Preliminary evidence of abnormal white matter related to the fusiform gyrus in Williams syndrome: a diffusion tensor imaging tractography study.

Williams syndrome (WS) is a genetic condition caused by a hemizygous microdeletion on chromosome 7q11.23. WS is characterized by a distinctive social phenotype composed of increased drive toward social engagement and attention toward faces. In addition, individuals with WS exhibit abnormal structure and function of brain regions important for the processing of faces such as the fusiform gyrus. This study was designed to investigate if white matter tracts related to the fusiform gyrus in WS exhibit abnormal structural integrity as compared to typically developing (TD; age matched) and developmentally delayed (DD; intelligence quotient matched) controls. Using diffusion tensor imaging data collected from 40 (20 WS, 10 TD and 10 DD) participants, white matter fibers were reconstructed that project through the fusiform gyrus and two control regions (caudate and the genu of the corpus callosum). Macro-structural integrity was assessed by calculating the total volume of reconstructed fibers and micro-structural integrity was assessed by calculating fractional anisotropy (FA) and fiber density index (FDi) of reconstructed fibers. WS participants, as compared to controls, exhibited an increase in the volume of reconstructed fibers and an increase in FA and FDi for fibers projecting through the fusiform gyrus. No between-group differences were observed in the fibers that project through the control regions. Although preliminary, these results provide further evidence that the brain anatomy important for processing faces is abnormal in WS.

Physiological and structural evidence for hippocampal involvement in persistent seizure susceptibility after traumatic brain injury.

Epilepsy is a common outcome of traumatic brain injury (TBI), but the mechanisms of posttraumatic epileptogenesis are poorly understood. One clue is the occurrence of selective hippocampal cell death after fluid-percussion TBI in rats, consistent with the reported reduction of hippocampal volume bilaterally in humans after TBI and resembling hippocampal sclerosis, a hallmark of temporal-lobe epilepsy. Other features of temporal-lobe epilepsy, such as long-term seizure susceptibility, persistent hyperexcitability in the dentate gyrus (DG), and mossy fiber synaptic reorganization, however, have not been examined after TBI. To determine whether TBI induces these changes, we used a well studied model of TBI by weight drop on somatosensory cortex in adult rats. First, we confirmed an early and selective cell loss in the hilus of the DG and area CA3 of hippocampus, ipsilateral to the impact. Second, we found persistently enhanced susceptibility to pentylenetetrazole-induced convulsions 15 weeks after TBI. Third, by applying GABA(A) antagonists during field-potential and optical recordings in hippocampal slices 3 and 15 weeks after TBI, we unmasked a persistent, abnormal APV-sensitive hyperexcitability that was bilateral and localized to the granule cell and molecular layers of the DG. Finally, using Timm histochemistry, we detected progressive sprouting of mossy fibers into the inner molecular layers of the DG bilaterally 2-27 weeks after TBI. These findings are consistent with the development of posttraumatic epilepsy in an animal model of impact head injury, showing a striking similarity to the enduring behavioral, functional, and structural alterations associated with temporal-lobe epilepsy.

Neonatal exposure to a novel environment enhances the effects of corticosterone on neuronal excitability and plasticity in adult hippocampus.

Electrophysiological studies have shown that activation of glucocorticoids receptors (GRs) influences neuronal excitability and activity dependent synaptic plasticity. In developmental studies, early life stimulation such as neonatal handling results in an up-regulation of glucocorticoid-receptor (GR) binding in the hippocampus that persists into adulthood. It is, therefore, hypothesized that early environment-induced changes in receptor sensitivity to corticosterone (CORT) might have functional effects on adult neuronal excitability and synaptic plasticity. To test this hypothesis, we exposed rats daily from post-natal days 1-21 to a non-home environment for 3 min. When the animals became adults, we studied the effects of glucocorticoid hormone corticosterone (CORT) on population spike (PS) amplitude and long-term potentiation of population spikes (PS-LTP) in vitro in the hippocampal CA1 region following activation of the Schaffer collateral fibers. Bath application of CORT reduced PS amplitude and subsequent induction of PS-LTP. This inhibitory effect of CORT was significantly greater in the slices from the novelty exposed rats (Novel) than the control rats that remained in their home cage (Home). Inhibition of population spike amplitude during CORT perfusion was 28.0+/-5.3% of baseline in Novel slices, and 9.1+/-4.4% in Home slices. CORT pre-exposure (20 min) also inhibited the subsequent induction of PS-LTP in Novel slices by 57.7+/-17.7% and by 7.5+/-12.1% in Home slices. These results provide electrophysiological evidence that neonatal novelty exposure results in functional increases in receptor sensitivity to CORT that enhances the inhibitory effects of CORT on field CA1 neuronal excitability and plasticity.

