolchicoside inhibited the function of recombinant human strychnine-sensitive glycine receptors composed of the alpha1 subunit with a potency (median inhibitory concentration of 47 microM) lower than that apparent with recombinant GABA(A) receptors. It also inhibited the function of human nicotinic acetylcholine receptors composed of the alpha4 and beta2 subunits, but this effect was only partial and apparent at high concentrations. In contrast, thiocolchicoside had no effect on the function of 5-HT(3A) serotonin receptors. Our results thus provide molecular evidence that the epileptogenic activity of thiocolchicoside might be due to inhibition of the function of inhibitory receptors in the central nervous system, especially that of GABA(A) receptors.

Dentate gyrus-selective colchicine lesion and performance in temporal and spatial tasks

The effects of multiple-site, intradentate, colchicine injections on the performance of a temporal, 'differential reinforcement of low rates of responding' (DRL-20s) task and a spatial, 'delayed non-matching-to-place' (DNMTP) task in a plus-maze were investigated in rats trained in both tasks prior to the lesion. Quantitative analysis revealed a greater than 86% reduction in the dentate gyrus (DG) of the colchicine-injected rats compared to the sham-operated controls. Dentate gyrus damage rendered rats less efficient than sham-operated controls in the performance of the DRL-20s task. The DRL inter-response time (IRT) distribution for the DG-lesioned rats and the sham-operated controls was similar; however, while the distribution peak for the control rats was 20s, it was 16s for the DG-lesioned rats, indicating that the latter rats underestimated time. Performance of the DG-lesioned rats was also disrupted in the DNMTP task. However, DG-lesioned rats recovered control levels of performance during repeated training with an intertrial interval equal to 3s. An increase in intertrial interval in lesioned and sham-operated controls disrupted performance in both groups; however, while DG-lesioned rats performed at chance levels when the intertrial interval was increased to 4min or longer, the sham-operated controls performed at chance levels only when the intertrial interval was increased to 16min. These results seem most parsimoniously interpreted following the cognitive map theory of hippocampal function.

Focal and secondarily generalised convulsive status epilepticus induced by thiocolchicoside in the rat

The objective of this study was to document the convulsant properties of thiocolchicoside in rats, and to characterise the electroclinical pattern of epileptic seizures. Experiments were carried out in three groups of male Wistar rats: in group A, thiocolchicoside was applied topically to the pia, or given by microinjection to the cerebral cortex (2 microg/microl); in group B, the drug was administered parenterally (6 mg/kg) to rats with minimal lesions of the dura and arachnoid membranes; in group C, thiocolchicoside was administered parenterally (up to 12 mg/kg) to intact rats. In all animals, electroclinical activity was continuously monitored for at least 3 hours after thiocolchicoside injection or application. In group A, electrographic and behavioural activity of focal motor seizures occurred in 100% of animals, developing into a focal status epilepticus; in group B, a multifocal epileptic pattern with secondary generalisation, clinically characterised by clonic or tonic-clonic seizures occurred in 100% of animals, until a secondarily generalised convulsive status epilepticus; in group C, none of animals showed either electrographic or behavioural seizure activity. Our study documents that thiocolchicoside has a powerful convulsant activity in the rat, perhaps due to an antagonistic interaction of the compound with a cortical subtype of the GABA(A) receptor.

Extrinsic regulation of injury/growth-related gene expression in the inferior olive of the adult rat

Successful axon regeneration relies on the capability of the lesioned neurons to up-regulate a specific set of injury/growth-associated genes. In the adult central nervous system, the strength of the cell body response is generally related to the distance of the injury site from the perikaryon, being stronger for proximal lesions. Nevertheless, inferior olive (IO) cells react to injury and regenerate their axons even after distal transections. To investigate the mechanisms that regulate the IO growth properties, we examined the expression of injury/growth markers (nitric oxide synthase, growth-associated protein 43 and c-Jun) after target deletion or axotomy performed at different sites along the olivocerebellar pathway. Both axon injury and target loss disclose two subsets of IO neurons distributed within precise subnuclei: one subset up-regulates all markers in all conditions, whereas the other shows a mild c-Jun expression but remains unresponsive even after a very proximal axotomy. These observations indicate that distinct subpopulations of IO cells respond to different regulatory strategies. Unresponsive neurons appear insensitive to environmental positive or negative cues, suggesting that they are intrinsically unable to set up a cellular reaction to injury. In contrast, cell body changes in reactive neurons are elicited after the removal of retrogradely transported target-derived inhibitory signals. Target loss also induces degeneration of IO cells, whose survival remains partially dependent on Purkinje targets in adulthood. Thus, the intrinsic regenerative potential of a functionally homogeneous population is regulated by multiple mechanisms, specific for distinct neuronal subsets.

Dynamics of a semiconductor laser array with delayed global coupling

We study the dynamics of an array of single mode semiconductor lasers globally but weakly coupled by a common external feedback mirror and by nearest neighbor interactions. We seek to determine the conditions under which all lasers of the array are in phase, whether in a steady, periodic, quasiperiodic, or chaotic regime, in order to maximize the output far field intensity. We show that the delay may be a useful control parameter to achieve in-phase synchronization. For the in-phase steady state, there is a competition between a delay-induced Hopf bifurcation leading to an in-phase periodic regime and a delay-independent Hopf bifurcation leading to an antiphased periodic regime. Both regimes are described analytically and secondary Hopf bifurcations to quasiperiodic solutions are found. Close to the stable steady state, the array is described by a set of Kuramoto equations for the phases of the fields. Above the first Hopf bifurcation, these equations are generalized by the addition of second and third order time derivatives of the phases.

Dentate gyrus-selective colchicine lesion and disruption of performance in spatial tasks: difficulties in "place strategy" because of a lack of flexibility in the use of environmental cues?

