Abstract
During limbic epileptogenesis in vivo the dentate granule cells (DGCs) exhibit increased expression of brain-derived neurotrophic factor (BDNF), followed by striking morphologic plasticities, namely the formation of basal dendrites and the sprouting of mossy fibers. We hypothesized that increased expression of BDNF intrinsic to DGCs is sufficient to induce these plasticities. To test this hypothesis, we transfected DGCs in rat hippocampal slice cultures with BDNF or nerve growth factor (NGF) via particle-mediated gene transfer, and we visualized the neuronal processes with cotransfected green fluorescent protein. Transfection with BDNF produced significant increases in axonal branch and basal dendrite number relative to NGF or empty vector controls. Structural changes were prevented by the tyrosine kinase inhibitor K252a. Thus increased expression of BDNF within DGCs is sufficient to induce these morphological plasticities, which may represent one mechanism by which BDNF promotes limbic epileptogenesis.
Elucidating the mechanisms of limbic epileptogenesis in cellular and molecular terms may provide novel therapeutic approaches for epilepsy prevention. The discovery that neurotrophin mRNA content is increased during epileptogenesis (Gall and Isackson, 1989) led to the idea that neurotrophic factors may contribute to the lasting structural and functional modifications underlying epilepsy (Gall, 1993).
Among the diverse neurotrophic factors exhibiting increased expression during epileptogenesis, brain-derived neurotrophic factor (BDNF) in particular is implicated as playing a causal role. Specifically, both pharmacological (Binder et al., 1999a) and genetic (Kokaia et al., 1995; Lahteinen et al., 2002) manipulations designed to reduce BDNF expression and/or activation of its receptor, TrkB, delay epileptogenesis. Moreover, transgenic mice overexpressing BDNF exhibit an enhanced response to epileptogenic stimuli (Croll et al., 1999). Together, these results are consistent with the idea that enhanced activation of TrkB by BDNF promotes epileptogenesis.
One population of neurons in which enhanced activation of TrkB may promote epileptogenesis is the dentate granule cells (DGCs) of the hippocampus. Striking increases of BDNF expression have been identified in DGCs in experimental models and humans with epilepsy (Wetmore et al., 1994; Mathern et al., 1997; Yan et al., 1997; Takahashi et al., 1999; Murray et al., 2000). Importantly, increased activation of TrkB receptors in the distribution of DGC axons has been identified in animal models of epileptogenesis (Binder et al., 1999b; He and McNamara, 2002).
Increased TrkB activation in the distribution of DGC axons is of particular interest because these neurons normally serve as a barrier to invasion of hippocampal circuitry by seizure activity (Collins et al., 1983). Importantly, the “barrier function” of granule cells is compromised in epileptic animals (Behr et al., 1998). Compromise of the barrier may be mediated in part by increased recurrent excitatory synapses formed among DGCs in the epileptic condition (Wuarin and Dudek, 1996; Molnar and Nadler, 1999; Okazaki et al., 1999; Lynch and Sutula, 2000; Wuarin and Dudek, 2001). Two distinct morphological plasticities identified in DGCs of the epileptic brain have been proposed to underlie recurrent excitatory synapses among these neurons. One is the sprouting of DGC axons (Nadler et al., 1980; Tauck and Nadler, 1985; Sutula et al., 1989; Babb et al., 1991, which leads to the formation of recurrent excitatory synapses on apical dendrites of granule cells (Frotscher and Zimmer, 1983; Franck et al., 1995; Okazaki et al., 1995; Wenzel et al., 2000). Another is the recently discovered formation of basilar dendrites identified in DGCs in experimental models (Spigelman et al., 1998). By projecting into the hilus, basal dendrites of granule cells become targets for innervation by the rich network of granule cell axons in this region.
Because BDNF and TrkB exert powerful morphoregulatory effects on diverse types of neurons (Horch et al., 1999; Yacoubian and Lo, 2000;Patapoutian and Reichardt, 2001) and because increased expression of BDNF and increased activation of TrkB occur in the mossy fiber pathway of the DGCs during limbic epileptogenesis, we hypothesized that increased expression of BDNF in granule cells is sufficient to induce some of the morphologic plasticities identified in granule cells in limbic epilepsy.
