Hippocampal Abnormalities and Enhanced Excitability in a Murine Model of Human Lissencephaly

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The Journal of Neuroscience, April 1, 2000, 20(7):2439-2450

Hippocampal Abnormalities and Enhanced Excitability in a Murine Model of Human Lissencephaly
Mark W. Fleck¹, Shinji Hirotsune², Michael J. Gambello², Emily Phillips-Tansey¹, Gregory Suares¹, Ronald F. Mervis³, Anthony Wynshaw-Boris², and Chris J. McBain¹
¹ Laboratory of Cellular and Molecular Neurophysiology, National Institute of Child Health and Human Development, National Institutes of Health, Bethesda, Maryland 20892, ² Genetic Disease Research Branch, National Human Genome Research Institute, National Institutes of Health, Bethesda, Maryland 20892, and ³ Neuro-Cognitive Research Labs, Columbus, Ohio 43212

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Human cortical heterotopia and neuronal migration disorders result in epilepsy; however, the precise mechanisms remain elusive.Here we demonstrate severe neuronal dysplasia and heterotopiathroughout the granule cell and pyramidal cell layers of micecontaining a heterozygous deletion of Lis1, a mouse model of human17p13.3-linked lissencephaly. Birth-dating analysis using bromodeoxyuridinerevealed that neurons in Lis1+/ $-$ murine hippocampus are born atthe appropriate time but fail in migration to form a defined celllayer. Heterotopic pyramidal neurons in Lis1+/ $-$ mice were stuntedand possessed fewer dendritic branches, whereas dentate granulecells were hypertrophic and formed spiny basilar dendrites fromwhich the principal axon emerged. Both somatostatin- and parvalbumin-containinginhibitory neurons were heterotopic and displaced into both stratumradiatum and stratum lacunosum-moleculare. Mechanisms of synaptictransmission were severely disrupted, revealing hyperexcitabilityat Schaffer collateral-CA1 synapses and depression of mossy fiber-CA3transmission. In addition, the dynamic range of frequency-dependentfacilitation of Lis1+/ $-$ mossy fiber transmission was less thanthat of wild type. Consequently, Lis1+/ $-$ hippocampi are proneto interictal electrographic seizure activity in an elevated [K⁺]_o model of epilepsy. In Lis1+/ $-$ hippocampus, intense interictalbursting was observed on elevation of extracellular potassiumto 6.5 mM, a condition that resulted in only minimal burstingin wild type. These anatomical and physiological hippocampal defectsmay provide a neuronal basis for seizures associated withlissencephaly.

Key words: lissencephaly; platelet-activating factor acetylhydrolase; knockout mouse; hippocampus; bromodeoxyuridine; Golgi; epilepsy; potassium

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

A number of genetic mutations that disrupt normal development of the human cerebral cortex have been described (for review,see Walsh, 1999). Classical or Type I lissencephaly defines asubgroup of human neuronal migration disorders characterized bygeneralized agyria/pachygyria, four abnormal cortical layers,enlarged ventricles, generalized neuronal heterotopias, and corpuscallosum defects (Barkovich et al., 1991; Dobyns and Truwit 1995).In the United States, ~1 in 40,000 infants is born annually withType I lissencephaly, including isolated lissencephaly sequence(ILS) and Miller-Dieker syndrome (MDS). These infants presentwith severe cognitive and motor impairments and often die fromseizures early in life. The defective gene, PAFAH1B1 also knownas LIS1, was identified from patient samples with informativedeletions of 17p13.3 (Reiner et al., 1993) and confirmed whendominant point mutations and a hemizygous intragenic deletionof the LIS1 gene were found in ILS patients (Lo Nigro et al.,1997). The LIS1 gene (Reiner et al., 1993) encodes a brain-specific,45 kDa noncatalytic subunit of platelet-activating factor acetylhydrolase-1b(PAFAH1b) (Hattori et al., 1994), an enzyme that inactivatesPAF.

Seizures are universal in humans with Type I lissencephaly (Dobyns et al., 1993). Precisely how a deficiency of LIS1 proteindisrupts normal brain development and precipitates seizures isunknown. The anatomical defects seen in Type I lissencephaly andthe developmental pattern of LIS1 protein expression are consistentwith an important role in neuronal migration (Reiner et al., 1995;Albrecht et al., 1996). The demonstration that PAF collapses neuronalgrowth cones (Clark et al., 1995) and reduces neuronal migrationin vitro (Bix and Clark 1998) suggests that PAF may play a rolein CNS development. PAFAH1b has strong evolutionary conservation,and in nonmammalian organisms (e.g., Aspergillus nidulans) itsortholog, nudF, is required for nucleus translocation along elongatedprocesses (Morris et al., 1998a). In the mammalian brain, PAFAH1b1interacts with elements of the microtubule network (Morris etal., 1998b; Sapir et al., 1997), strengthening the connectionbetween LIS1 protein and neuronal migration. Experimental supportfor abnormal neuronal migration in lissencephaly has come frommice with a hemizygous deletion of the Lis1 gene. Lis1+/ $-$ micepossess similar developmental brain abnormalities observed inILS and MDS as well as reduced cell migration both in vivo andin vitro, and they display lethal tonic-clonic seizures (Hirotsuneet al., 1998).

Although the anatomical disruptions of the cerebral cortex in ILS and MDS are profound and have been well studied, much lessis known about the hippocampus. Dilatation of the posterior hornsof the lateral ventricles is common in Type I lissencephaly (Pilzand Quarrell, 1996) suggesting incomplete development of adjacentstructures, including the hippocampus. However, no detailed anatomicaldata exist on the hippocampus in Type I lissencephaly. In addition,the functional consequences of abnormal or incomplete migrationthat might account for cognitive impairments or seizure generationhave not been examined at the cellular or synaptic level. Thisreport describes the hippocampal disorganization in a mouse modelof human Type I lissencephaly and may provide a basis for epilepsyrelated to neuronal migrationdefects.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Lis1 mutant mice
The mutant Lis1 allele designated Lis1^ex6neo-8 (or Lis1-neo) was generated by gene targeting, as previously described (Hirotsune etal., 1998). All animal experiments were performed under protocolsapproved by the National Human Genome Research Institute and NationalInstitute of Child Health and Human Development Animal Care andUse Committees and followed the National Institutes of HealthGuidelines Using Animals in Intramural Research.