The effects of intradentate colchicine injections on the performance of tasks requiring spatial working and reference memory are controversial. Multiple-site colchicine injections (7 microg/microl; via a drawn micropipette) throughout the dentate gyrus (DG) of rats (nine sites in each hemisphere, 0.06 microl at each site) selectively destroy about 90% of the DG granule cells, as revealed by quantitative stereological estimates; stereology also revealed minor neuronal losses in the CA4 (33%) and CA1 (23%) subfields, but lack of damage to the CA3 hippocampal subfield. Spatial reference and working memory were assessed in Morris' water maze; in the reference memory task, the rats were required to learn a single, fixed location for the platform over several days of training; in the working memory task, animals were required to learn a new platform location every day, in a matching-to-place procedure. Compared to sham-operated controls, lesioned rats showed significant disruption in acquisition of the reference memory water maze task; however, the data reveal that these rats did acquire relevant information about the task, probably based on guidance and orientation strategies. In a subsequent probe test, with the platform removed, lesioned rats showed disruption in precise indexes of spatial memory (e.g., driving search towards the surroundings of the former platform location), but not in less precise indexes of spatial location. Finally, the lesioned rats showed no improvement in the match-to-place procedure, suggesting that their working memory for places was disrupted. Thus, although capable of acquiring relevant information about the task, possibly through guidance and/or orientation strategies, DG-lesioned rats exhibit a marked difficulty in place strategies. This is particularly evident when these rats are required to deal with one-trial place learning in a familiar environment, such as in the working memory version of the water maze task, which requires flexibility in the use of previously acquired information.

Colchicine administration in the rat central nervous system induces SNAP-25 expression

he arrest of axonal transport by colchicine administration has been extensively used in immunocytochemical studies to increase the levels of neuroactive compounds in neuronal somata. In order to study the accumulation rates of a variety of proteins with location and physiological action at the synaptic terminal, we analysed, by immunocytochemical methods, the neuronal cell body content of these synaptic proteins in colchicine-injected rats. In sham-injected animals, all synaptic proteins tested were essentially observed in nerve fibres and terminal boutons. After colchicine administration, intense SNAP-25 immunoreactivity was found in many neuronal cell bodies throughout the CNS. In contrast, immunostaining for the rest of the synaptic proteins analysed (syntaxin 1A and 1B, synaptobrevin I and II, Rab3A, synaptophysin, synapsin I, synaptotagmin I and GAP-43) was virtually absent in neuronal cell bodies in treated animals. Furthermore, northern blot and in situ hybridization analysis revealed an increase in SNAP-25a and SNAP-25b messenger RNA isoforms in the brains of adult colchicine-administered animals. In addition, colchicine administration in five-day-old rat pups induced a notable increase in both SNAP-25 transcript isoforms. The present results indicate that in vivo colchicine administration, under conditions known to inhibit axoplasmic transport, upregulates SNAP-25 expression in the rat brain.

Multidimensional quasiperiodic antiphase dynamics

We study analytically the (N-1)-fold degenerate Hopf bifurcation at which N stationary modes with identical parameters become unstable in a model of a solid-state laser with intracavity second harmonic generation. We use the normal form method and exploit the symmetries of the problem. Up to N=3, stable periodic antiphased solutions emerge from the Hopf bifurcation. For N=4, stable quasiperiodic solutions arise from the degenerate Hopf bifurcation. For N>4, the quasiperiodic solutions may be unstable. Then chaotic itineracy is observed numerically close to the degenerate Hopf bifurcation.

Spatial learning deficits in rats after injection of vincristine into the dorsal hippocampus

In the present study, performance in the Morris water escape task after bilateral lesioning of the dorsal hippocampus induced by the microtubule poison vincristine is discussed as a cognitive deficit model in rats. As we are especially interested in spontaneous or pharmacologically induced recovery processes after experimentally induced cognitive dysfunctions, the model should fulfil a number of criteria. Firstly, a clear dose-effect relationship between the dose of vincristine and the amount of spatial learning impairments should be present. Secondly, lesions must remain within the target area. Thirdly, there should be an observable behavioural recovery or compensation of the induced deficit. Two experiments evaluated the influence of the application volume (experiment 1) and the concentration of vincristine (experiment 2) on lesion location and size, and on spatial learning. The results of both experiments demonstrated that the effect of vincristine on the performance in the Morris water escape task seems to be characterized by an "all-or-none" relationship. Concentrations above a "threshold" value induced severe damage in the hippocampus and adjacent brain structures, whereas concentrations below the "threshold" value had marginal or no effects. The non-selective and highly toxic properties of vincristine make this neurotoxin an unsuitable tool for the establishment of a learning and memory deficit model.

Neuronal activity in somatosensory cortex of monkeys using a precision grip. I. Receptive fields and discharge patterns

Three adolescent Macaca fascicularis monkeys weighing between 3.5 and 4 kg were trained to use a precision grip to grasp a metal tab mounted on a low friction vertical track and to lift and hold it in a 12- to 25-mm position window for 1 s. The surface texture of the metal tab in contact with the fingers and the weight of the object could be varied. The activity of 386 single cells with cutaneous receptive fields contacting the metal tab were recorded in Brodmann's areas 3b, 1, 2, 5, and 7 of the somatosensory cortex. In this first of a series of papers, we describe three types of discharge pattern, the receptive-field properties, and the anatomic distribution of the neurons. The majority of the receptive fields were cutaneous and covered less than one digit, and a chi2 test did not reveal any significant differences in the Brodmann's areas representing the thumb and index finger. Two broad categories of discharge pattern cells were identified. The first category, dynamic cells, showed a brief increase in activity beginning near grip onset, which quickly subsided despite continued pressure applied to the receptive field. Some of the dynamic neurons responded to both skin indentation and release. The second category, static cells, had higher activity during the stationary holding phase of the task. These static neurons demonstrated varying degrees of sensitivity to rates of pressure change on the skin. The percentage of dynamic versus static cells was about equal for areas 3b, 2, 5, and 7. Only area 1 had a higher proportion of dynamic cells (76%). A third category was identified that contained cells with significant pregrip activity and included cortical cells with both dynamic or static discharge patterns. Cells in this category showed activity increases before movement in the absence of receptive-field stimulation, suggesting that, in addition to peripheral cutaneous input, these cells also receive strong excitation from movement-related regions of the brain.