NMDA receptor-dependent plasticity of granule cell spiking in the dentate gyrus of normal and epileptic rats.

Because granule cells in the dentate gyrus provide a major synaptic input to pyramidal neurons in the CA3 region of the hippocampus, spike generation by granule cells is likely to have a significant role in hippocampal information processing. Granule cells normally fire in a single-spike mode even when inhibition is blocked and provide single-spike output to CA3 when afferent activity converging into the entorhinal cortex from neocortex, brainstem, and other limbic regions increases. The effects of enhancement of N-methyl-D-aspartate (NMDA) receptor-dependent excitatory synaptic transmission and reduction in gamma-aminobutyric acid-A (GABA(A)) receptor-dependent inhibition on spike generation were examined in granule cells of the dentate gyrus. In contrast to the single-spike mode observed in normal bathing conditions, perforant path stimulation in Mg(2+)-free bathing conditions evoked graded burst discharges in granule cells which increased in duration, amplitude, and number of spikes as a function of stimulus intensity. After burst discharges were evoked during transient exposure to bathing conditions that relieve the Mg(2+) block of the NMDA receptor, there was a marked increase in the NMDA receptor-dependent component of the EPSP, but no significant increase in the non-NMDA receptor-dependent component of the EPSP in normal bathing medium. Supramaximal perforant path stimulation still evoked only a single spike, but granule cell spike generation was immediately converted from a single-spike firing mode to a graded burst discharge mode when inhibition was then reduced. The induction of graded burst discharges in Mg(2+)-free conditions and the expression of burst discharges evoked in normal bathing medium with subsequent disinhibition were both blocked by DL-2-amino-4-phosphonovaleric acid (APV) and were therefore NMDA receptor dependent, in contrast to long-term potentiation (LTP) in the perforant path, which is induced by NMDA receptors and is also expressed by alpha-amino-3-hydroxy-5-methyl-4-isoxazoleproprionate (AMPA) receptors. The graded burst discharge mode was also observed in granule cells when inhibition was reduced after a single epileptic afterdischarge, which enhances the NMDA receptor-dependent component of evoked synaptic response, and in the dentate gyrus reorganized by mossy fiber sprouting in kindled and kainic acid-treated rats. NMDA receptor-dependent plasticity of granule cell spike generation, which can be distinguished from LTP and induces long-term susceptibility to epileptic burst discharge under conditions of reduced inhibition, could modify information processing in the hippocampus and promote epileptic synchronization by increasing excitatory input into CA3.

Synaptic and axonal remodeling of mossy fibers in the hilus and supragranular region of the dentate gyrus in kainate-treated rats.