Histology, immunohistochemistry, Golgi analysis, and bromodeoxyuridine birth dating
Immunohistochemistry. Adult mice were deeply anesthetized with isofluorane (Ohmeda, Liberty Corner, NJ) and transcardiallyfixed with 0.9% NaCl and 4% paraformaldehyde. Hippocampal sections(50 µm) were prepared on a freezing microtome. Slices were incubatedfor 3 hr at room temperature with anti-calretinin (1:500, Chemicon,Temecula, CA), anti-human somatostatin (1:100, Dako, Glostrup,Denmark), or monoclonal anti-parvalbumin (PV) (1:1000, Sigma,St. Louis, MO). Polyclonal anti-calbindin (CB) D-28K (1:400, Chemicon)was incubated at 4°C for 48 hr. For calretinin and calbindin immunohistochemistry,sections were incubated overnight at 4°C with biotinylated goatanti-rabbit IgG (1:200, Vector Laboratories, Burlingame, CA);for parvalbumin immunohistochemistry, biotinylated goat anti-mouseIgG (1:200, Sigma) was used. For somatostatin, unconjugated goatanti-rabbit IgG (1:200, Vector) at 4°C was used followed by a1 hr incubation with rabbit peroxidase anti-peroxidase (1:100,Sigma). All proteins were visualized using diaminobenzidine. Immunostainedsections were then Nissl-counterstained (see below) to revealthe location of the heterotopic cells of interest in relationto the multiple pyramidal celllayers.
Histology. For Nissl staining, 1% cresyl violet acetate was applied to sections for 1 min, rinsed with dH₂O, followed by differentiationin 70% ethanol/2% glacial acetic acid. Stained sections were dehydratedin ethanol andcoverslipped.
Golgi analysis. Blocks of coronally cut 10% formalin-fixed mouse brain encompassing the hippocampus were stained with therapid Golgi method as detailed elsewhere (Valverde, 1976). Forthe Golgi study, seven wild-type controls and four Lis1+/ $-$ micewere used. Briefly, the blocks were impregnated using osmium tetroxideplus potassium dichromate followed by immersion in silver nitrate.After dehydration, the blocks were embedded in nitrocellulose,and coronal sections were cut at 120 µm. For dendritic analysisof CA1 pyramidal neurons, camera lucida drawings of the basilartree were prepared. The extent and distribution of dendritic branchingof the CA1 neurons was evaluated by Sholl analysis. Statisticalsignificance was evaluated using a repeated measures ANOVA witha Bonferroni post hoc test. The total dendritic length for thebasilar tree of each CA1 neuron was calculated by tracing cameralucida drawings with a planimeter. Statistical analysis was performedby ANOVA followed by the Tukey post hoctest.
Bromodeoxyuridine birth dating. Pregnant dams were injected at embryonic day (E) 11, 13, 14, 15, and 17, and pups were killedat postnatal day (P) 30. Hippocampi were sectioned (50 µm). DNAwas denatured by a 60 min incubation in 2N HCl. Slices were blockedfor 60 min using unconjugated anti-mouse IgG (1:10, Sigma), thenincubated with anti-bromodeoxyuridine (BrdU) IgG (1:20-1:100,Becton Dickinson). Biotinylated goat anti-mouse (1:100, Sigma)was used as a secondary antibody. BrdU expression was visualizedusing ABC (Vector) anddiaminobenzidine.

Hippocampal electrophysiology
Transverse hippocampal slices (350-400 µm) were obtained from P28-60 mice as described previously (Maccaferri and McBain,1995). Mice were anesthetized by volatile inhalation of isofluoraneand decapitated. Hippocampal slices were prepared in standardice-cold artificial CSF (ACSF) (see below) containing 0.5 mM CaCl₂and 10 mM MgSO₄. For recording, slices were bathed in ACSF containing(in mM): 130 NaCl, 24 NaHCO₃, 3.5 KCl, 1.25 NaH₂PO₄, 2.5 CaCl₂,1.25 MgSO₄, 10 glucose, 95% O₂/5% CO_2, pH 7.3. For current-clamprecordings, electrodes contained (in mM): 130 K-gluconate, 10NaCl, 10 HEPES, 0.2 EGTA, 1 MgCl₂, pH 7.2, and 0.5% biocytin.For voltage-clamp experiments, electrodes contained (in mM): 80CsCl, 50 CsF, 10 HEPES, 10 EGTA, 1 QX-314, 1 MgCl₂, 0.5 CaCl_2,and 0.5%biocytin.
Extracellular recordings were made using low-resistance patch pipettes filled with gassed extracellular solution. Stimulatingelectrodes (Frederick Haer and Co., Bowdoinham, ME, stainlesssteel) were positioned in the appropriate cell layer using infrared-DICoptics, and brief constant current pulses (50-100 µsec) were usedto evoke field EPSPs (fEPSPs). Mossy fiber synaptic events weredistinguished from associational/commissural inputs to CA3 bythe use of Group 2 metabotropic glutamate receptor agonists (mGluRs):(2S,2'R,3'R)-2-(2',3'-dicarboxycyclopropyl)glycine (DCG-IV) 100nM or (1S,3R)-1-aminocyclopentane-1,3-dicarboxylic acid (ACPD)1 µM. In all experiments involving mossy fiber transmission, theDCG-IV (or ACPD)-sensitive record was subtracted out of the totaltrace to allow analysis of mossy fiber synaptic activity inisolation.
In the "High [K⁺]_o" model of epilepsy, [K⁺]_o was sequentially elevated from 3.5 to 6.5, 8.5, and 10.5 mM. Extracellular recordingsof spontaneous and evoked interictal bursts were acquired usingClampfit or Axoscope (Axon Instruments). Burst intensity was estimatedas described previously (Korn et al., 1987). Briefly, the entirelength of the burst waveform was measured, and an identical burst-freesegment was subtracted. The resulting digital value termed the"coastline bursting index" (CBI) is correlated with the intensityof the underlying activity and expressed in arbitrary units. Twentyspontaneous events per condition were analyzed, and the resultswereaveraged.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Hippocampal histopathology

We have shown previously that mice with a hemizygous deletion of the Lis1 gene possess developmental brain abnormalities associatedwith the cortex, olfactory bulb, and hippocampus (Hirotsune etal., 1998). In the present study we now focus on the hippocampalformation to determine the nature and extent of these structuralabnormalities and how they impact hippocampal synaptic function,and we use a combination of anatomical and electrophysiologicaltechniques.

The principal cell layers (i.e., CA subfields and granule cell layer) of the Lis1+/ $-$ mouse hippocampus are severely disorganized.Figure 1 illustrates cresyl violet-stained sections of adult wild-typeand Lis1+/ $-$ hippocampus. Pyramidal cell somata in both CA1 andCA3 are heterotopic and loosely packed, and they often formedmultiple distinct cell layers with many cells displaced throughoutstratum oriens to the alvear surface (Fig. 1). These heterotopicbands appear to radiate throughout the entire subfield and areinterspersed with single cells (presumably inhibitory interneurons)between adjacent bands of principal cells. Disruption of the dentategyrus granule cell layer was less severe. Although granule cellsusually were not heterotopic, they were "loosely" packed intoa cell layer, but clusters of granule cells were often observeddeep within the hilar layer, blurring the granule cell-hilar border.In Figure 1B3, only the upper blade of the granule cell layerwas dispersed, whereas the lower blade was more "normal." In general,either blade of the granule cell layer could show disruption,and the abnormalities associated with Lis1 deficiency were notrestricted to the upper or lower blade of the dentate gyrus. Thehippocampi of several hundred Lis1+/ $-$ mice have now been analyzed,and although the severity of the heterotopia was quite variable,the pattern of disruption and heterotopia described above is stereotypicalof these animals.