Alteration of GABA transporter expression in the rat cerebral cortex following needle puncture and colchicine injection

In the adult cerebral cortex, GABA transporters (GATs) are expressed by both neurons and astrocytes. GAT-1 immunoreactivity is found in axon terminals of GABAergic neurons and astrocytes, while GAT-3 immunolabeling occurs only in the latter. The present study was designed to determine whether the expression of GAT-1 and GAT-3 in the adult rat cerebrum changes after needle lesion and colchicine infusion. Following a needle puncture or a saline injection, immunolabeling for GAT-1 and GAT-3 was slightly increased in an area around the needle track. Not only was the neuropil labeling for both GATs increased, but also a few neuronal somata were found to be immunoreactive for GAT-1. Colchicine injections induced a striking increase in immunolabeling for both GATs in the neuropil in an area adjacent to the needle path and surrounding it. A homologous region of the contralateral hemisphere also showed a moderate increase of immunoreactivity in the neuropil for both GATs. Furthermore, this contralateral site showed many neuronal somata immunolabeled for GAT-1. These changes were mainly detected during the first 5 days following intracortical lesions. These results indicate that (1) the upregulation of GAT-1 and GAT-3 in cortical interneurons and astrocytes is caused by both mechanical and chemical factors associated with the injections; (2) increased GAT-1 and GAT-3 expression contralateral to the site of colchicine injection is mediated by transcellular signaling across the corpus callosum; and (3) the lesion-induced GAT expression may play a protective role by helping to balance excitatory and inhibitory neuronal activities.

Retrograde regulation of growth-associated gene expression in adult rat Purkinje cells by myelin-associated neurite growth inhibitory proteins

Axon regeneration requires that injured neurons reinitiate long-distance growth and upregulate specific genes. To address the question of whether inhibitory environmental cues along the axon could exert a negative, tonic downregulation of growth-associated genes, we have examined adult rat Purkinje cells, which are endowed with poor regenerative capabilities. First we have compared their response to axotomy with that of neurons of the inferior olive, lateral reticular nucleus, and deep cerebellar nuclei, all of which vigorously regenerate into growth-permissive transplants. These injured neurons upregulate the transcription factors c-Jun and JunD, GAP-43, and NADPH diaphorase. In contrast, most axotomized Purkinje cells fail to express any of these markers, showing that the strength of this response parallels the regenerative potential of the examined neuron populations. However, strong upregulation of the same genes can be induced in Purkinje cells after colchicine injection into the uninjured adult cerebellum, indicating that their expression could be controlled by retrograde signals. To assess whether myelin-associated neurite growth inhibitory proteins contribute to this regulation, we applied the neutralizing antibodies IN-1 against one of the main inhibitory components of central myelin (NI-250) either in vivo or in vitro to organotypic cerebellar cultures. Application of IN-1 antibodies induces the upregulation of c-Jun, JunD, and NADPH diaphorase in Purkinje cells, showing that their expression is suppressed constitutively by myelin-associated neurite growth inhibitors. Thus, the inhibitory activity of the IN-1 antigen on axon growth is not restricted to the control of growth cone motility but also involves a retrograde regulation of gene expression in adult central neurons.

Comparison of intracranial infusions of colchicine and ibotenic acid as models of neurodegeneration in the basal forebrain

Colchicine and ibotenic acid were compared for their ability to produce neurodegeneration and cognitive deficit after bilateral infusions into the nucleus basalis magnocellularis of male Long-Evans rats. Four weeks post-lesion, there was no difference in locomotor activity following infusion of either neurotoxicant or vehicle. In a passive avoidance task, both treated groups had significantly shorter step-through latencies compared with vehicle. Five weeks post-lesion, rats were killed for neurochemistry or histochemistry. Choline acetyltransferase (ChAT) activity in both the frontal and parietal cortex was significantly decreased (25-35%) in the colchicine- and ibotenic acid-infused rats when compared to control. There was no effect of either neurotoxicant on ChAT activity in the hippocampus or striatum. Both neurotoxicants produced damage in the general area of the ventromedial pallidum, although ibotenic acid infusion consistently produced a larger area of damage as assessed in Nissl-stained sections. Analysis of the number of ChAT-immunoreactive cells in the nucleus basalis magnocellularis (NBM) showed an average 60% cell loss following colchicine infusion and a 75% cell loss after ibotenic acid infusion. Area of glutamic acid decarboxylase (GAD) staining was significantly decreased in several regions surrounding the NBM for ibotenic acid (51% average decrease), and showed non-significant decreases (28%) following colchicine infusion. Colchicine infusion decreased dopamine and 3,4-dihydroxyphenylacetic acid (DOPAC) in the striatum; ibotenic acid had no effect on brain catechol of indoleamine levels. The results indicate that although similar cholinergic hypofunction and behavioral deficits were achieved, several non-cholinergic differences between the neurotoxicants were detected.