MATERIALS AND METHODS
Organotypic hippocampal explant method. Slice cultures were prepared from 10-d-old (P10) male Sprague Dawley rat pups from multiple mothers (Zivic-Miller, Zelienople, PA) and then maintained via the interface method (Stoppini et al., 1991). All procedures conformed to National Institutes of Health and Institutional guidelines for the care and use of animals. After treatment with ketamine (100 mg/kg, i.p.) the animals were decapitated, brains were bisected in the sagittal plane, and blocks containing the hippocampus and cortex were removed. Slices (400 μm each) were isolated with a McIlwain tissue chopper and plated onto Millicel inserts (Millipore, Bedford, MA) in six-well plates with 1.2 ml of medium (50% minimum essential medium, 25% HBSS, 25% heat-inactivated horse serum, 10 mm HEPES, 0.5% GlutaMaxII (all from Invitrogen, San Diego, CA), and 0.65% glucose (Sigma, St. Louis, MO), pH 7.2, preheated to 37°C. The slices were incubated at 37°C in a 95% CO2/5% O2 air mix. For K252a experiments the tissue culture inserts were transferred to new six-well plates with medium containing either 200 nm K252a (Calbiochem, La Jolla, CA) or 1 μl of DMSO (Sigma) per milliliter of medium, reflecting the final concentration of DMSO resulting from the dilution of K252a stock solution.
Construction and characterization of pro-BDNF/NGF-HA and BDNF-HA.Four plasmids were used in these experiments, BDNF-HA (henceforth referred to as BDNF), pro-BDNF/NGF-HA (henceforth referred to as nerve growth factor, NGF), pEGFP-IRESneo (henceforth referred to as green fluorescent protein, GFP), and pcDNA3 (Invitrogen). The pcDNA3 plasmid lacked an insert and was used as a negative control. The pEGFP-IRESneo plasmid (generous gift of Dr. Nancy Ip, Hong Kong University of Science and Technology) expresses enhanced GFP (EGFP) driven by a CMV promoter in the pIRESneo plasmid (Clontech, Palo Alto, CA). The BDNF plasmid contains the full-length rat BDNF sequence (nucleotides 2123–2842, accession number D10938; National Center for Biotechnology database, Bethesda, MD), followed by a single C-terminal hemagglutinin (HA) tag in a pcDNA3 vector with a CMV promoter. The NGF plasmid contains the rat pro-BDNF sequence (nucleotides 2123–2519, accession number D10938; National Center for Biotechnology database), followed by the mouse NGF precursor sequence (nucleotides 519–836, accession number S62089) with a single C-terminal HA tag in a pcDNA3 vector. Both NGF and BDNF plasmids have consensus Kozak initiation sites. Endogenous BDNF and NGF are expressed in pro-forms that then are cleaved into active BDNF or NGF. The substitution of the pro-BDNF sequence for the pro-NGF sequence does not change the structure of the released NGF protein, but it does change the expression pattern of the NGF protein as assessed by epitope tag immunohistochemistry. Inclusion of the pro-NGF sequence resulted in low levels of NGF in the soma, whereas expression of the pro-BDNF/NGF plasmid resulted in high levels of NGF in the soma (data not shown). Because this latter expression pattern was similar to the expression of transfected BDNF, the pro-NGF/BDNF plasmid served as a better control. BDNF and NGF plasmids were generously provided by Richard Murphy and Stephen Morris (Montreal Neurological Institute, Quebec, Canada).
Particle-mediated gene transfer. Hippocampal slices were transfected by using a particle-mediated gene transfer device according to the manufacturer's protocols (Helios, Bio-Rad, Hercules, CA) 1–4 hr after slice preparation. Briefly, either 16 or 25 mg of 1.6 μm gold particles (Bio-Rad) was coated with the following plasmid combinations: 0.25 μg of GFP/mg gold, 0.25 μg of GFP plus 1.75 μg of empty PCDNA-3 plasmid/mg gold, 0.25 μg of GFP plus 1.75 μg of NGF/mg gold, and 0.25 μg of GFP plus 1.75 μg of BDNF/mg gold. Tissue cultures were transfected in six-well plates at 300 psi. Nylon mesh (90 μm thread spacing) was placed between the barrel of the gene gun and the culture during transfection. At 24 hr after transfection the cultures were fixed for 1.5 hr in 2.5% paraformaldehyde and 4% sucrose. Then the cultures were cryoprotected overnight in 30% sucrose in PBS, frozen on dry ice, and stored at −80°C.