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Figure 1. Heterotopia of the Lis1+/ $-$ hippocampus. Nissl-stained sections of adult Lis1+/ $-$ mouse hippocampus reveal the cellular disorganization and heterotopia of the principal cell layers. A1, The normal wild-type hippocampus (5×) is characterized by tightly packed CA1 and CA3 pyramidal (A2, 25×) and granule cell layers (DG) (A3, 25×), typically only a few cells thick. In contrast, severe pyramidal neuron heterotopia exists in the Lis1+/ $-$ hippocampus (B1-B3, 5×). In CA1, the pyramidal cell layer is loosely packed, with cells forming distinct, multiple layers that radiate from the stratum oriens/alveus into the stratum radiatum (B2, 25×). In the dentate gyrus, the granule cell layer is similarly disorganized into a diffuse band. The upper blade of the dentate gyrus granule cells is more diffusely packed than the lower blade. The loose organization of the granule cell layer obscures the hilar-dentate gyrus border (B3, 25×). st o-a, Stratum oriens-alveus; st. rad, stratum radiatum; st. pyr, stratum pyramidale. Scale bars: A1, B1, 250 µm; A2, A3, B2, B3, 66 µm.

BrdU birth dating reveals a normal pattern of neurogenesis but incomplete neuronal migration

Developmental processes within the hippocampus follow patterns similar to development of the neocortex, with the exceptionof the long-lasting neurogenesis of the dentate gyrus granulecells and their "outside-in" gradient of positioning (Cowan etal., 1980). Hippocampal principal cells migrate along the radialglia and are positioned in the hippocampal plate following an"inside-out" gradient. By E14-15 principal neurons are sandwichedbetween populations of GABAergic neurons in the subplate and theinner marginal zone, which are destined to become the stratumoriens and stratum radiatum, respectively (Soriano et al., 1994).Thus each plexiform layer of the developing hippocampus is populatedby a characteristic neuronal population, the distribution of whichdoes notoverlap.

By using bromodeoxyuridine (BrdU) labeling, we determined whether cellular malformation of the Lis1+/ $-$ hippocampus resultedfrom abnormal neurogenesis at a particular developmental timepoint. Pregnant dams were injected with BrdU on E11, 13, 14, 15,and 17 to label actively dividing cells, and the distributionof BrdU-positive cells was examined at P14-30 in Lis1+/ $-$ miceand wild-type littermates (Fig. 2). At E11 only a small numberof BrdU cells were observed. At this time point, however, a significantlyhigher number of BrdU-positive cells were observed in Lis1+/ $-$ CA1 stratum pyramidale than were wild type, perhaps indicatingearly neurogenesis in these animals (Table 1). Most cells inthe CA1-CA3 subfields are born between E13 and E14 in both thewild-type and the Lis1+/ $-$ mouse. The distribution of E13 BrdU-labeledcells was similar in both wild-type and Lis1+/ $-$ animals; cellswere observed throughout all subfields. Furthermore, similar numbersof BrdU-positive cells were generated in both wild type and Lis1+/ $-$ (Table 1). E14 BrdU-labeled neurons were most numerous in thetightly packed stratum pyramidale in wild type; however, mostBrdU-positive cells in the Lis1+/ $-$ hippocampus were observed throughoutthe entire CA subfield from the stratum oriens-alveus to the stratumlacunosum-moleculare. We were particularly struck by the observationthat BrdU-labeled cells were observed throughout all of the heterotopicbands of pyramidal cells in the CA1 subfield and were not restrictedto a particular band at a particular developmental time point.This suggests that many of the cells within these discreet bandsof stratum pyramidale are generated at a similar time point; however,these clusters of cells fail in migration to consolidate intoa single cell layer. A significantly lower number of E14 BrdU-labeledcells were observed in the extra pyramidal cell layers (i.e.,stratum radiatum, oriens-alveus, and lacunosum-moleculare). Itis unclear whether this reflects a true reduction in cell numbersor the difficulty in counting cells when multiple bands of interlacedprincipal cells are present throughout all CA1 subfields. By E15and E17, BrdU labeling was markedly reduced in both CA1 and CA3subfields but remained high in the granule cell layer of the dentategyrus (Table 1). A significantly lower number of E15 BrdU-positivecells were observed in both Lis1+/ $-$ CA1 and CA3 stratum pyramidale(Table 1).

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Figure 2. BrdU birth dating reveals appropriate neurogenesis. BrdU birth dating was used to determine whether neurons are born at the appropriate point in development in the Lis1+/ $-$ hippocampus. In tissue sections (P30) from animals injected with BrdU at embryonic day 11 (E11), BrdU labeled relatively few cells located primarily at the hippocampal fissure, the hilus, the molecular layer, and the subiculum in wild-type animals. A similar pattern of BrdU labeling was observed in the Lis1+/ $-$ hippocampus. By E13, BrdU-labeled neurons were distributed widely throughout all hippocampal subfields. In wild type, BrdU-labeled neurons were primarily observed in both the dentate gyrus-hilus, and in stratum pyramidale, stratum oriens, stratum radiatum, and subiculum. In Lis1+/ $-$ hippocampus, BrdU-labeled cells were widely distributed throughout all subfields from the stratum oriens-stratum radiatum. High numbers of BrdU-labeled cells were also observed in the granule cell layer and hilus. In E14 injected animals, most wild-type BrdU-labeled cells were observed in a tight, well defined band analogous to the principal cell layers of the dentate gyrus and pyramidal cell layer. In the Lis1+/ $-$ animal, although similar numbers of neurons were BrdU-labeled (Table 1), neurons had failed to fully complete migration and were diffusely scattered throughout the CA1 subfield and the dentate gyrus. In addition, large numbers of BrdU-labeled cells were observed in the fimbria-fornix areas. By E17, BrdU labeling declined in the CA subfields and was highest within the dentate gyrus cell layer of both wild-type and Lis1+/ $-$ hippocampus. st. or, Stratum oriens-alveus; st. rad, stratum radiatum; st. pyr, stratum pyramidale; sub, subiculum; hf, hippocampal fissure.


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Table 1. Developmental expression pattern of BrdU-positive cells in wild-type and Lis1+/ $-$ mice

Although cells in both wild-type and Lis1+/ $-$ hippocampus are generated in nearly identical numbers (with few exceptions) atsimilar embryonic time points (Table 1), it is worthwhile notingthat the scattered distribution of cells in the adult Lis1+/ $-$ hippocampus does not allow us to determine whether heterotopiccells represent principal cell types or reflect an altered neurogenesisof inhibitory interneuron types. However, these data further demonstratethat the characteristic organization of the embryonic and earlypostnatal murine hippocampus is severely disrupted. This presumablyresults not from significant changes in the numbers of neuronsbeing generated but an altered migration of both principal andinhibitory interneurons. Similar data were observed in three independentexperiments.