Localization of oestrogen receptors in preoptic neurons containing neurotensin but not tyrosine hydroxylase, cholecystokinin or luteinizing hormone-releasing hormone in the male and female rat

The neurochemical identity of preoptic neurons containing oestrogen receptors was investigated in the male and female rat using a sequential double-staining immunocytochemistry procedure. Single-immunostaining revealed large populations of cells with nuclear immunoreactivity to the oestrogen receptor in the medial preoptic area of the male and female rat. Optimal double-staining of sections for the oestrogen receptor and one of several neuropeptides or tyrosine hydroxylase, was achieved with short-term (two- to four-day) gonadectomized rats treated with colchicine where necessary. Neurotensin-immunoreactive cells were distributed in a sexually dimorphic manner in the region of the anteroventral preoptic nucleus and exhibited oestrogen receptor immunoreactivity in both sexes. Double-labelled cells in this area of the female rat comprised 50% and 11% of the total neurotensin- and oestrogen receptor-containing cell populations, respectively, compared with 25% and 4% in the male (P less than 0.01). The numbers of neurotensin-immunoreactive cells in the region of the medial preoptic nucleus were similar in male and female rats with double-labelled cells making up 20-38% and 3-5% of the total numbers of cells containing neurotensin and oestrogen receptors, respectively, in both sexes. Neurons immunoreactive for tyrosine hydroxylase were distributed in a gender-specific manner within the anterior periventricular area but were not immunoreactive for the oestrogen receptor in either sex. Following colchicine treatment, cholecystokinin-immunoreactive cells were identified predominantly within periventricular regions of the preoptic area and similarly, did not possess immunoreactivity to the oestrogen receptor in either the male or the female rat. Neurons containing luteinizing hormone-releasing hormone were found immediately lateral to the cell populations containing oestrogen receptors and immunoreactivity to the oestrogen receptor was not identified within any neurons containing luteinizing hormone-releasing hormone in either the male or female rat. The absence of oestrogen receptor immunoreactivity in neurons containing tyrosine hydroxylase, cholecystokinin or luteinizing hormone-releasing hormone suggests that gonadal steroids acting through this receptor do not influence these cells directly in either sex. In particular, it appears that gender-specific patterns of luteinizing hormone secretion cannot be attributed to sex differences in oestrogen receptor localization within luteinizing hormone-releasing hormone neurons. These experiments also show that the sexually dimorphic neurotensin neurons in the preoptic area possess oestrogen receptors and that female rats have larger number of neurons co-localizing neurotensin and oestrogen receptors. As such, these neurons may be involved in mediating sex-specific actions of the gonadal steroids in the preoptic area.

Effects of colchicine on retrogradely-transported WGA-HRP

The effects of colchicine treatment on retrogradely-transported WGA-HRP were examined in the cat. The ventroposterolateral nucleus of the thalamus was bilaterally injected with WGA-HRP followed 2 days later by a unilateral injection of colchicine into the dorsal column nuclei (DCN). The cats were sacrificed by perfusion 24 h later. Retrogradely-transported WGA-HRP within DCN neurons was visualized in coronal, vibratome-cut sections of the medulla using the procedure of Rye and collaborators (J. Histochem. Cytochem., 32 (1984) 1145-1153). On the uninjected side, as expected, the reaction product filled numerous neuronal perikarya and their dendrites. In contrast, on the colchicine-treated side, the reaction product was restricted to dendrites; little labeling was observed within perikarya. These findings appear to reflect colchicine's effects on the translocation of lysosomes from neuronal perikarya to their dendrites are important for the interpretation of data from experiments using colchicine to enhance perikaryal immunohistochemical staining.

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.

Entorhinal cortex lesion or intrahippocampal colchicine injection increases peripheral type benzodiazepine binding sites in rat hippocampus

The peripheral type benzodiazepine binding site (PTBBS) has been proposed to be a good marker for reactive glial cells following brain insults. In the present study, homogenate binding of 3H-Ro5-4864 and quantitative autoradiography of 3H-PK-11195 binding (two ligands for the PTBBS) were used to assess the distribution, time-course and extent of reactive gliosis in the hippocampus following deafferentation by unilateral entorhinal cortex lesion or neuronal death produced by intrahippocampal colchicine injection. Intrahippocampal colchicine injections produced a 3-fold increase in 3H-Ro5-4864 binding in the dentate gyrus within 2 days. This effect was doubled in animals pretreated with the lysosomal inhibitor chloroquine. Quantitative autoradiography of 3H-PK-11195 binding 1 or 2 weeks after colchicine injection indicated that the increase in binding was restricted to the dorsal hippocampus both rostrally and caudally and was present in the dentate gyrus and CA1. Following a unilateral electrolytic lesion of the entorhinal cortex, the binding of 3H-Ro5-4864 to homogenates of the dentate gyrus was doubled 18 h after the lesion, reached a maximum at 4 days post-lesion, and returned to control values by 2 months after the lesion. A transient increase in binding was also observed 2 and 4 days post-lesion in the dentate gyrus contralateral to the lesion side. Autoradiography of 3H-PK-11195 binding indicated that the increase in PTBBS following entorhinal cortex lesion was restricted to the molecular layer of the dentate gyrus.(ABSTRACT TRUNCATED AT 250 WORDS)

Four groups of tyrosine hydroxylase-immunoreactive neurons in the ventrolateral medulla of rats, guinea-pigs and cats identified on the basis of chemistry, topography and morphology