Immunohistochemistry. Frozen cultures were thawed in PBS and blocked for 3 hr in 10% normal goat serum (Invitrogen), 2% BSA (Sigma), and 0.5% Igepal (Sigma) in PBS. All slices (including those transfected with GFP only) were incubated overnight in 5 μg/ml rabbit polyclonal anti-GFP protein antibody (Chemicon, Temecula, CA) and 500 ng/ml rat monoclonal anti-HA peptide antibody (Roche, Mannheim, Germany). Secondary antibodies included 1:400 Oregon green 488 goat anti-rabbit (2 mg/ml stock; Molecular Probes, Eugene, OR) and 1:500 Alexa Fluor 594 goat anti-rat (2 mg/ml stock; Molecular Probes). Slices were rinsed in PBS, mounted to Superfrost Plus slides (Port City Diagnostics, Wilmington, NC), dehydrated, cleared in xylenes, and coverslipped with Krystalon (EM Science, Gibbstown, NJ).
Neuron selection. Small numbers of principal neurons (usually 0–4) were transfected in each culture, making it easy to distinguish the processes of individual neurons. Anatomical criteria were used to identify a neuron as a DGC, CA3 or CA1 pyramidal cell, or interneuron, respectively. For DGCs (1) the soma was located in either the superior blade or crest of the DGC layer or adjacent hilus or molecular layer (within 100 μm), and (2) the dendritic tree exhibited a fan-like spread in the molecular layer of the dentate gyrus and/or an axon in stratum lucidum of CA3. For CA3 pyramidal cells (1) the cell body was located in the CA3 pyramidal cell layer, (2) the apical and basal dendritic fields were as described by Ramon y Cajal (1893) andLorente de No (1934), and (3) the cell displayed a large soma and lack of collateral branches on the proximal apical dendrite relative to CA1 pyramidal cells. CA2 pyramidal cells were grouped with CA3 pyramidal cells. For CA1 pyramidal cells (1) the soma was located in the CA1 pyramidal cell layer, (2) apical and basal dendritic fields typical of a pyramidal cell were present (Ramon y Cajal, 1893; Lorente de No, 1934), and (3) the soma was smaller than CA3 pyramidal cells and collaterals off the proximal apical dendrite were present. In addition to these criteria, those neurons that were selected for analysis had to be filled completely with GFP in the case of DGCs or at least filled out to the more distal regions of the dendrites in the case of pyramidal cells. Furthermore, neurons had to be absent of degenerative changes (e.g., dendritic blebbing). Finally, to verify expression of the cDNA that was being studied, neurons transfected with either BDNF or NGF must have exhibited immunoreactivity for the HA tag. Importantly, neuron selection and analysis were conducted with the experimenter blind to the treatment group.
Neuronal imaging and analysis. Neurons selected for analysis were imaged with a Bio-Rad MRC 600 confocal microscope and a Nikon Fluor 40× oil objective. Endogenous autofluorescence of the tissue provides a Nissl-like stain, making it possible to distinguish hippocampal subfields. Neurons were z-sectioned at 0.5 μm increments, using Kalman filtering and the COMOS software of Bio-Rad (version 7.1). Image stacks were collapsed to make two-dimensional reconstructions of the neurons. Images then were imported into Photoshop, the brightness and contrast were optimized, and montages were made if necessary. Photoshop images were imported into theNeurolucida software program (MicroBrightField, Colchester, VT; version 4.10d), and computerized two-dimensional reconstructions of the neurons were made.
To be counted, axonal branches and apical or basal dendrites had to be at least 10 μm in length. Basal dendrites were counted as those dendrites that originated from the hilar side of the soma, even if the dendrite subsequently curved back into the dentate molecular layer. Transverse spread of the apical dendritic field (Claiborne et al., 1990) and the depth into the molecular layer reached by the longest dendrite also were determined from confocal reconstructions. Axonal branch number and location of the soma within the granule cell layer were determined directly from the tissue slices via the Neurolucidasystem and a Zeiss Axioskop (Oberkochen, Germany) microscope equipped with a motorized stage and a Zeiss Fluor 40× oil objective.
The medial-to-lateral location of each DGC was determined by measuring the distance between the soma and the tip of the superior blade of the DGC layer; distance from the hilus was determined by measuring the distance between the soma and the hilar/granule cell layer border. Neuronal parameters were collected with the accompanying Neuroexplorer software (MicroBrightField, version 3.25).
Primary dendrite number was determined by fluorescent microscopy on aZeiss Axiovert 135 microscope equipped with Zeiss Achroplan 20× [numerical aperture (NA), 0.45] and Zeiss Fluor 40× oil (NA, 1.30) objectives. This system also was used to determine the number of giant mossy fiber boutons. For each DGC the furthest subfield of the mossy fiber pathway reached by the longest axon collateral was determined also; the subfields included the DGC layer, hilus, CA3c, CA3b, and CA3a. Scores of 1, 2, 3, 4, or 5, respectively, were assigned. Fully developed mossy fibers will reach CA3a, whereas less developed fibers will terminate in one of the preceding subfields.