Golgi analysis of hippocampal neuron anatomy

CA1 pyramidal neurons
We next examined pyramidal cell anatomy in brains of adult Lis1+/ $-$ mice and wild-type littermates after Golgi impregnation(Fig. 3). To evaluate anatomical differences, we compared thebasilar dendritic arbor of CA1 pyramids in (1) control wild-typecells, (2) cells that had migrated to a location equivalent tostratum pyramidale, and (3) heterotopic pyramidal cells "stranded"in stratum oriens or stratum radiatum in the Lis1+/ $-$ hippocampus.We chose to study the basilar dendritic tree because it was representativeof morphological changes across the entire dendritic tree (i.e.,both apical and basilar dendrites were similarly affected). Thedendritic arbors of neurons from both wild-type and Lis1+/ $-$ cellslocated within stratum pyramidale were not significantly different.In contrast, the dendritic arbor of heterotopic pyramidal cellswas significantly smaller compared with both cell types (Fig.3). Sholl analysis revealed that heterotopic pyramidal neuronsmade significantly fewer dendritic intersections per shell (p< 0.001) than pyramidal neurons. Similarly, the total dendriticlength of heterotopic CA1 pyramidal cells was considerably reduced(949 ± 99 µm, p < 0.001, n = 12 cell from four animals) comparedwith both control (1629 ± 79 µm, n = 20 cells from four animals)and regular CA1 pyramidal neurons (1564 ± 114 µm, n = 35, fromseven animals). The total number of branch points was also significantlyreduced (~40% of control) in heterotopic pyramidal neurons comparedwith wild-type controls; mean number of branch points was 6.8versus 16.8 per neuron, respectively. Of interest, the dendriticspine density was not different among the three groups; controlwild type = 1.61 ± 0.03 spines per micrometer (n = 35), Lis1+/ $-$ stratum pyramidale neurons = 1.63 ± 0.04 (n = 20), Lis1+/ $-$ ectopicpyramidal cells = 1.45 ± 0.09 (n = 12). These data reveal thatneurons, within the presumed stratum pyramidale, are anatomicallysimilar to wild type; however, heterotopic cells stranded withinstratum oriens or stratum radiatum possess dendrites that arestunted and make fewer branches.

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Figure 3. The basal dendrites of CA1 pyramidal neurons in the Lis1+/ $-$ hippocampus are stunted and possess few branches. A, Camera lucida drawings of six representative Golgi-stained CA1 pyramidal neuron basal dendrites from wild-type and Lis1+/ $-$ hippocampus. Two groups of CA1 pyramids were analyzed in the Lis1+/ $-$ hippocampus: those cells located in a cell layer most likely representing the stratum pyramidale (Regular) and those cells stranded in migration in the stratum oriens (Heterotopic). Note that heterotopic pyramidal neurons possess a significantly less elaborate dendritic arbor than both wild-type and regularly positioned Lis1+/ $-$ CA1 pyramids. B, Sholl analysis reveals that the basal dendrites of regular Lis1+/ $-$ (n = 20 pyramids) and wild-type (n = 35) CA1 pyramids are similar. In contrast, the dendrites of heterotopic Lis1+/ $-$ neurons (n = 12) make significantly fewer intersections per shell and have a significantly reduced total dendritic length (C).

Dentate gyrus granule cells
Granule cells of adult mice lack basal dendrites (Seress and Mrzljak 1987; Spigelman et al., 1998), although they are transientlyexpressed during postnatal development. A recent study has demonstrated,however, that basal dendrites are a prominent feature of granulecells in rats with epilepsy induced by high-frequency stimulationof the perforant path, a model of temporal lobe epilepsy (Spigelmanet al., 1998). Spiny basilar dendrites have also been describedin dentate granule cells from adult epileptic human tissue (Francket al., 1995). We next analyzed the anatomy of Golgi-stained dentategyrus granule cells. Similar to pyramidal neurons, granule cellsthat migrated to a presumed cell layer were indistinguishablefrom wild-type granule cells. Striking abnormalities were observed,however, in heterotopic granule cells located in both the molecularlayer and the subgranular region of the hilus (Fig. 4). HeterotopicLis1+/ $-$ dentate granule cells were hypertrophic and possesseda high incidence of spiny basilar dendrites from which emergedthe mossy fiber axon. The diameters of granule cell somata werenot different among the three cell groups (wild-type, normallypositioned, and heterotopic granule cells); however, the somataof heterotopic granule cells were extremely spiny (Fig. 4). Furtheranalysis of the presence of spiny basilar dendrites in wild-typeand heterotopic Lis1+/ $-$ granule cells demonstrated that 17% ofwild-type granule cells (80 of 468 cells analyzed from 10 animals)possessed more than three spines (but fewer than eight) on theirsomata, but none possessed basal dendrites. In contrast, 83% ofheterotopic Lis1+/ $-$ granule cells (86 of 103 cells analyzed fromfour animals) possessed both spiny (>10 spines) somata and basilardendrites.

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Figure 4. Hypertrophy of dentate gyrus granule cells and a decreased dynamic range of mossy fiber synaptic transmission in Lis1+/ $-$ . A, Representative camera lucida drawings of Golgi-impregnated dentate gyrus granule cells from wild type (left) and Lis1+/ $-$ (right). Wild-type granule cells possess spiny apical dendrites, lack spines on their soma, and have an axon that emerges from the basal pole of the soma. In contrast, heterotopic Lis1+/ $-$ granule cells located in the subgranular region have spiny basal dendrites (indicated by arrows) that give rise to the axon. Note that both the somata and basal dendrites are extremely spiny in both cases. The inset shows digital image of spiny soma and basal dendrites of the left Lis1+/ $-$ granule cell. Scale bars for main panels and inset: 15 µm. B, C, The dynamic range of frequency facilitation is reduced in Lis1+/ $-$ mossy fiber-CA3 synapses. B, Amplitude of mossy fiber fEPSPs evoked at various stimulation frequencies before and after induction of LTP in wild type (left) and Lis1+/ $-$ (right). Mossy fiber synapses were stimulated at a frequency of 0.0125 Hz. Arrows indicate changes in the stimulation frequency (0.025, 0.05, 0.1, 0.2, and 0.33 Hz). Marked facilitation was observed at frequencies as low as 0.05 Hz. After induction of LTP (4 × 100 Hz, 1 sec, 0.03 Hz), the stimulus intensity was decreased to avoid possible nonlinearities during frequency facilitation (Salin et al., 1996). Data are normalized to fEPSPs obtained at 0.025 Hz. Right trace shows the identical experiment performed at mossy fiber synapses in Lis1+/ $-$ ; arrows are not shown in right trace for clarity. C, Summary graph from eight representative experiments in both wild type and Lis1+/ $-$ shows the range of frequency facilitation before and after LTP induction normalized to 0.025 Hz. The dynamic range of frequency facilitation is significantly less in Lis1+/ $-$ animals before the induction of LTP (p < 0.001, two-tailed Student's t test). After LTP the degree of facilitation is reduced both in wild type and in Lis1+/ $-$ at frequencies above 0.05 Hz. After LTP the degree of facilitation was similar in both Lis1+/ $-$ and wild type (p = 0.1, two-tailed paired Student's t test).

Heterotopia of parvalbumin- and somatostatin-containing interneurons

The profound cellular disorganization in both human lissencephaly and Lis1+/ $-$ mouse clearly involves large numbers of pyramidalneurons. To determine whether local circuit inhibitory interneuronsare similarly affected, we examined the distribution of immunohistochemicallydefined subpopulations of interneurons in the hippocampus of Lis1+/ $-$ mice and littermate controls (Fig. 5).