The data in the preceding paper [Halliday G. M. and McLachlan E. M. (1991) Neuroscience 43, 531-550] suggest that some neurons in the rostral ventrolateral medulla contain some catecholamine-synthesizing enzymes but may not produce catecholamines. The present study addresses this question directly by comparing the anatomical location and morphology of these neurons with those revealed by formaldehyde-induced fluorescence. Catecholamine-containing somata of rats and guinea-pigs have been demonstrated following FAGLU-perfusion in normal untreated animals, in animals pretreated with pargyline (a monoamine oxidase inhibitor), and in animals pretreated with colchicine (to block axoplasmic transport). The number and location of fluorescent somata in the ventrolateral medulla have been determined in serial coronal sections of tissue from the cervical spinal cord to the level of the facial nucleus. Catecholamine-fluorescent neurons at different levels of the ventrolateral medulla varied in their topography and sensitivity to pharmacological manipulation. However, the rostrocaudal distributions in rats and guinea-pigs were quantitatively remarkably similar implying that homologous groups of catecholamine-containing neurons exist. Comparison between these distributions and those of somata stained immunohistochemically for catecholamine-synthesizing enzymes and neuropeptide Y [Halliday G. M. and McLachlan E. M. (1991) Neuroscience 43, 531-550] revealed that the majority of fluorescent neurons in both species probably contain dopamine-beta-hydroxylase and neuropeptide Y as well as tyrosine hydroxylase. Those neurons lying just caudal to the facial nucleus immunoreactive for tyrosine hydroxylase and phenylethanolamine-N-methyltransferase but not dopamine-beta-hydroxylase and neuropeptide Y also lack catecholamine fluorescence. This rostral group of somata can be identified immunohistochemically in cats. The size and morphology of catecholamine-fluorescent neurons have been analysed in detail, and compared with the same features of the immunohistochemically stained neurons. Three morphological types of catecholamine-containing neurons could be distinguished in material prepared by both techniques from rats and guinea-pigs, and in immunohistochemical material from cats. Rostral tyrosine hydroxylase-positive neurons, which differed morphologically from these three types, were present in all three species. On the basis of anatomical location, neuronal morphology and chemical characteristics, four groups of tyrosine hydroxylase-immunoreactive neurons have been identified in the ventrolateral medulla of rats, guinea-pigs and cats. Only the caudal three of these four groups appear to synthesize catecholamine, probably noradrenaline. From published data it seems likely that these four groups of tyrosine hydroxylase-positive neurons have distinct projections and functions related to cardiovascular and respiratory control.

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

The microtubule disrupting agent, colchicine, was infused both bilaterally and unilaterally into the fimbria of the rat brain. Such infusions produced a transient impairment in radial-arm maze performance during the first week following surgery but only in bilaterally injected animals. This behavioral finding was correlated with a reduction in the number of neurons expressing choline acetyltransferase and nerve growth factor receptor in the septum and vertical limb of the diagonal band but not in other regions of the basal nuclear complex. The altered expression of the two neurochemical markers was not due to cellular degeneration because numbers of neurons demonstrated by Nissl staining were unchanged. Putative cholinergic fibers in the fimbria demonstrating acetylcholinesterase and nerve growth factor receptor also showed aberrations in caliber, shape, and course.

Reversal of advanced colchicine toxicity in mice with goat colchicine-specific antibodies

Colchicine-specific antibody (IgG(C] was tested in mice for reversal of colchicine toxicity. The mouse model was chosen because it reflects human pathophysiology in colchicine poisoning. IgG(C) was administered when at least 85% of colchicine was distributed in tissues. It resulted in a dramatic decrease in lethality from 85% (control group) to 10% (treated group). The decrease in toxic effects was confirmed by evaluating physiological parameters. The recovery of thermoregulation was very rapid in mice treated with IgG(C), while recovery in body weight was less marked. IgG(C) administration, therefore, decreases the intensity but may extend the duration of colchicine toxicity (reversible binding). The total neutralizing binding capacity of IgG(C) used was such that administered IgG(C) neutralizing binding sites were either 7 or 15% of the injected colchicine dose. In spite of this low neutralizing capacity the treatment was successful because of the ability of IgG(C) to buffer the amount of colchicine molecules on the critical slope of the dose-lethality curve.

The effect of antimitotic agents on the intraneuronal distribution of lysosomes

We previously showed that a single injection of colchicine into the lateral cerebral ventricle of the rat causes a redistribution of lysosomes from their normal localization in neuronal cell bodies into dendrites. In the present report we have examined the time course and specificity of this effect using a variety of microtubule poisons. Dipeptidylaminopeptidase II (Dpp II), a lysosomal marker enzyme, histochemistry was used to visualize lysosomes at the light microscopic level. Acid phosphatase, another lysosomal enzyme, histochemistry was used to confirm the Dpp II localization of lysosomes. Two h after an intracerebroventricular (i.c.v.) injection of colchicine, the distribution of neuronal lysosomes was drastically altered. Lysosomes in a number of neuronal populations were observed to move from the soma to the dendrites. This effect was maximal between 12 and 24 h and was partially reversed by 96 h. Injections of colcemid or podophyllotoxin, drugs that bind to tubulin rapidly, and much less tightly than colchicine, produced a much less pronounced alteration in the intraneuronal distribution of lysosomes. Injections of vinblastine or vincristine, whose binding kinetics range between that of colchicine and that of colcemid and podophyllotoxin, resulted in a redistribution of lysosomes which was less pronounced than the effects of colchicine but more pronounced than that caused by colcemid and podophyllotoxin. Likewise, treatment with other related compounds, 2-methoxy-5-(2',3',4'-trimethoxyphenyl)tropone (A-C compound) and lumicolchicine, whose binding to tubulin is extremely rapid and reversible or non-existent, produced little or no alteration in the intraneuronal distribution of lysosomes. The results suggest that lysosome redistribution may be dependent upon a relatively slow dissociation rate constant of these drugs from tubulin, and this transport may occur when normal microtubule function is compromised.