To assess BDNF and NGF expression levels, we captured images of transfected neurons immunostained for HA by a digital camera (Princeton Instruments, Trenton, NJ). Exposure settings were identical for each image. The MetaMorph Imaging program (Universal Imaging, West Chester, PA) then was used to obtain an average gray value over the soma of the transfected neuron minus the background gray value.
Statistical significance was determined by using SigmaStat, version 2.0 (Jandel, San Rafael, CA). In cases in which more than one neuron came from a given culture, the measurements for these neurons were averaged (except for the analysis of neuronal location). The number of slices used is therefore equivalent to the number of neurons that have been examined. Both parametric and nonparametric tests were used as appropriate. Dunn's posttest was used for ANOVAs on ranks. Medians and ranges are reported for nonnormally distributed data, and means and SE values are reported for data that passed the normality test. When used, the percentage of increase was calculated from the means.
RESULTS
BDNF-transfected DGCs have abnormal dendritic fields and increased axonal branching
The morphology of DGCs under control conditions as detected by GFP immunoreactivity was similar to that described in studies using Golgi (Ramon y Cajal, 1893; Lorente de No, 1934) or dye labeling of neurons (Claiborne et al., 1986, 1990). That is, the apical dendritic arbors of DGCs transfected with either GFP alone or GFP and NGF exhibited the characteristic fan-like spread with multiple branches emanating from the soma into the molecular layer and terminating at the hippocampal fissure (Fig. 1, left andmiddle columns, respectively). No obvious differences were detected between DGCs cotransfected with NGF and GFP compared with GFP alone (Fig. 1, compare neurons in left and middle columns).
In contrast to the morphological characteristics of control DGCs, transfection with BDNF resulted in a diversity of abnormalities evident even under casual inspection. The dendritic fields were altered profoundly, as evident in the appearance of basal dendrites emerging from the hilar margin of the DGC soma (Fig. 1, right column,arrows); moreover, the apical dendritic tree was altered in that numerous short branches emanated from the soma and proximal dendritic tree, a pattern sharply contrasting with the fan-like arbor evident in control DGCs. In addition, the axons were altered in that numerous short branches were evident close to the soma, and the caliber of the main axon appeared to be increased relative to controls. In general, DGCs with striking dendritic changes also exhibited increased axonal branching and caliber.
To exclude the possibility that differences in NGF and BDNF expression were responsible for the overt differences in morphology between these groups, we assessed expression levels by immunostaining for the epitope tag HA. Similar levels of HA immunoreactivity were evident for BDNF- and NGF-transfected DGCs (Fig. 2,right panels) as assessed by gray scale analysis [BDNF = 1130 ± 214 (means ± SEM); NGF = 990 ± 246;p = 0.6, Student's t test], thereby demonstrating the specificity of the morphological consequences of BDNF expression. In addition, comparison of HA and GFP immunoreactivity in the same neurons revealed that HA immunoreactivity was much less intense than GFP immunoreactivity (Fig. 2). Whereas GFP immunoreactivity filled the entire neuron, HA immunoreactivity was found routinely only in the granule cell soma and proximal dendrites, less frequently in proximal axons (Fig. 2), and in only a single neuron in the distal axon (data not shown).
BDNF effects on axonal branching: quantitative analyses
In contrast to the paucity of branching of the proximal axon of control DGCs, proximal axons of BDNF-transfected DGCs exhibited increased numbers of branches (Fig. 3,top). Sholl analyses (Sholl, 1953) were used to quantify the number of axonal branch points within 100 μm of the soma. These analyses disclosed a spatially specific effect of BDNF on branch number. That is, an approximately three- to fourfold increase in the number of primary axon branches was evident within 50 μm of the somata of BDNF-transfected neurons (n = 33) compared with NGF-transfected (n = 11) or GFP-transfected (n = 30) neurons (Fig. 3, bottom, Table1) (a priori ANOVA on ranks;p < 0.001 compared with GFP and NGF). These additional branches tended to be short (10–50 μm) and typically did not cross the granule cell layer (see Figs. 1, 3, 5). The effect of BDNF was restricted to the first 50 μm as evident in the similar numbers of branches in the three groups between 50 and 100 μm from the soma (Fig. 3, Table 1). No significant differences in the furthest region of stratum lucidum reached by the longest axon collateral or in the number of giant mossy fiber boutons were detected among the three groups (Table 1). Finally, axon caliber appeared to be increased in BDNF-transfected DGCs relative to GFP- and NGF-transfected granule cells (Figs. 1, 3), but this was not quantified.