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Figure 5. Heterotopic somatostatin- and parvalbumin-containing interneurons in the Lis1+/ $-$ hippocampus. Immunohistochemical techniques were used to determine the expression pattern of markers specific for inhibitory interneuron populations. A1, A2, In wild-type hippocampus, parvalbumin (PV) is found in interneurons whose somata are located primarily in the stratum pyramidale and stratum oriens. A2 illustrates a higher magnification of the boxed region in A1. The somatodendritic profile of these cells is generally perpendicular to the principal cell layer. The axons of PV interneurons are largely confined to stratum pyramidale and form a dense plexus around the somata of pyramidal cells. B1, B2, The distribution of PV-containing interneurons in Lis1+/ $-$ sections closely resembled those found in wild type. Somas maintained their associations with the stratum oriens and stratum pyramidale layers, whereas their axonal processes remained in stratum pyramidale. Consequently, PV-containing interneurons appeared in multiple bands caused by the disorganization of the Lis1+/ $-$ stratum pyramidale. B2 illustrates the boxed region in B1 at a higher magnification. Note that PV-positive cell bodies are found in both heterotopic principal cell layers. All immunostained sections have been Nissl-counterstained to allow visualization of the inhibitory interneurons relative to the heterotopic principal cell layers. C1, C2, In wild-type hippocampus, somatostatin (SOM)-containing interneurons were predominantly found in CA1 stratum oriens-alveus. The CA3 subfield contains a broader distribution of SOM interneurons with somas found in stratum pyramidale, stratum lucidum, and stratum radiatum. The hilar region of the dentate gyrus also contained numerous SOM-positive interneurons. C2, Higher magnification of the boxed region indicated that C1 shows typical somatostatin-containing cells of the CA1 stratum oriens. These cells typically possess horizontally oriented somata and dendrites. D1, D2, In the CA1 subfield of the Lis1+/ $-$ hippocampus (5×, 25×), numerous SOM-containing interneurons were observed not only in the stratum oriens but were dispersed throughout the clusters of CA1 pyramids and deep within the stratum radiatum areas (the boxed region in D1 is shown at high magnification in D2). In this particular hippocampus, the pyramidal neurons are loosely packed as revealed by the Nissl counterstain. The asterisks indicate where the CA1 pyramidal cell layer divides into two heterotopic principal layers. Note that somatostatin cells (indicated by the solid arrows) are found in the region between the two principal cell layers as well as in the stratum radiatum proper. The hilus and CA3 distribution of SOM interneurons remained normal in Lis1+/ $-$ murine brains. Scale bars: A1, 325 µm; A2, 125 µm; B1, 365 µm; B2, 135 µm; C1, 315 µm; C2, 125 µm; D1, 300 µm; D2, 100 µm.

In the wild-type hippocampus, the somata of PV-containing interneurons are predominantly located near or within the stratumpyramidale and stratum oriens (Fig. 5A1,A2). Their axons are restrictedto stratum pyramidale where they form symmetrical synapses onthe somata, proximal dendrites, and axon initial segments of pyramidalneurons (Freund and Buzsaki, 1996). In Lis1+/ $-$ mice, the distributionof PV-immunoreactive interneurons paralleled the disruption ofstratum pyramidale, although the cells themselves were anatomicallysimilar to wild type. It is worthwhile noting that although thesomata of PV cells were typically associated with heterotopicpyramidal neurons (Fig. 5B1,B2), they were also often observedwithin stratumradiatum.

Somatostatin-positive interneurons (SOM) account for ~15% of GABAergic cells in the murine hippocampus (Freund and Buzsaki,1996). In the CA1 subfield they are normally confined to the stratumoriens-alveus (Fig. 5C1,C2) and are activated in a feedback mannerby the axons of CA1 pyramidal neurons (Maccaferri and McBain,1995). The distribution of SOM-immunoreactive interneurons inLis1+/ $-$ mice resembled that of wild type with one notable exception;SOM-positive interneurons were frequently observed in CA1 stratumradiatum of Lis1+/ $-$ hippocampus, subjacent to the innermost pyramidalneurons or between the blades of the heterotopic pyramidal celllayers (Fig. 5D1,D2). Such cells were never observed in wild-typehippocampus. In contrast, the distribution of CB and calretinin-containinginterneurons was normal in Lis1+/ $-$ mice (data notshown).

Synaptic connectivity, physiology, and plasticity

Given the abnormal cellular organization of the hippocampus, we next considered whether synaptic connections were correctlyestablished. Using in vitro hippocampal slices, we performed alaminar analysis of field EPSPs (fEPSPs). A stimulating electrodewas placed at a fixed position within the stratum radiatum ofCA1, and an extracellular electrode was moved sequentially fromstratum oriens to stratum lacunosum-moleculare of CA1. In thecontrol hippocampus, stimulation of the Schaffer collateral/commissuralfibers evoked positive-going EPSPs in stratum oriens (Fig. 6A).A negative inflection was superimposed on the EPSP when the recordingelectrode was positioned within stratum pyramidale, which correspondsto the synchronous firing of the pyramidal cell population. Anegative potential was generated in stratum radiatum correspondingto the current sink of the apical dendrites of active CA1 pyramidalneurons. As expected from the disruption of the pyramidal celllayer into multiple layers, the laminar profile of Lis1+/ $-$ hippocampuswas severely disrupted. In all slices tested, synchronous populationspikes were observed throughout all regions of the CA1 subfield.The population spike was typically combined with a negative potentialrepresenting the fEPSP, which could be recorded in isolation furthertoward the inferior stratum radiatum where few pyramidal cellbodies were observed. This field potential reversed polarity onlywhen measurements were made at the stratum oriens-alveus border(Fig. 6A, top trace). This indicates that both inferior and superiorpyramidal cells are functionally innervated and capable of contributingto information flow through the hippocampal circuit.

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Figure 6. Disruption of Schaffer collateral synaptic transmission in the CA1 hippocampus. A, Laminar analysis of Schaffer collateral evoked fEPSPs reveals multiple current sinks in the Lis1+/ $-$ hippocampus. A stimulating electrode was placed at a fixed position within the stratum radiatum of both wild-type and Lis1+/ $-$ hippocampi. The recording electrode was positioned sequentially in stratum radiatum, stratum pyramidale, and the alveus. In wild-type hippocampus, stimulation of the Schaffer collateral/commissural inputs evoked a negative-going fEPSP in the stratum radiatum (3), which is generated as an active current sink of the apical dendrites of the CA1 pyramids. As the recording electrode was moved into stratum pyramidale (2), a single negative-going population spike superimposed on a positive-going fEPSP was observed. In the alveus (1), a positive-going fEPSP was observed, which represents the source currents of the active pyramids. In contrast, laminar field analysis of the Lis1+/ $-$ hippocampus revealed multiple active current sinks throughout all layers of the CA1 subfield. Despite the presence of two distinct pyramidal cell layers, fEPSPs were always negative going, reflecting that synaptic inputs occur over a broadened pyramidal dendritic field. Scale bars: left panel, 43 µm; right panel, 55 µm. B, Averaged input-output curves of Schaffer collateral/commissural evoked fEPSP (measured as the slope of the initial fEPSP) and fPS amplitude were generated for both wild-type (n = 9) and Lis1+/ $-$ (n = 10) slices. Data were normalized to both the maximal evoked fEPSP (or fPS) and the stimulus intensity range in each experiment to permit comparison between the two groups. In the Lis1+/ $-$ hippocampus, both the fEPSP and fPS input-output curves were shifted to the left of the control wild-type hippocampus, indicating an increased excitability and lower threshold for synaptic transmission in the knockout. C, Schaffer collateral/commissural evoked fEPSPs (recorded in stratum radiatum) revealed that the degree of paired-pulse facilitation at all stimulus intervals was similar between wild-type (n = 6) and Lis1+/ $-$ hippocampus (n = 10).