Seizures evoked by kainic acid and a variety of experimental methods induce sprouting of the mossy fiber pathway in the dentate gyrus. In this study, the morphological features and spatial distribution of sprouted mossy fiber axons in the dorsal dentate gyrus of kainate-treated rats were directly shown in granule cells filled in vitro with biocytin and in vivo with the anterograde lectin tracer Phaseolus vulgaris leucoagglutinin (PHAL). Sprouted axon collaterals of biocytin-filled granule cells projected from the hilus of the dentate gyrus into the supragranular layer in both transverse and longitudinal directions in kainate-treated rats but were not observed in normal rats. The sprouted axon collaterals projected into the supragranular region for 600-700 microm along the septotemporal axis. Collaterals from granule cells in the infrapyramidal blade crossed the hilus and sprouted into the supragranular layer of the suprapyramidal blade. Sprouted axon segments in the supragranular layer had more terminal boutons per unit length than the axon segments in the hilus of both normal and kainate-treated rats but did not form giant boutons, which are characteristic of mossy fiber axons in the hilus and CA3. Mossy fiber axons in the hilus of kainate-treated rats had more small terminal boutons, fewer giant boutons, and there was a trend toward greater axon length compared with mossy fibers in the hilus of normal rats. With the additional length of supragranular sprouted collaterals, there was an overall increase in the length of mossy fiber axons in kainate-treated rats. The synaptic and axonal remodeling of the mossy fiber pathway could alter the functional properties of hippocampal circuitry by altering synaptic connectivity in local circuits within the hilus of the dentate gyrus and by increasing the divergence of the mossy fiber terminal field along the septotemporal axis.

NMDA receptor dependence of kindling and mossy fiber sprouting: evidence that the NMDA receptor regulates patterning of hippocampal circuits in the adult brain.

The NMDA receptor plays an important role in patterning neural connectivity in the developing brain. In the adult brain, repeated kindling stimulation of limbic pathways increases the NMDA-dependent component of synaptic transmission in granule cells of the dentate gyrus (DG) and also induces sprouting of the mossy fiber axons of granule cells that reorganizes synaptic connections in the DG. Because the NMDA antagonist MK801 impedes the progression of kindling, it was of interest to determine whether MK801 also modified mossy fiber sprouting. Low doses of MK801, which had no antiseizure effect, impaired the progression of kindling and development of mossy fiber sprouting during the initial and also more advanced stages of kindling. These observations demonstrate that the NMDA receptor is a component of a molecular pathway that influences the progression of kindling and mossy fiber sprouting and suggest that NMDA-dependent gene expression may play a role in the development of long-term structural and functional alterations induced by seizures in hippocampal circuitry. The NMDA receptor appears to play a continuing role in modifying the organization and patterns of connectivity in hippocampal circuits of the adult brain.

Ca2+ release from intracellular stores induced by afferent stimulation of CA3 pyramidal neurons in hippocampal slices.

1. Ca2+ imaging and simultaneous intracellular recording were performed on CA3 pyramidal neurons in hippocampal slice cultures and standard acute slices. Both fura-2 and a dextran conjugate of fura-2 (MW = 10,000) were used in the Ca2+ measurements to control for compartmentalization artifacts. Experiments were performed under conditions giving minimal ligand- and voltagegated Ca2+ influx, with the use of competitive and noncompetitive antagonists of ionotropic glutamate receptors and steady-state depolarization, respectively. 2. Tetanic stimulation of stratum lucidum evoked dendritic Ca2+ transients with rapid onset that were blocked by the noncompetitive N-methyl-D-aspartate (NMDA) receptor antagonist, MK-801 (2-5 microM), but not by the competitive alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor antagonist, 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) (10-50 microM). Zn(2+)-containing mossy fiber terminals (assessed by Timm's staining) and postsynaptic structures (thorny excrescences) are preserved in s. lucidum of hippocampal slice cultures. 3. A Ca2+ store loading protocol, consisting of brief repolarizations followed by steady depolarization, primed most of the neurons so that a subsequent tetanus gave a Ca2+ increase in the presence of MK-801 that was reported by both fura-2 and the dextran conjugate. The onset of the Ca2+ increase was significantly delayed (by 2-3 s) with respect to the MK-801-sensitive increase, and often had a different spatial pattern within the neuron. Response characteristics were similar in slice cultures and acute slices. 4. The delayed Ca2+ increase showed a steep rundown with subsequent stimuli, but was restored by further priming by the Ca2+ store loading paradigm. Postsynaptic currents evoked by the tetani under these conditions were not correlated with the magnitude of the delayed Ca2+ transients. 5. Delayed Ca2+ increases were observed in 44% of the neurons dialyzed with normal intracellular solution at room temperature. The success rate of observing delayed Ca2+ transients was increased to 86% in neurons maintained at 30 degrees C, and dialyzed with an inhibitor of the inositol-triphosphate-3-kinase. 6. The delayed Ca2+ transients could not be initiated after inhibition of endosomal Ca(2+)-ATPase-mediated uptake by thapsigargin. 7. Both fura-2 and the dextran conjugate reported increases in resting Ca2+ levels after the loading protocols, that were absent after priming in thapsigargin, and decreases in resting Ca2+ levels after successive tetani in MK-801, suggesting that the Ca2+ changes were largely cytosolic. 8. The present results support the hypothesis that these synaptically mediated, delayed Ca2+ transients represent release from intracellular Ca2+ stores that can be loaded and depleted repeatedly, and are evoked by presynaptic release of endogenous neurotransmitter.