Cholinergic cell loss and cognitive impairments following intraventricular or intradentate injection of colchicine

Bilateral injections of colchicine (3.5 or 7.0 micrograms/0.5 microliters/site) into either the dentate gyrus or the lateral cerebroventricles (i.c.v.) of Sprague-Dawley rats produced specific behavioral, histopathological and neurochemical alterations. Colchicine, administered via either route, produced impairments in the performance of a radial-arm maze task which did not subside during 8 weeks of testing. Intradentate colchicine decreased (1) the thickness of both blades of the dentate granule cell layer, (2) the size of the overlying molecular layer, (3) hippocampal volume, and (4) the number of cholinergic neurons in the medial septum/vertical limb of the diagonal band (MS/VLDB). I.c.v. administration of colchicine did not alter any index of hippocampal morphology but did significantly decrease the number of cholinergic neurons in the MS/VLDB. An analysis of the time course of cholinotoxicity revealed that both intradentate and i.c.v. colchicine decreased choline acetyltransferase (ChAT) activity and high affinity choline uptake (HAChU) in the hippocampus at 1 and 3, but not 9, weeks following surgery. Furthermore, i.c.v. colchicine decreased ChAT activity in the septum at both 3 and 9 weeks following surgery. Neither route of administration altered ChAT or HAChU in the frontal cortex, olfactory bulb or striatum. The decreases in presynaptic cholinergic parameters were paralleled by a reduction in acetylcholinesterase staining in the hippocampus which appeared to recover within 9 weeks. These data suggest that intradentate colchicine produces either (i) transsynaptic degeneration of cholinergic neurons due to a loss of their target sites (granule cells in the dentate gyrus), (ii) a direct cholinotoxic effect, or (iii) a combination of these mechanisms. The i.c.v. injection of colchicine appears to exert a direct toxic effect on cholinergic neurons and/or nerve terminals that results in the death of these neurons. Colchicine may be a useful tool for investigating the behavioral and neurobiological properties of the septohippocampal cholinergic pathway and its response to injury.

Neurotoxic lesions of the nucleus basalis induced by colchicine: effects on spatial navigation in the water maze

Neuronal loss in the nucleus basalis magnocellularis (NBM) has been consistently associated with learning and memory impairments. Previous studies have used excitotoxicants such as kainic acid or ibotenic acid to examine the behavioral consequences of NBM lesions. In the present study, rats were given bilateral injections of the neurotoxicant colchicine (1.0 micrograms/site) into the NBM and examined for changes in learning and memory. Unlike excitotoxicants, which can produce extensive subcortical damage, colchicine produced a lesion limited to the site of injection. Histological studies demonstrated that colchicine decreased the number of choline acetyltransferase (ChAT)-positive cells in the NBM, and resulted in a marked loss of cortical acetylcholinesterase staining. Separate neurochemical analysis showed that colchicine lesions decreased ChAT activity in the neocortex but not the hippocampus or caudate nucleus. Similar to previous studies, rats with NBM lesions showed a large deficit in a passive avoidance task. Lesions of the NBM impaired acquisition of a reference memory task in the Morris water maze. However, the deficit was transient and with continued training lesioned rats performed as well as controls. In a reversal test in the water maze the learning deficit reappeared. These data suggest that colchicine may be useful in producing lesions of the NBM, which primarily affects the rate of acquisition of a spatial reference memory task.

GM1 ganglioside counteracts cholinergic and behavioral deficits induced in the rat by intracerebral injection of vincristine

The intracerebroventricular injection of 0.5 mg of vincristine sulphate in adult male Wistar rats caused within 11 days the impairment of motor and reflexive behavior, evaluated by the elevated platform and hanging wire tests, a decrease in food consumption and loss of body weight, a 45% decrease in hippocampal choline acetyltransferase (ChAT) activity and a 35% decrease in the rate of high-affinity choline uptake (HACU) in the injected side. The latter effects are due to the death of neurons in the respective hemiseptum. Intrafimbrial injection of vincristine caused the same decrease in ChAT activity without behavioral alterations. Daily i.p. administration of GM1 ganglioside, beginning immediately after the vincristine injection, prevented dose dependently the decrease in ChAT activity and HACU rate. Prevention was complete with the 60 mg/kg dose. The same dose was equally active on ChAT activity when given s.c. but was inactive p.o. The ChAT decrease was also prevented when GM1 treatment began 5 days after vincristine. GM1 60 mg/kg i.p. also reduced the behavioral toxicity of vincristine. The possibility that GM1 might prevent vincristine toxicity by antagonizing its disruption of neurofilaments and axonal flow is discussed.

GM1 ganglioside attenuates the behavioral deficits but not the granule cell damage produced by intradentate colchicine

Bilateral injection of 3.5 micrograms of colchicine into the dentate gyrus produced hyperactivity, impaired retention of a passive avoidance task, and enhanced the motor stimulant effects of a dopaminergic agonist (apomorphine) and the analgesic effects of morphine. In contrast, there was no alteration in scopolamine-induced hyperactivity. These effects were associated with a decrease in the thickness of the granule cell layer in both the superior and inferior blade of the dentate gyrus and a coincident decrease in the size of the overlying dentate molecular layer. Intraperitoneal injection of monosialoganglioside GM1 (30 mg/kg) beginning 3 days prior to surgery and continuing for 25 days following surgery appeared to limit the extent and duration of these behavioral effects. GM1 facilitated recovery of motor activity and attenuated the impaired retention of the passive avoidance task and the alterations in pharmacological sensitivity following intradentate injection of colchicine. Despite the facilitative effects of GM1 on behavior histological analysis of the hippocampus did not reveal a protective effect of this compound on colchicine-induced granule cell destruction. The results of these studies suggest that intradentate injection of colchicine is a useful model of human diseases where only restricted populations of neurons are damaged. Furthermore, these studies indicate that the use of monosialoganglioside GM1 might be a useful primary or adjunct approach to the treatment of neurodegenerative disorders and their behavioral sequelae.