To determine whether synaptic transmission was abnormal in the Lis1+/ $-$ hippocampus, we analyzed the input-output (I-O) curvesof both the Schaffer collateral evoked fEPSP and the field populationspike (fPS) (Fig. 6B). I-O curves were normalized to the maximalstimulus intensity and the maximal field response to allow a comparisonbetween slices, and between wild type versus Lis1+/ $-$ . Both thefEPSP and the fPS I-O curves in Lis1+/ $-$ (n = 10) were shiftedto the left compared with wild-type controls (n = 9). At a stimulusintensity that activated 50% of the maximal fPS and fEPSP in wildtype, the same stimulus evoked 68 ± 4% and 62 ± 3% in Lis1+/ $-$ ,respectively, demonstrating an enhanced excitability in the Lis1+/ $-$ CA1 pyramidal cell layer (p = 0.01, Student's t test). The maximalfEPSP and fPS evoked in Lis1+/ $-$ CA1 pyramidal cell layer was notsignificantly different from wild type; mean maximal fEPSP = 1.65± 0.28 mV (n = 10) compared with 1.50 ± 0.32 mV (n = 9) in control,mean maximal fPS = 6.34 ± 0.89 mV (n = 10) compared with 5.64± 0.86 mV (n = 9) in control. In contrast, fEPSP I-O curves fromassociational/commissural inputs (n = 7) or mossy fibers (n =7) onto Lis1+/ $-$ CA3 pyramidal neurons were not different fromwild type (n = 6) (data notshown).

We next examined short- and long-term mechanisms of plasticity of excitatory synapses onto both CA1 and CA3 pyramidalneurons.

Schaffer collateral-CA1 synapses
Paired-pulse facilitation was not different between Lis1+/ $-$ and wild-type hippocampus (Fig. 6C). Potentiation of the fEPSPslope peaked at an interval of ~50 msec with a maximal enhancementof 52.9 ± 5.8 and 45.9 ± 13.5% (n = 6) in Lis1+/ $-$ and wild-typehippocampus, respectively. Similarly, post-tetanic potentiationand long-term potentiation (LTP) (three trains of 100 Hz × 1 secduration) at Schaffer collateral-CA1 synapses were normal in Lis1+/ $-$ hippocampus. LTP was stable for at least 30 min after inductionand averaged 133.7 ± 4.1% (n = 10) for Lis1+/ $-$ versus 135.4 ±6.3% (n = 6) for wild type (data notshown).
Using whole-cell current- and voltage-clamp recordings, CA1 pyramidal neurons had resting membrane potentials of $-$ 50.4 ± 1.5mV and input resistances of 140 ± 13 M $Omega$ , values similar to thoseof wild-type neurons. Threshold for action potential generationwas $-$ 39.3 ± 2.4 mV, and action potentials were themselves notunusual, with 10-90% rise time of 0.8 ± 0.1 msec and half-widthsof 2.1 ± 0.28 msec (n =8).

Mossy fiber-CA3 synapses
We next determined whether the granule cell hypertrophy in the Lis1+/ $-$ mouse altered transmission at mossy fiber synapses.Using extracellular field recordings, we studied frequency-dependentfacilitation at mossy fiber synapses, which in striking contrastto associational/commissural synapses onto CA3 pyramidal neuronsexhibit temporal integration even at very low stimulation frequencies(Salin et al., 1996). Figure 4B,C shows experiments in which thestimulus frequency was increased in a series of steps from 0.025to 0.33 Hz. At wild-type mossy fiber synapses, facilitation occurredat frequencies as low as 0.05 Hz and reached a magnitude of morethan sixfold (642.1 ± 92.1%, n = 8) at 0.33 Hz, similar to previousreports (Salin et al., 1996). Consistent with previous reports,the magnitude of facilitation was markedly reduced by the inductionof LTP (4 × 100 Hz, 0.03 Hz, in the presence of 50 µM DL-APV),which acts to increase the probability of transmitter release.At 0.33 Hz the maximal facilitation was now 48% of control (312± 34.6%, n = 8). Identical experiments in Lis1+/ $-$ revealed thatmossy fiber-CA3 synapses possessed a significantly smaller degreeof facilitation at all frequencies tested compared with wild type:the maximal facilitation at 0.33 Hz was 400.3 ± 43.0 (n = 8, p< 0.001, two tailed Student's t test). After LTP induction, thedynamic range of frequency facilitation was reduced further; themaximal facilitation measured at 0.33 Hz was 59% (237 ± 23.5%,n = 8) of that seen during the control period. Of interest, thedegree of maximal facilitation (measured at 0.33 Hz) observedin both wild type and Lis1+/ $-$ after induction of LTP was not significantlydifferent (312 ± 34.6 in control versus 237 ± 23.5 in Lis1+/ $-$ ,p = 0.1). The magnitude of LTP (30 min after induction) observedat both wild-type and Lis1+/ $-$ mossy fiber synapses was not significantlydifferent (298 ± 51% in wild type, n = 8 vs 276 ± 32% in Lis1+/ $-$ ,n = 8,). Taken together these data demonstrate that mossy fibersynapses in the Lis1+/ $-$ are less excitable than wild type. Moreover,under control conditions the dynamic range of facilitation inthe Lis1+/ $-$ is less than wild type, attributable in part to adifference in the initial release probability of the Lis1+/ $-$ mossyfibersynapses.

The Lis1+/ $-$ hippocampus is predisposed to electrographic activity in the elevated [K⁺]_o model of epilepsy.

Seizures are practically universal in humans with Type I lissencephaly (Dobyns et al., 1993). Lethal tonic-clonic seizureswere observed in several Lis1 mutant mice (of all ages) but todate have not been studied in any detail (Hirotsune et al., 1998);however, spontaneous epileptiform activity was not observed inthe extracellular field potential recorded from the in vitro hippocampus.Because neurotransmission at both mossy fiber and Schaffer collateralsynapses was altered, we wanted to determine whether the Lis1+/ $-$ hippocampus was susceptible to electrographic seizureactivity.

Extracellular field potentials were recorded from hippocampal CA1 stratum pyramidale exposed to modest elevations of [K⁺]_o, the so-called High K⁺ model of epilepsy, a model for status epilepticus (McBain etal., 1993). In general, both wild-type and Lis1+/ $-$ slices didnot display spontaneous interictal bursts until [K⁺]_o was elevated to 6.5 mM (Fig. 7). Intense, spontaneous interictalbursts were observed in all Lis1+/ $-$ slices on exposure to 6.5mM [K⁺]_o (n = 14) (Fig. 7A,B). In contrast, only ~75% of wild-type slicesreached bursting threshold in 6.5 mM [K⁺]_o (n = 13); however, these bursts were usually composed of onlythree to five spike trains, in contrast to the hypersynchronousevents recorded under similar conditions in the Lis1+/ $-$ slices.These data are consistent with the enhanced excitability of Schaffercollateral-CA1 synapses observed in the input-output experiments.