Functional alterations in the dentate gyrus after induction of long-term potentiation, kindling, and mossy fiber sprouting.

1. The effects of long-term potentiation (LTP) and kindling on membrane currents evoked in the dentate gyrus (DG) by stimulation of the perforant path (PP) were studied by current-source density (CSD) analysis in urethan-anesthetized rats. The spatial and temporal patterns of the evoked currents were analyzed after induction of LTP, at 24 h after three afterdischarges (ADs) induced by kindling stimulation, and at 4-5 wk after 70-120 generalized tonic-clonic (class V) kindled seizures. 2. The amplitude of the ipsilateral monosynaptic population excitatory postsynaptic current (iEPSC) evoked in the middle and outer stratum moleculare (STM) of the DG by PP stimulation increased by 20-100% after induction of LTP (N = 7 of 7). There was a trend to shorter onset latency of the iEPSC after induction of LTP, but the duration and spatial distribution of the iEPSC were unchanged (N = 7 of 7). The latency of inward current generated by synchronous granule cell discharge during the population spike decreased by 0.5-1 ms after induction of LTP (N = 6 of 7). 3. There were no significant alterations in the spatial and temporal pattern of the monosynaptic iEPSC evoked by PP stimulation at 24 h after three ADs induced by kindling stimulation (N = 6 of 6), or at 4-5 wk after the last of 70-120 class V kindled seizures (N = 14 of 14). 4. The spatial and temporal distribution of low-amplitude inward currents generated after the population spike was not altered after induction of LTP (7 of 7), or at 24 h after three ADs induced by kindling stimulation (N = 6 of 6). In kindled rats studied at 4-5 wk after the last of 70-120 class V seizures, there was an alteration in evoked currents after the population spike consisting of a distinct peak of net inward current at a latency of 9-12 ms in the proximal STM (N = 10 of 14). Inward current at this latency and location was not observed in > 100 normal rats, in age-matched normal controls (N = 4 of 4), or after acute seizures induced by pentylenetetrazol (35 mg/kg ip, N = 5 of 5). 5. Timm histochemistry was combined with CSD analysis to examine the relationship of the inward current at 9-12 ms to the terminal field of the sprouted mossy fiber pathway, which forms asymmetric, putatively excitatory synapses in the inner STM of the DG in kindled rats. In six of eight kindled rats with sprouted mossy fiber terminals demonstrated by Timm histochemistry, CSD analysis revealed that the peak amplitude of the inward current colocalized with the laminar distribution of sprouted mossy fiber terminals. In the remaining two of the eight kindled rats with sprouted terminals in the inner STM, there was no alteration in the spatial and temporal distribution of inward current after the population spike. 6. In conclusion, LTP and kindling induced distinct alterations in currents evoked in the DG by stimulation of the PP. After induction of LTP, there was an acute increase in the amplitude of the monosynaptic iEPSC and reduction in the latency of currents associated with granule cell discharge, but there was no alteration in the spatial or temporal organization of multisynaptic activity. In contrast, long-lasting effects of kindling included an alteration in the spatial and temporal organization of multisynaptic currents, which was consistent with excitatory synaptic transmission by synaptic terminals of the sprouted mossy fiber pathway. The functional alterations induced by LTP and kindling may have implications for associative properties, information processing, and epileptogenesis in the DG.