Selective working memory impairments following intradentate injection of colchicine: attenuation of the behavioral but not the neuropathological effects by gangliosides GM1 and AGF2

Bilateral injection of 3.5 micrograms of colchicine into the dentate gyrus produced specific learning and memory impairments together with a selective pattern of neuropathology. Animals injected with colchicine exhibited a significant impairment in their ability to perform the working memory, but not the reference memory, component of a multiple component T-maze task. These deficits were transient and over time all animals were able to reaquire the task to preoperative levels of performance. Histological analyses revealed that intradentate injection of colchicine produced 1) a significant decrease in the width of both the superior and inferior blades of the dentate gyrus reflecting the extensive loss of granule cells, 2) a related decrease in the size of the dentate molecular layer, and 3) a decrease in the number of cholinergic neurons in the medial septum. The second phase of the experiment demonstrated that gangliosides GM1 and AGF2 did not prevent the initial impairments in working memory performance induced by colchicine but rather accelerated the rate at which it recovered. The gangliosides did not decrease the extent of neuronal damage; there was no sparing of granule cells in the dentate gyrus or cholinergic neurons in the medial septum. These data further support a role for the hippocampus in working memory processes and they also indicate that gangliosides GM1 and AGF2 might be useful for treating the behavioral deficits induced by hippocampal damage.

Colchicine lesions of ventromedial hypothalamus: effects on regulatory thermogenesis in the rat

Experiments were carried out to test whether the ventromedial hypothalamus (VMH) is the site of a pathway that stimulates thermoregulatory heat production in brown adipose tissue (BAT). Adult Sprague-Dawley rats received bilateral 50 nl microinjections of colchicine solution into the VMH (0.1, 0.32, 1.0 or 3.2 micrograms per side). Beginning a day later, hyperphagia developed consistently with 0.32 microgram colchicine; and with higher doses there appeared the additional effect that for several days rats developed hypothermia when placed temporarily at 6 degrees C. The degree of hypothermia was limited by activation of nonshivering thermogenesis (NST) in BAT, as evidenced by increased shivering after propranolol injection to block NST, and by increased GDP binding measured in IBAT mitochondria after cold exposure. The findings suggest that chemical lesioning to induce the VMH hyperphagia syndrome does not produce an obligatory impairment of thermoregulation against cold unless the dose of neurotoxin and lesion area extends beyond that which underlies the overeating response. Furthermore, when tolerance to cold is thus compromised, the effect is not readily explained in terms of simply disconnecting a proposed stimulatory pathway from the VMH to BAT.

Intrahippocampal colchicine injection results in spectrin proteolysis

Neurons in the hippocampal formation vary markedly in their susceptibility to colchicine toxicity. The present study was directed at evaluating the effects of colchicine on the proteolytic breakdown of the cytoskeletal protein spectrin within the hippocampus in the rat. Quantified by immunoblot analysis of spectrin breakdown products, the extent of proteolysis was found to correlate with the relative vulnerability of different hippocampal subfields to colchicine toxicity. Levels of breakdown products increased dramatically between 1 and 2 days after colchicine injection, peaked between 2 and 4 days, and remained detectably elevated for at least 35 days. Two days after colchicine injection, the spectrin breakdown products were significantly more concentrated in the molecular layer than in the granule cell/hilar region of the dentate gyrus. The colchicine-induced increase in spectrin breakdown products was significantly reduced by pretreatment with the protease inhibitor leupeptin and was significantly elevated by pretreatment with the lysosomal inhibitor chloroquine. Immunohistochemical analyses of the hippocampus at various times after colchicine injection revealed changes in the distribution of spectrin-like immunoreactivity that paralleled the changes observed by Western blot analysis. Thus increased staining was observed in the molecular layer of the dentate gyrus at 2 and 4 days after the injection, while staining in CA3 was only slightly increased. In addition, abnormal staining of reactive astrocytes was prominent at 2 days. The mechanism whereby colchicine results in neuronal death is as yet unknown. However, the results presented here demonstrate that extensive proteolysis of a cytoskeletal protein occurs in response to the drug, suggesting a plausible mechanism for its neurotoxicity. The protease responsible for the effect is likely to be calpain since the process is non-lysosomal, leupeptin-sensitive and produces spectrin breakdown products indistinguishable from those generated by calpain treatment in vitro. These data support the hypothesis that calpain-mediated degradation of cytoskeletal elements is a common and early response to neurodegenerative events and serves as a trigger in the development of various neuropathologies.

Effect of colchicine on micturition reflex in rats

Intracerebral or intraspinal cord, but not intraperitoneal, injection of low doses of colchicine in rats induces specific toxic symptoms. This paper deals in particular with the effect of colchicine on micturition. After the injection of 5-25 micrograms/rat in cerebral ventricle or 2.5-20 micrograms/rat intraspinal cord, bladder content was markedly increased, due to a dramatic urine retention. Time of latency of vesical retention was related to the dose and to the route of colchicine administration. Cystometrographic analyses were performed in control and treated rats at various intervals of time after the injection: bladder tone, as expressed by the delta P/delta V ratio, monitored from 12 to 120 hr after colchicine injection, decreased more and more during time, suggesting that the observed vesical hypotonicity is an irreversible phenomenon.

Immunocytochemical localization of angiotensin-(1-7) in the rat forebrain

Recent findings by this group have led us to reconsider the view that amino (N-) terminal fragments of angiotensin (Ang) II are inactive degradation products of renin-angiotensin system. To further examine this possibility, an antibody to Ang-(1-7), the N-terminal heptapeptide, was produced to demonstrate the neuroanatomical distribution of the rat brain. Ang-(1-7)-immunoreactivity was found in paraventricular, supraoptic, and suprachiasmatic nuclei, bed nucleus of the stria terminalis, substantia innominata, median eminence, and neurohypophysis. This distribution of Ang-(1-7) in the rat forebrain, together with our previous demonstrations of vasopressin secretion in response to this peptide, suggest that Ang-(1-7) functions as a neuromodulator.

Decreased metabolism of cerebrosides and sulfatides in rat sciatic nerve after intraneural injection of colchicine

To obtain an understanding of the importance of the neuronal cytoskeleton in Schwann cell metabolism, an antimicrotubular agent (colchicine) was injected into the rat sciatic nerve 24 or 48 h before incubation of the nerve with labeled precursor: [35S]sulfate, [14C]galactose, or [3H]-galactose. Colchicine inhibited the incorporation of 35S radioactivity into sulfatides and, to a lesser extent, into proteins. With galactose as the radioactive precursor, synthesis of cerebrosides was reduced by colchicine injection, whereas incorporation of radioactivity into phosphatidylserine and phosphatidylcholine increased. Intraneural injection of lumicolchicine had no effect. The effects of colchicine on the metabolism of the Schwann cell are discussed in relation to its action on microtubules.