BDNF induces the formation of basal dendrites and increases dendritic branching around the somata of DGCs
BDNF increased the number of dendritic processes relatively uniformly around the somata of transfected DGCs (see Figs. 1, 5). This uniformity was striking because the DGCs are polar neurons. Dendrites typically originate only from the apical side of the soma; the basal (hilar) side of the soma typically is devoid of dendrites. Indeed, the majority of GFP- and NGF-transfected DGCs were devoid of basal dendrites; in the remainder (12% of GFP- and 30% of NGF-transfected DGCs) a single basal dendrite was observed. The pattern evident in both the GFP- and NGF-transfected DGCs is similar to that described previously in Golgi studies of normal brain and slice culture (Seress and Pokorny, 1981; Seress and Ribak, 1990; Heimrich and Frotscher, 1991; Zafirov et al., 1994). The results with BDNF stand in sharp contrast to GFP and NGF. That is, basal dendrites were evident in a majority (74%) of BDNF-transfected DGCs, and the majority of these (71%) exhibited multiple, not single, basal dendrites (Fig.4, top left). BDNF likewise produced striking increases in the length of the basal dendrites in comparison to GFP or NGF (Fig. 4, top right). For BDNF-transfected neurons the median basal dendrite length was 170 μm, whereas GFP- and NGF-transfected neurons had medians of zero.
Within the apical dendritic field BDNF transfection also increased the number of short dendritic processes around the soma. Because DGCs normally possess apical dendrites, however, this increase manifested slightly differently (relative to the basal dendritic field). Rather than increasing the number of primary apical dendrites (those dendrites that originate from the apical side of the soma), BDNF transfection led to increased branching of primary apical dendrites. Thus the number of primary apical dendrites was not altered among treatment groups (Table2), but the number of branches off the apical dendrites (secondary dendrites) was increased in regions close to the soma (Fig. 5).
To quantify the increase of short dendritic processes around the somata of BDNF-transfected DGCs for both the apical and basal dendritic fields combined, we determined the number of dendritic terminations at given distances from the soma. By definition, short dendritic processes originating from the soma or proximal dendrites will terminate close to the soma, and long dendrites that extend substantial distances (as is typical of control DGCs) will terminate far from the soma. This measure, therefore, provides a means to quantify the observed differences in the dendritic fields among groups. Indeed, BDNF-transfected neurons possessed large numbers of dendritic processes that ended within 50 μm of the soma (Fig. 4, bottom). In contrast, dendrites from GFP- and NGF-transfected DGCs tended to extend ∼175 μm from the soma before ending (Fig. 4, bottom). A statistical analysis comparing the number of dendritic endings within 50 μm of the cell body revealed a significant increase in ending number for BDNF-transfected DGCs relative to GFP- and NGF-transfected cells (Table 2, a priori ANOVA on ranks; p< 0.001). No change was found between 50 and 100 μm. The increase within 50 μm represents an ∼6000% increase over GFP-transfected and a 700% increase over NGF-transfected neurons. Approximately 60% of this effect was the result of changes in the apical dendritic field, with the remainder resulting from changes in the basal dendritic field (Table 3).
In contrast to these effects on short dendritic processes, BDNF did not significantly modify soma area, apical dendrite number, total number of branches off apical dendrites (despite the increased branch number within 50 μm of the soma, as in Fig. 4, bottom), or total (the combined length of all apical dendrites and their branches) and mean (total apical dendrite length divided by the number of primary apical dendrites) apical dendritic lengths in comparison to NGF or GFP (Tables 1, 2). There were also no overt differences in dendritic spine number, although this parameter was not examined systematically. Finally, although the apical dendritic fields of BDNF-transfected cells often were disorganized in comparison to GFP- or NGF-transfected cells (Figs. 1, 3), there were no significant differences in the transverse spread of the apical dendrites nor the depth into the molecular layer reached by the longest dendrite.
Morphological effects of BDNF are cell type-specific
In contrast to its effects on DGCs, BDNF did not modify the number of apical or basal dendrites of CA3 or CA1 pyramidal cells in comparison to GFP or NGF (Table 4). The cell type specificity of BDNF is unlikely to be attributable to differences in BDNF protein levels, because considerable overlap in BDNF levels exists between DGCs and pyramidal cells as assessed by quantitative gray scale analysis of epitope tag immunohistochemistry (data not shown).