Bilateral organization of parallel and serial pathways in the dentate gyrus demonstrated by current-source density analysis in the rat.

1. Membrane currents evoked in the dentate gyrus (DG) by stimulation of afferent pathways from the entorhinal cortex (EC) and contralateral DG were examined by current-source density (CSD) analysis in urethan-anesthetized rats. Stimulation of each afferent pathway evoked membrane currents with distinct spatial and temporal organization in the DG. CSD and anatomic analysis revealed that afferent input from the EC activated the DG bilaterally through parallel and serial pathways. The analysis provided a detailed description of the location, timing, and relative amplitude of evoked monosynaptic and multisynaptic currents in the DG. 2. Orthodromic stimulation of the perforant path (PP) evoked a large ipsilateral excitatory postsynaptic current (iEPSC) at a latency of 2.5-4 ms in the middle and outer stratum moleculare (STM) of the DG, and a population spike that was generated by an excitatory inward current at a latency of 5-9 ms in the stratum granulosum. 3. A variable, low-amplitude ipsilateral inward current followed the population spike at a latency of 13-16 ms in the inner STM, which is the site of synaptic terminals of the associational and commissural pathways arising from neurons in the hilus of the DG. Orthodromic stimulation of the commissural pathway from the hilus of the contralateral DG also evoked an inward current in the inner STM at a latency of 2-6 ms, which was 40-60% of the amplitude of the monosynaptic iEPSC. 4. Orthodromic stimulation of the EC evoked a low-amplitude contralateral excitatory postsynaptic current (cEPSC) at a latency of 3-6 ms in the outer and middle STM of the contralateral DG, which was generated by monosynaptic transmission in the sparse crossed pathway from the EC. In contrast to the variable, low-amplitude inward current in the inner STM that followed the iEPSC, the cEPSC was consistently followed by a large inward current at a latency of 8-14 ms in the inner STM of the contralateral DG. 5. The large inward current in the inner STM of the contralateral DG was abolished by transection of the PP ipsilateral and rostral to the stimulating electrode, but was unaffected by transection of the PP at a similar location in the hemisphere contralateral to the stimulating electrode. These observations suggested that this current was most likely generated by a multisynaptic pathway involving the ipsilateral PP and the commissural pathway arising from the hilus of the DG. 6. In conclusion, efferents from the EC activated the DG bilaterally by parallel and serial pathways. Parallel monosynaptic pathways from the EC activated homologous distal segments of granule cell dendrites bilaterally, by a massive input to the ipsilateral DG and a sparse input to the contralateral DG. Sequential propagation from the EC through a multisynaptic pathway that included the commissural pathway from the hilus of the DG bilaterally activated the proximal segments of granule cell dendrites at longer latencies. The amplitude of the multisynaptic currents generated by serial pathways in the proximal dendrites varied inversely with the amplitudes of the monosynaptic currents evoked by parallel pathways in the distal dendrites. These observations may have implications for synaptic integration, associative properties, and information processing in the DG.

Genetic analysis of thyroid hormone receptors in development and disease.