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Figure 7. The Lis1+/ $-$ hippocampus is predisposed to interictal burst firing. Extracellular recording electrodes were positioned within the stratum pyramidale to monitor the threshold and intensity of spontaneous interictal bursts in response to elevation of [K⁺]_o. A shows two representative experiments from wild-type and Lis1+/ $-$ hippocampal slices. In wild-type hippocampus, interictal bursts were initiated in 75% of slices exposed to 6.5 mM [K⁺]_o (n = 13) (A, B). Bursts in 6.5 mM [K⁺]_o were generally small and consisted of small clusters of spikes of low intensity. In wild type, the most intense, robust bursts were observed in 8.5 mM [K⁺]_o. At 10.5 mM [K⁺]_o, spontaneous interictal activity decreased in intensity, and clusters of spikes became disorganized (A, B). In contrast, interictal burst firing was observed in all Lis1+/ $-$ exposed to 6.5 mM [K⁺]_o, and was most intense compared with all other [K⁺]_o (A, B). Burst intensity decreased on further elevation of Lis1+/ $-$ slices to 8.5 and 10.5 mM [K⁺]_o. B, Histograms to show the mean coastline bursting index (Mean CBI) for both wild-type and Lis1+/ $-$ interictal bursting in all [K⁺]_o conditions. Interictal bursting in Lis1+/ $-$ slices was significantly more intense at 6.5 mM [K⁺]_o than wild type (p < 0.0001).

To compare interictal burst intensity in different [K⁺]_o, we used the method of coastline bursting index (Korn et al., 1987)to quantify the electrographic waveform. CBI is sensitive to changesin the number or amplitude of population spikes, and it increaseswhen neuronal synchrony, firing frequency or duration, or thenumber of participating neurons increases. In wild-type slices(n = 13), interictal bursts were most intense in 8.5 mM [K⁺]_o. The relative CBIs were 286 ± 103, 544 ± 178, and 263 ± 177in 6.5, 8.5, and 10.5 mM [K⁺]_o, respectively (Fig. 7B). In contrast, interictal bursting inthe Lis1+/ $-$ hippocampus (n = 14) was most intense at 6.5 mM [K⁺]_o and had a CBI approximately fourfold greater than wild type(mean 863 + 80, p < 0.0001, Student's unpaired t test). In Lis1+/ $-$ slices, burst intensity waned on exposure to 8.5 and 10.5 mM [K⁺]_o (mean CBI = 319 ± 120 and 88 ± 36, respectively). It is worthwhilementioning that the maximal interictal burst intensity in wild-typeslices was always significantly less than the maximal burst intensityobserved in Lis1+/ $-$ slices at 6.5 mM [K⁺]_o.

In 6.5 mM [K⁺]_o, interictal burst frequency was similar in both wild-type and Lis1+/ $-$ slices (0.15 ± 0.03, n = 13 and 0.16± 0.03 Hz, n = 14, respectively). In contrast, in 8.5 mM [K⁺]_o, burst frequency more than doubled in the Lis1+/ $-$ slices (0.35± 0.05 Hz), whereas the frequency of bursts in wild type remainedunchanged (0.18 ± 0.07 Hz). In experiments in which we recordedsimultaneously from two heterotopic bands of CA1 pyramidal neurons,interictal bursts were synchronous in the extracellular recordingfrom both cell layers, suggesting that despite belonging to distinctcell layers both sets of cells are paced by an identical mechanism(data notshown).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

ILS and MDS result from haplo-insufficiency at chromosome 17p13.3, and recent evidence has determined that mutation or deletionof the LIS1 gene within band 17p13.3 is responsible for lissencephaly.The conservation of linkage between the human 17p13.3 and themouse 11B2 gene has permitted the generation of an animal modelfor the study of human lissencephaly (Hirotsune et al., 1998;Walsh 1998, 1999). Although incomplete development of the hippocampalformation has been reported in Type I lissencephaly (Pilz andQuarrell 1996), the anatomical malformations of the hippocampusassociated with ILS or MDS have not been previously describedin detail. In the present study, the Lis1+/ $-$ mouse hippocampusdisplayed malformation and neuronal heterotopia across all principalcell layers. Dysplasia and generalized neuronal heterotopias arecommon features of ILS brains and are presumed to contribute tothe severe mental retardation and seizure disorders commonly associatedwith classical lissencephaly. In addition, we show that hippocampalmalformations within the Lis1+/ $-$ mutant are associated with perturbationsin excitatory synaptic transmission and a lowered threshold forintense interictal burstfiring.

A number of cortical abnormalities have been associated with human epileptogenesis. These include (but are not restrictedto) abnormal dendritic branching (Belichenko et al., 1994), alteredsynaptic transmission (Avoli and Williamson, 1996), loss or compromiseof inhibitory interneuron function (Ferrer et al., 1992), andperturbed receptor subunit expression (Ying et al., 1998a,b).Several of these abnormalities may be responsible for the enhancedexcitability observed in the Lis1+/ $-$ hippocampus.

Golgi analysis of pyramidal cell dendritic arbor revealed that heterotopic CA1 pyramidal neurons possessed less elaboratebasal dendritic trees with fewer branch points than wild type.These findings provide an epigenetic link between migration anddevelopment, because the amount of branching was correlated withthe extent of the heterotopia. In addition, abnormalities of dendriticmorphology are common in cortical neurons of human partial epilepsy(Belichenko et al., 1994), and neuronal modeling studies havedemonstrated that alteration of dendritic morphology can significantlyaffect neuronal firing patterns (Mainen and Sejnowski 1996). Furthermore,mossy fiber sprouting and reorganization in the dentate gyrusare common features of many models of temporal lobe epilepsy.Neuroplastic changes of granule cell dendrites, although lesscharacterized, have been described after tetanic stimulation ofthe perforant path projection, a model of temporal lobe epilepsy(Spigelman et al., 1998). The presence of basilar dendrites extendinginto the subgranular region suggests that these heterotopic granulecells may be postsynaptic targets for mossy fiber axons. Interestingly,mossy fiber transmission was not hyperexcitable as seen in theCA1 subfield, but possessed a lower dynamic range of frequencyfacilitation. Because inhibitory interneurons of the CA3 subfieldare the primary targets of mossy fiber synaptic transmission (Acsádyet al., 1998), it is possible that the narrow range of facilitationof mossy fiber transmission impacts the degree of recruitmentof feedforward inhibition to the CA3 subfield, consequently resultingin an enhancement of hippocampalexcitability.