The effect of BDNF on granule cell dendritic morphology is receptor tyrosine kinase-dependent
To determine whether BDNF increased granule cell basal dendrite number by activating a tyrosine kinase, we examined the effects of the Trk receptor tyrosine kinase inhibitor K252a. BDNF produced a striking increase in the number of DGCs exhibiting basal dendrites in comparison to GFP alone (Fig. 6), thereby confirming the results of earlier experiments (Fig. 4). Inclusion of K252a (200 nm) in the BDNF-transfected cultures resulted in a significant reduction of the number of DGCs with basal dendrites (Fig.6). The median basal dendrite number of DGCs in the GFP (n = 19), GFP+K252a (n = 22), BDNF (n = 16), and BDNF+K252a (n = 15) groups were 0, 0.42, 2.5, and 0, respectively (ANOVA on ranks;p < 0.001). Similarly, BDNF-transfected DGCs (median, 3.0) had significantly more axonal branches within 50 μm of the soma than GFP-transfected control granule cells (median, 0.0), whereas BDNF+K252a-treated granule cells (median, 1.0) were not different from these controls.
DGCs with the most robust morphological changes are closest to the hilus
Despite similar levels of expression as assessed by HA immunoreactivity, heterogeneity was noted with respect to the morphological consequences of BDNF expression in DGCs. Some DGCs exhibited robust increases in axonal branches and basal dendrites, whereas others were indistinguishable from controls (Fig. 4, top panels). Further examination of the transfected DGCs revealed that cells close to the hilar/granule cell layer border tended to exhibit robust BDNF-induced changes, whereas the morphology of DGCs farther from this border (closer to the molecular layer) tended to appear normal. To quantify this effect, we correlated the distance of the DGCs from the hilar/granule cell layer border with the number of dendritic endings within 50 μm of the soma, a robust indicator of BDNF response. A Spearman Rank Order Correlation revealed a significant negative interaction between distance from the hilus and ending number (Fig. 7) (r = −0.528;p < 0.01). That is, neurons closest to the hilus exhibited the greatest number of endings within 50 μm of the cell body and therefore looked the most abnormal. Interestingly, a few of the DGCs in the BDNF group actually were located within the hilus, a finding reminiscent of the hilar ectopic DGCs described in several recent reports of epileptic animals (Parent et al., 1997; Scharfman et al., 2000; Dashtipour et al., 2001) and humans (Houser, 1990). Like thein vivo findings, hilar DGCs in the present study had an axon in stratum lucidum [a feature thought to be exclusive to DGCs (Ramon y Cajal, 1893; Lorente de No, 1934)], had small cell bodies (also characteristic of DGCs), and exhibited numerous basal dendrites. By contrast, no DGCs were found within the hilus of control animals. There was also no correlation between dendritic endings and distance from the hilus for GFP-transfected (Fig. 7) (r = 0.493;p > 0.05) and NGF-transfected (Fig. 7) (r = 0.487; p > 0.05) DGCs. A similar location analysis found no correlation between ending number and the distance a BDNF-transfected DGC was from the tip of the superior blade of the granule cell layer (medial-to-lateral location,r = 0.260; p > 0.05; data not shown).
A correlation analysis of axonal branch points within 50 μm of the soma revealed a similar effect. Within the BDNF-treated group the DGCs closest to the hilus had the greatest number of axonal branch points (Spearman Rank Order Correlation, r = −0.516;p = 0.003) (Fig. 7). In contrast, no significant correlations were found between location and axonal branch number for either GFP-transfected (r = −0.15; p = 0.4) or NGF-transfected (r = 0.04; p = 0.9) granule cells.
Differences in DGC location and survival cannot account for the morphological differences
Quantitative analysis of DGC location and cell number demonstrates that the differences among the experimental groups are unlikely to be explained by location-dependent differences in morphology or selective survival. For each DGC the distance of the soma from the tip of the superior blade of the dentate (medial-to-lateral position) and from the hilar/granule cell layer border was determined. There were no systematic differences in DGC location that could account for the differences in morphologic patterns among the three groups (data not shown). Furthermore, an analysis examining the number of transfected DGCs per explant found no differences among treatment groups (medians for GFP, NGF, and BDNF all = 0; range = 0–4, 0–2, and 0–4, respectively), arguing that differences in survival cannot account for the differences in morphologic patterns among the three groups.