Thyroid hormone (T3) fulfills diverse functions in vertebrate development and physiology. These functions are thought to be mediated by two genes encoding the related T3 receptors. TR alpha and TR beta. The use of homologous recombination in embryonic stem cells to generate defined, single-gene mutations provides a powerful means to investigate the individual functions of TR alpha and TR beta in mice. We have shown that targeted inactivation of the TR beta gene results in goiter and elevated levels of thyroid hormone. Thyroid stimulating hormone (TSH), which is released by pituitary thyrotropes and is normally suppressed by increased levels of thyroid hormone, was present at elevated levels in homozygous mutant (Thrb-/-) mice. These findings suggest a unique role for TR beta that cannot be substituted by TR alpha in the T3-dependent feedback regulation of TSH transcription. Thrb-/- mice provide a recessive model for the human syndrome of resistance to thyroid hormone (RTH). Typically, RTH is associated with dominant mutations in TR beta. It is unknown whether TR alpha, TR beta, or other receptors are targets for inhibition in dominant RTH; however, the analysis of Thrb-/- mice suggests that antagonism of TR beta-mediated pathways underlies the disorder of the pituitary-thyroid axis. Thrb-/- mice also display defective maturation of auditory function, demonstrating that TR beta is essential for the development of hearing. Interestingly, hearing defects are generally absent in dominant RTH, indicating that in the auditory system, a dominant TR beta mutant cannot mimic the defect caused by loss of TR beta. This suggests the existence of tissue-specific mechanisms that modulate the activity of TR beta. These results define in vivo functions for TR beta and indicate that specificity in T3 signaling is conferred by distinct receptor genes.

Alteration of long-lasting structural and functional effects of kainic acid in the hippocampus by brief treatment with phenobarbital.

Kainic acid, an analog of the excitatory amino acid L-glutamate, induces acute hyperexcitability and permanent structural alterations in the hippocampal formation of the adult rat. Administration of kainic acid is followed by acute seizures in hippocampal pathways, neuronal loss in CA3 and the hilus of the dentate gyrus, and reorganization of the synaptic connections of the mossy fiber pathway. Rats with these hippocampal structural alterations have increased susceptibility to kindling. To evaluate the role of the acute seizures and associated hippocampal structural alterations in the development of this long-lasting susceptibility, rats that received intraventricular kainic acid were cotreated with phenobarbital (60 mg/kg, s.c., once daily). Treatment with this dose for 5 d after administration of kainic acid suppressed acute seizure activity, protected against excitotoxic damage in the dentate gyrus, reduced mossy fiber sprouting, and completely abolished the increased susceptibility to kindling associated with kainic acid. Brief treatment with phenobarbital modified the pattern of damage and synaptic reorganization in the dentate gyrus in response to seizure-induced injury, and altered the long-lasting functional effects associated with hippocampal damage. As phenobarbital treatment did not protect against neuronal damage in CA3 or other regions of the hippocampus, the circuitry of the dentate gyrus was implicated as a locus of cellular alterations that influenced the development of kindling. These observations are evidence that pharmacological intervention can prevent the development of epilepsy in association with acquired structural lesions, and suggest that pharmacological modification of cellular responses to injury can favorably alter long-term functional effects of CNS damage.

Septotemporal variation of the supragranular projection of the mossy fiber pathway in the dentate gyrus of normal and kindled rats.

Previous studies have demonstrated regional variation in the anatomical organization and physiological properties of the hippocampus along its septotemporal (dorsoventral) axis. In this study, regional variation of the supragranular projection of the mossy fiber pathway in the dentate gyrus of normal and kindled rats was characterized with a scoring method for assessment of the distribution of mossy fiber synaptic terminals detected by Timm histochemistry. In normal rats, there was a sparse projection of the mossy fiber pathway into the supragranular region near the tips and crest of the dentate gyrus along the entire septotemporal axis, and a prominent projection into the supragranular region at the temporal pole. Kindling of the perforant path, amygdala, and olfactory bulb induced synaptic reorganization of the mossy fiber pathway into the supragranular region along the entire septotemporal axis of the dentate gyrus. There was regional variation of the seizure-induced synaptic reorganization along this axis, and distinct septotemporal patterns were observed as a function of the site of kindling stimulation. Kindling of the perforant path induced mossy fiber synaptic reorganization that was relatively more prominent in the septal pole than in the temporal pole of the dentate gyrus. In contrast, rats that received kindling stimulation of the amygdala had a more uniform distribution of synaptic reorganization along the septotemporal axis. As there is regional variation of the anatomical and physiological properties of the human epileptic hippocampus, these observations could be pertinent to human epilepsy.