Although Schaffer collateral excitatory synaptic inputs onto heterotopic CA1 pyramidal neurons were functional, analysis ofthe input-output properties of the fPS and fEPSP revealed enhancedexcitability of the Lis1+/ $-$ CA1 subfield without a change in themaximal fEPSP or fPS amplitude. Whether this reflects an alterationin the inhibitory-excitatory "balance" within the hippocampusattributable to alterations in inhibitory interneuron innervationor alternatively to an alteration of receptor subunit expressionremains to be determined. Whole-cell patch-clamp recordings fromindividual Lis1+/ $-$ CA1 pyramidal neurons revealed no change inneuronal resting membrane potential, input resistance, or thresholdfor action potential generation. This enhancement of synaptictransmission presumably contributes to the lowered threshold andintense epileptogenesis observed in the Lis1+/ $-$ mouse. How doesan absence of LIS1 protein alter synaptic function? In additionto its role in neuronal migration, PAF also regulates synaptictransmission and has been identified as a retrograde transmitterin various forms of LTP (Kato et al., 1994; Kato and Zorumski1996). Increased concentrations of PAF have also been shown toresult in massive glutamate exocytosis (Bazan and Allan, 1996),reducing the readily releasable pool of transmitter, which mayaccount for the lower degree of synaptic facilitation observedat mossy fiber synapses. Taken together, it is possible that thealterations of synaptic transmission seen in the present experimentsare a secondary consequence of the reduction of LIS1 protein,Pafah1b1, which presumably will impact PAF metabolism. The roleof PAF regulation of synaptic activity is presumably independentfrom its role in development andmigration.

Numerous animal models of epilepsy have been generated by compromise of various aspects of GABAergic inhibitory neurotransmission.Although we did not detect a loss of any specific inhibitory interneuronpopulation, both somatostatin- and parvalbumin-containing interneuronswere ectopically placed in the CA1 stratum radiatum. Both interneurontypes represent distinct populations of GABAergic cells involvedin the regulation of neuronal excitability and the generationof intrinsic oscillations (Freund and Buzsaki, 1996). The axonsof PV interneurons were observed to form "baskets" around heterotopicpyramidal cell somata, suggesting that these cells correctly innervatedtheir targets despite marked heterotopia of the principal celllayer. Neurogenesis of nonpyramidal, GABAergic interneurons thatlie within the pyramidal layer (presumably parvalbumin-positivecells) occurs within the hippocampal plate and simultaneouslywith principal neurons (Seress and Ribak 1988; Soriano et al.,1989) and may explain the "accuracy" of the axon targeting. Theaxons of SOM interneurons usually project to the CA1 stratum lacunosum-moleculare(McBain et al., 1994) to regulate the temporoammonic input fromthe entorhinal cortex (Maccaferri and McBain, 1995). Whether SOMinterneurons in the Lis1+/ $-$ hippocampus correctly innervate theirtargets and regulate the temporoammonic input is a subject forfuture study. Although both calbindin and calretinin interneuronswere present and appeared to be positioned within the appropriatelayers of the hippocampus, their characteristic diffuse positionwithin the hippocampus did not permit an accurate assessment ofwhether these cells are positioned correctly. Future analysisof all inhibitory interneurons' axon targets will be requiredto determine whether inhibitory interneurons correctly innervatetheirtargets.

A causal link between cortical and hippocampal malformations and epilepsy is well established (Chavassus-au-Louis et al.,1999). The recently renewed interest in "neuronal migration disorders"has arisen from the availability of a number of animal models(Chavassus-au-Louis et al., 1999; Walsh 1999). Such models currentlyinclude spontaneous murine mutants (e.g., telencephalic internalstructural heterotopia, reeler), gestational teratogenic exposure,exposure to the DNA alkylating agent, methylazoxymethanol, orx-irradiation. Unlike these models, in this study we have investigateda mouse model of a human genetic neuronal migration disorder.How good a model for ILS is the Lis1+/ $-$ animal? The Lis1+/ $-$ micedisplay migration defects in the hippocampus, cortex, and cerebellum(Hirotsune et al., 1998), all areas affected in ILS patients.In addition, behavioral testing has demonstrated motor and cognitiveimpairments in Lis1+/ $-$ mice (R. Paylor, S. Hirotsune, M. Gambello,J. Crawley, and A. Wynshaw-Boris, unpublished observations) thatare consistent with ILS. Although Lis1+/ $-$ hippocampal slices didnot show spontaneous electrographic activity in vitro, the presentstudy has highlighted numerous anatomical defects consistent witha predisposition to electrographic activity. Moreover, in a modelfor status epilepticus, a severe form of epilepsy common in lissencephaly,we demonstrate that Lis1+/ $-$ mice have a reduced threshold forinterictal activity and more intense interictal bursts than seenat any [K⁺]_o in wild-type mice (Fig. 7C). Future experiments are targetedtoward determining the precise mechanisms leading to epileptiformactivity and how antiepileptic drugs impact the epileptiform activityrecorded in the Lis1+/ $-$ hippocampus. Finally, simultaneous recordingsfrom distally located bands of heterotopic CA1 pyramidal neuronsin slices exposed to elevated [K⁺]_o revealed that epileptiform activity occurred synchronously.This suggests that heterotopic regions are functionally linkedto the hippocampal network and support synchronous hyperexcitabilitypresumably driven by common afferents from the CA3 subfield. Takentogether these data would suggest that the Lis1+/ $-$ animal providesan extremely powerful model for Type 1lissencephaly.

In conclusion, we provide a new model for Type 1 lissencephaly-related epilepsy. A 50% reduction in LIS1 protein disruptsthe normal migration of pyramidal neurons, dentate granule cells,and interneurons in the hippocampus. This migrational defect isassociated with both anatomical disorganization and morphologicalabnormalities, including sparse dendritic branching in pyramidalcells and granule cell hypertrophy. Despite this disorganization,some pathways appear to find their appropriate targets, whereasothers do not. The cumulative result of these abnormalities isa hyperexcitable hippocampus. At the moment, we cannot rule outthe possibility that cortical migrational defects also contributeto the human seizure phenotype. This will be tested in the futureusing the conditional Lis1 mutant (Hirotsune et al., 1998) matedto transgenic mice that express Cre exclusively either in thedeveloping cortex or hippocampus. The present data, however, wouldsuggest that more attention should be paid to the hippocampalformation in the various human neuronal migration disorders (Walshet al., 1998) as a possible focus for seizure related activity.How a reduction of Lis1 protein results in such disruption ofhippocampal anatomy and function is at present unclear, but thepresent experiments provide a detailed description of the hippocampalLis1+/ $-$ phenotype in which to study more closely the nature ofthe LIS1protein.

  FOOTNOTES

Received Sept. 1, 1999; revised Jan. 10, 2000; accepted Jan. 12, 2000.

We thank Dr. Katalin Toth for her help throughout this study, Timothy Pindell and Jody McKean for their contribution to theGolgi staining, dendritic analysis, and spine counting, and Drs.Vittorio Gallo and Mark L. Mayer for critically reading thismanuscript.
Correspondence should be addressed to Dr. Chris J. McBain, Laboratory of Cellular and Molecular Neurophysiology, NationalInstitute of Child Health and Human Development, Building 49/5A72,49 Convent Drive, National Institutes of Health, Bethesda, MD20892-4495. E-mail: chrismcb{at}codon.nih.gov.

Dr. Fleck's current address: Department of Pharmacology and Neuroscience, Albany Medical College, A-136 47 New Scotland Avenue,Albany, NY12208.

Dr. Hirotsune's current address: The Institute for Animal Genetics, Odakura, Nishigo, Nishi-Shirakawa Fukushima 961,Japan.

Dr. Gambello's and Dr. Wynshaw-Boris's current address: Departments of Pediatrics and Medicine, School of Medicine, Universityof California San Diego, La Jolla, CA92093.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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