DISCUSSION
The principal findings are fivefold. First, transfection with BDNF, but not NGF, increased axonal branching and formation of basal dendrites of DGCs. Second, the effects of BDNF were specific to granule cells in that similar alterations were not detected in CA3 or CA1 pyramidal cells. Third, the effects of BDNF on DGC morphology were most robust close to the soma, the region most immunoreactive for the epitope-tagged BDNF. Fourth, the effects of BDNF were eliminated by the tyrosine kinase inhibitor K252a. Finally, a significant correlation was found in that the effects of BDNF were marked most on DGCs located close to the border of the hilus with the granule cell layer. Together, these findings demonstrate that increased expression of BDNF in DGCs, an occurrence common to human limbic epilepsy as well as its animal models, is sufficient to induce two distinctive morphological features of these neurons identified in an epileptic brain, namely the formation of basal dendrites and axonal sprouting.
Previous work from our laboratory and others suggested that BDNF may have morphoregulatory effects on DGCs. For example, the bath application of BDNF to dentate gyrus neurons in primary culture or coculture with CA3 minislices increased axonal length, number, and branching (Patel and McNamara, 1995; Lowenstein and Arsenault, 1996a,b); whether the neurons that were identified were in fact DGCs and whether the effects of BDNF were direct or indirect were not clear from these studies. The experimental approach that was used here permitted unambiguous identification of DGCs. Second, in contrast to cultures on coated plates or in a collagen matrix (Patel and McNamara, 1995; Lowenstein and Arsenault, 1996a,b), the explant method that was used here more nearly approximates the in vivo condition by retaining some of the afferent and efferent connections as well as some of the molecular cues of the extracellular milieu such as cell adhesion molecules and extracellular matrix proteins. Finally, instead of bath application, the present approach more nearly approximated the in vivo condition during epileptogenesis by increasing the expression of BDNF within individual DGCs via transfection. The CMV promoter used to drive BDNF expression in the present study markedly increases BDNF levels, but whether these increases match those evident in vivo during epileptogenesis is uncertain. That is, quantitation of BDNF content in homogenates of hippocampus during epileptogenesis discloses increases as high as 400% of control (Nawa et al., 1995) (see also Elmer et al., 1998; Rudge et al., 1998); because immunohistochemical analyses reveal that the greatest increases are within the granule cells (Wetmore et al., 1994; Yan et al., 1997;Vezzani et al., 1999), which account for <20% of hippocampal protein (Byrne et al., 1980), the 400% increase is almost certainly an underestimate of the increase of BDNF within granule cells. The ability to drive marked increases of BDNF appears to be critical, because only marginal increases (32%) recently described in transgenic mice (Croll et al., 1999) were not associated with robust effects on indirect histochemical measures of axonal sprouting (Qiao et al., 2001).
The advantages inherent in the experimental approach used here permitted demonstration that increased expression of BDNF within a DGC was sufficient to recapitulate some of the morphological plasticities of the DGCs in the epileptic brain. For example, the increased expression of BDNF described here triggered increased branching of mossy fiber axons within 50 μm of the cell soma, a finding similar to earlier descriptions of increased branching of biocytin-labeled DGC axons in the dentate hilus in vivo in the kainic acid model of epilepsy (Buckmaster and Dudek, 1999). Likewise, the increased expression of BDNF triggered the formation of basal dendrites, a plasticity similar to that described in vivo in the kindling, kainic acid, and pilocarpine models of epilepsy (Spigelman et al., 1998; Buckmaster and Dudek, 1999; Ribak et al., 2000). Basal dendrites are of particular interest because their close intermingling with a rich network of mossy fiber axons of granule cells in the dentate hilus facilitates the formation of excitatory synapses between or even within the same DGC, as demonstrated by electron microscopy (Ribak et al., 2000; Dashtipour et al., 2002).
Whereas the BDNF-induced formation of basal dendrites and sprouting of the proximal axon of DGCs are concordant with findings in granule cells in animal models of epilepsy (Spigelman et al., 1998; Buckmaster and Dudek, 1999; Ribak et al., 2000), the invasion of sprouted axons into the inner molecular layer of the dentate gyrus or into stratum oriens of CA3 as described in the epileptic brain (Sutula et al., 1988; Represa and Ben-Ari, 1992) was not detected in the present study. This discrepancy simply may reflect the short time period that was examined in the present study. Mossy fiber sprouting develops over weeks in vivo; thus it seems unlikely that such sprouting would develop in our preparation in the 24 hr time period examined, especially given that high BDNF levels are present only for the latter portion of that period. Importantly, however, Wenzel et al. (2000)noted that in epileptic animals mossy fibers tended to sprout from the main axon within a short distance from the soma. The increased axonal branching observed in the present study, therefore, is consistent with what one would expect to observe in the early stages of mossy fiber sprouting.