Activation of the dentate gyrus by pentylenetetrazol evoked seizures induces mossy fiber synaptic reorganization.

Kindled seizures evoked by electrical stimulation of limbic pathways in the rat induce sprouting and synaptic reorganization of the mossy fiber pathway in the dentate gyrus (DG). To investigate whether seizures evoked by different methods also induce reorganization of this pathway, the distribution of mossy fiber terminals in the DG was examined with Timm histochemistry after systemic administration of pentylenetetrazol, a chemoconvulsant that reduces Cl- mediated GABAergic inhibition. Myoclonic seizures evoked by subconvulsant doses of pentylenetetrazol (24 mg/kg i.p.) were not accompanied by electrographic seizures in the DG, and did not induce mossy fiber sprouting. Generalized tonic-clonic seizures evoked by repeated administration of PTZ (24 mg/kg i.p.) were consistently accompanied by electrographic seizure activity in the DG, and induced sprouting and synaptic reorganization of the mossy fiber pathway. The results demonstrated that repeated generalized tonic-clonic seizures evoked by pentylenetetrazol induced mossy fiber synaptic reorganization when ictal electrographic discharges activated the circuitry of the DG.

Assessing the functional significance of mossy fiber sprouting.

In recent years, a variety of histological techniques have provided evidence that the mossy fiber pathway in the dentate gyrus undergoes sprouting and reorganization of its synaptic connections in association with kindling, other experimental models of epilepsy, and human epilepsy. Although the neural circuitry of the dentate gyrus has been identified as a site of cellular and molecular alterations that influence the development of epilepsy by kindling, the functional effects of mossy fiber synaptic reorganization have not been defined. There has been rapid progress in the characterization of morphological alterations induced by seizures in the dentate gyrus and other pathways, but information on many fundamental aspects of hippocampal organization that could influence excitability are not available. Emerging evidence which suggests a possible link between synaptic reorganization and functional alterations in hippocampal circuitry needs to be considered in the context of limited information about critical details of hippocampal organization, the growing evidence for a diversity of seizure-induced cellular and molecular alterations that may alter excitability, and with awareness that mechanisms for generation of seizures may vary at different stages in the evolution of kindling and other epileptic syndromes. Efforts to characterize the role of synaptic reorganization and other specific cellular and molecular alterations in the generation of epileptic activity need to address this variety and complexity of potential mechanisms.

Mossy fiber synaptic reorganization induced by kindling: time course of development, progression, and permanence.

Recent studies have revealed that mossy fiber axons of granule cells in the dentate gyrus undergo reorganization of their terminal projections in both animal models of epilepsy and human epilepsy. This synaptic reorganization has been demonstrated by the Timm method, a histochemical technique that selectively labels synaptic terminals of mossy fibers because of their high zinc content. It has been generally presumed that the reorganization of the terminal projections of the mossy fiber pathway is a consequence of axonal sprouting and synaptogenesis by mossy fibers. To evaluate this possibility further, the time course for development of Timm granules, which correspond ultrastructurally to mossy fiber synaptic terminals, was examined in the supragranular layer of the dentate gyrus at the initiation of kindling stimulation with an improved scoring method for assessment of alterations in Timm histochemistry. The progression and permanence of this histological alteration were similarly evaluated during the behavioral and electrographic evolution of kindling evoked by perforant path, amygdala, or olfactory bulb stimulation. Mossy fiber synaptic terminals developed in the supragranular region of the dentate gyrus by 4 d after initiation of kindling stimulation in a time course compatible with axon sprouting. The induced alterations in the terminal projections of the mossy fiber pathway progressed with the evolution of behavioral kindled seizures, became permanent in parallel with the development of longlasting susceptibility to evoked seizures, and were observed as long as 8 months after the last evoked kindled seizure. The results demonstrated a strong correlation between mossy fiber synaptic reorganization and the development, progression, and permanence of the kindling phenomenon.