Purkinje cells of adult rat cerebellum express nerve growth factor receptor immunoreactivity: light microscopic observations

Adult rat cerebellum was examined for the presence of nerve growth factor receptor (NGFr) immunoreactivity (IR) using the monoclonal antibody 192-IgG. In normal animals, light NGFr-IR was observed consistently in Purkinje cells and molecular layer throughout the flocculonodular lobe. However, animals treated with intracerebroventricular colchicine 7-72 h prior to analysis displayed a graded increase of IR in Purkinje cells of all regions with progressively longer survival times. These findings demonstrate the usefulness of colchicine in revealing accumulation of NGFr in adult CNS neurons where previously not visualized and suggest responsiveness of a non-cholinergic neuronal population to nerve growth factor (NGF).

Enhancement of neurotrophic activity in cholinergic cells by hippocampal extract prepared from colchicine-lesioned rats

The effect of hippocampal extract on neurotrophic activity for cultured cholinergic cells was determined. Extract prepared from lesioned hippocampus caused by intrahippocampal infusion of colchicine promoted neuron survival of chick ciliary ganglion cells. The maximal level of survival-promoting activity was reached at 12 days postlesion. The biochemical differentiation of NG108-15 cells was assessed by measuring the activity of choline acetyltransferase (ChAT). After 3 days in culture, hippocampal extract was found to stimulate ChAT activity in a concentration-dependent manner. Hippocampal extract prepared after colchicine lesions elicited a large increase in ChAT-enhancing activity. The effect of hippocampal extract was additive to that of dibutyryl cyclic AMP (db-cAMP). The neurite outgrowth from NG108-15 cells was also potentiated when cells were cultured with hippocampal extract plus db-cAMP. The results suggest that one or several factors in colchicine-lesioned hippocampus promote neurotrophic activity, and the enhancing effect of hippocampal extract on cellular differentiation may act, at least in part, through a mechanism distinct from that for db-cAMP.

Colchicine as an investigative tool in neurobiology

Neurotoxicants are being used with increasing frequency in neurobiology as investigative tools to study the structure and function of the nervous system. Colchicine administered directly into the hippocampus produces preferential destruction of dentate gyrus granule cells and mossy fibers and affects conditioned behavior. Studies from our laboratory have demonstrated the dose- and time-dependent loss of dentate gyrus granule cells and stimulation of motor activity following intradentate administration of colchicine. Preferential degeneration of pyramidal cells and other morphological changes observable at the light microscopic level were not seen in colchicine-treated rats. Other studies showed that intradentate colchicine produces specific damage to granule cells in both the dorsal and ventral hippocampus and that this damage is associated with depletion of dynorphin, a neuropeptide preferentially localized in the granule cells and mossy fibers of the hippocampus. Finally, it was noted that there are compensatory changes in the nervous system following treatment with colchicine and that the behavioral effects of colchicine can be modified by factors such as handling. One potentially important compensatory change occurring after intradentate colchicine is an alteration in cholinergic function. Pharmacological studies suggest that colchicine-treated rats may be less sensitive to the behavioral effects of scopolamine. These experiments support the conclusion that given at the appropriate dose into the hippocampus, colchicine may be a useful investigative tool to study the function of the dentate gyrus granule cells and mossy fibers, as well as the compensatory changes in the nervous system that follow chemical-induced neurodegeneration.

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.

Time-dependent neurobiological effects of colchicine administered directly into the hippocampus of rats

Rats were given bilateral injections of colchicine into the dorsal and ventral hippocampus. Behavioral, neurochemical and histopathological measurements were taken, up to 12 weeks after surgery. Colchicine produced a consistent increase in spontaneous motor activity, enhanced acoustic startle reactivity, and accelerated acquisition of two-way shuttle box avoidance, but did not affect reactivity to a noxious thermal stimulus. Measurement of dynorphin in the hippocampus indicated that colchicine rapidly depleted this neuropeptide, which is thought to be contained preferentially in the mossy fibers of granule cells of the hippocampus. Colchicine also decreased Met-enkephalin in the hippocampus, but the magnitude of the change (22%) was less than that (89% depletion) observed for hippocampal dynorphin. Examination of hippocampal morphology using light microscopic techniques indicated that colchicine caused approximately 60% degeneration of granule cells in the hippocampus. Although the length of the pyramidal cells was decreased (12-16%), the width of the CA1 and CA3 region of the hippocampus was not affected. These data underscore the importance of the granule cells in the mediation of behavioral processes such as motor activity, startle reactivity and performance of shuttle box avoidance.

Experiential factors in the expression of hypermotility produced by intradentate colchicine: lack of effect of GM1 ganglioside on colchicine-induced loss of granule cells and mossy fibers

Adult male Fischer-344 rats were given bilateral injections of 2.5 micrograms colchicine or artificial cerebrospinal fluid into caudal and rostral sites of the dentate gyrus of the hippocampus. One group of rats received 21 consecutive daily injections of 20 mg/kg GM1 gangliosides, i.p., beginning the day prior to surgery. Another group received saline. Colchicine-induced hypermotility was not seen in animals repeatedly handled 21 d after surgery, in spite of significant decreases in granule cell number and decreases in the volume of hippocampal mossy fibers. Pretreatment with GM1 had no effect on behavior and it did not protect against the hippocampal damage produced by colchicine. Rats given colchicine, but not handled for 21 d, showed significant hypermotility, which was associated with decreases in hippocampal granule cells. These data underscore the importance of handling in postlesion functional recovery.