A notable feature of the present study was the striking cellular specificity of the morphological effects of BDNF among neurons within the hippocampus. Transfection with BDNF produced robust morphological changes of DGCs, but not of CA1 or CA3 pyramidal cells. Indeed, even among DGCs, transfection with BDNF produced striking effects in the subset of neurons near the margin of the hilus and the granule cell layer; more subtle or no detectable effects were found on granule cells located closer to the molecular layer. Interestingly, this finding parallels in vivo findings that used the pilocarpine model of epilepsy in which basal dendrites were most numerous on DGCs located at the hilar/granule cell layer border (Ribak et al., 2000; Dashtipour et al., 2002). It seems plausible that differences in neuronal age might account for this pattern of responding and nonresponding neurons. CA1 and CA3 pyramidal cells are born earlier than DGCs (Altman and Bayer, 1990a), and newborn and young granule cells reside closer to the margin of the hilus and granule cell layer (Altman and Das, 1965;Altman and Bayer, 1990b). A correlation exists, therefore, suggesting that young DGCs may be more responsive to BDNF than older granule cells. Although the mechanistic basis of any developmental changes in BDNF sensitivity is not obvious, the TrkB receptor may play a role. The effects of transfected BDNF likely were mediated by the activation of TrkB, because the tyrosine kinase inhibitor K252a eliminated the morphological changes. An alternative explanation, activation of the p75 receptor, is unlikely both because of the lack of effect of transfected NGF and the elimination of BDNF effects by K252a. Developmental differences in the levels of expression of the TrkB receptor, and in particular its noncatalytic, truncated isoform, therefore may play a role in the cellular specificity of BDNF (Dugich-Djordjevic et al., 1993; Escandon et al., 1994; Knusel et al., 1994; Fryer et al., 1996). Interestingly, increased immunoreactivity for the polysialylated form of neural cell adhesion molecule (NCAM) is evident in developing DGCs (Seki and Arai, 1991; Parent et al., 1999;Seki and Arai, 1999), which might contribute to an increased responsiveness to BDNF, because PSA-NCAM increases the potency of BDNF in activating TrkB (Muller et al., 2000; Vutskits et al., 2001).
In summary, repeated and/or prolonged focal hippocampal seizures promote limbic epileptogenesis, the process by which a normal brain becomes epileptic (Goddard et al., 1969). The cascade of gene expression activated by focal hippocampal seizures includes marked increases of BDNF content in multiple neuronal populations including the DGCs (Wetmore et al., 1994; Smith et al., 1997; Yan et al., 1997;Vezzani et al., 1999). Pharmacological and genetic interventions implicate a causal role for BDNF in epileptogenesis (Kokaia et al., 1995; Binder et al., 1999a; Lahteinen et al., 2002; Scharfman et al., 2002). Here we show that increasing the expression of BDNF in DGCs is sufficient to induce the formation of basal dendrites and axonal sprouting. The morphological consequences of increased BDNF expression may underlie the recurrent excitatory synapses demonstrated among DGCs in epileptic animals (Molnar and Nadler, 1999; Wuarin and Dudek, 2001) and thus may constitute one mechanism by which seizure-induced BDNF expression promotes limbic epileptogenesis. Our findings provide the rationale for determining whether increased BDNF expression is sufficient and/or necessary for the morphological and physiological plasticities of the granule cells during epileptogenesis in vivo and, if so, for elucidating the role of such plasticities in epileptogenesis. Analyses of the morphological plasticities of the granule cells in mice carrying mutations of BDNF and TrkB genes will provide an initial approach to addressing these questions.
Footnotes
This work was supported by National Institutes of Health (NIH) Grants NS07370 and NS32334 and National Institute of Neurological Disorders and Stroke Grant NS17771. S.C.D. was supported by an NIH National Research Service Award grant and the Pharmaceutical Research and Manufacturers of America Foundation. We also thank Dr. David Fitzpatrick for the use of his Neurolucida system and Dr. Ram Puranam, Dr. Victor Nadler, and Keri Kaeding for useful comments on previous versions of this manuscript. We offer special thanks to Charles Hemphill of Leica Microsystems for assistance in collecting confocal images.
Correspondence should be addressed to Dr. James O. McNamara, Duke University Medical Center, 401 Bryan Research Building, Durham, NC 27705. E-mail: jmc{at}neuro.duke.edu.