Abstract
The generation of properly functioning circuits during brain development requires precise timing of cell migration and differentiation. Disruptions in the developmental plan may lead to neurological and psychiatric disorders. Neocortical circuits rely on inhibitory GABAergic interneurons, the majority of which migrate from subcortical sources. We have shown that the pleiotropic molecule hepatocyte growth factor/scatter factor (HGF/SF) mediates interneuron migration. Mice with a targeted mutation of the gene encoding urokinase plasminogen activator receptor (uPAR), a key component in HGF/SF activation and function, have decreased levels of HGF/SF and a 50% reduction in neocortical GABAergic interneurons at embryonic and perinatal ages. Disruption of interneuron development leads to early lethality in most models. Thus, the long-term consequences of such perturbations are unknown. Mice of theuPAR−/− strain survive until adulthood, and behavior testing demonstrates that they have an increased anxiety state. TheuPAR−/− strain also exhibits spontaneous seizure activity and higher susceptibility to pharmacologically induced convulsions. The neocortex of the adultuPAR−/− mouse exhibits a dramatic region- and subtype-specific decrease in GABA-immunoreactive interneurons. Anterior cingulate and parietal cortical areas contain 50% fewer GABAergic interneurons compared with wild-type littermates. However, interneuron numbers in piriform and visual cortical areas do not differ from those of normal mice. Characterization of interneuron subpopulations reveals a near complete loss of the parvalbumin subtype, with other subclasses remaining intact. These data demonstrate that a single gene mutation can selectively alter the development of cortical interneurons in a region- and cell subtype-specific manner, with deficits leading to long-lasting changes in circuit organization and behavior.
- GABA
- interneuron
- epilepsy
- anxiety
- urokinase
- plasminogen
- calbindin
- calretinin
- somatostatin
- parvalbumin
- knock-out mouse
- neocortex
- uPAR
Introduction
Functional circuits in the CNS depend on a delicate balance of synaptic excitation and inhibition. Inherited disruption of these interactions in the cerebral cortex commonly leads to human neurological and psychiatric disorders such as epilepsy, anxiety, and depression (Sanacora et al., 2000;Sandford et al., 2000; Ballenger, 2001; Holmes and Ben-Ari, 2001), with a developmental onset during childhood or adolescence (Hauser, 1995;Heim and Nemeroff, 2001). Animal models of human disorders have been used to perturb circuit function by the mutation of genes encoding ion channels, neurotransmitter receptors, and developmentally essential molecules, or by environmental manipulations (Mehta and Ticku, 1999;Liu et al., 2000; Steinlein and Noebels, 2000; Anagnostopoulos et al., 2001). Several experimental approaches, including focal cortical freezing (Prince and Jacobs, 1998; Jacobs et al., 1999), methylazoxymethanol treatment (Chevassus-au-Louis et al., 1999; Baraban et al., 2000), and genetic disruption of critical developmental molecules such the transcription factor BETA2/NeuroD (Liu et al., 2000), lead to forebrain malformations and epileptic phenotypes. These studies also provide paradigms for studying adaptive changes that result from the developmental perturbations.
In the cerebral cortex, excitatory glutamatergic neurons arise from the proliferative zone of the neuroepithelium and migrate radially to form the cortical plate (Sidman and Rakic, 1973; Rakic, 1990; Tan et al., 1998). Simultaneously, the inhibitory GABAergic neurons relocate from their origin in the ganglionic eminence of the ventral telencephalon into the developing cortex by migrating tangentially before infiltrating the newly formed individual laminas of the cortex (Anderson et al., 1997; Tamamaki et al., 1997; Lavdas et al., 1999). Several molecules have been implicated in controlling interneuron migration, including the transcription factors DLX1 and DLX2 (Anderson et al., 1997; Sussel et al., 1999), the extracellular matrix molecule slit1 (Zhu et al., 1999), growth factors neurotrophin-4 (NT-4) (Brunstrom et al., 1997; Polleux et al., 2002) and hepatocyte growth factor/scatter factor (HGF/SF) (Powell et al., 2001), guidance molecules semaphorin 3A and semaphorin 3F, and the neuropilins (Marin et al., 2001). Disruption of GABAergic interneuron migration and differentiation could alter the balance of excitatory to inhibitory neurotransmission, leading to behavioral deficits. However, this hypothesis has not been directly tested, primarily because of the embryonic or perinatal lethality of many gene mutations that disrupt neural development more broadly than do GABAergic interneurons.
We have shown previously that HGF/SF mediates interneuron migration (Powell et al., 2001). Genetic deletion of HGF/SF results in midgestation lethality before the onset of interneuron migration. However, inactivation of the urokinase plasminogen activator receptor (uPAR) gene, which regulates HGF/SF activation (Blasi, 1993), leads to diminished levels of HGF/SF and a 50–65% reduction in cortical GABAergic interneurons beginning at embryonic day 16.5 (E16.5) (Powell et al., 2001). Because theuPAR−/− mouse survives to adulthood, it provides a unique opportunity for studying developmental perturbations of the cortical GABAergic interneurons in the mature brain. Here we demonstrate that theuPAR−/− mouse lacks specific subpopulations of cortical interneurons, displays increased anxiety, and exhibits a novel pattern of spontaneous myoclonic seizures. These deficits demonstrate the importance of the normal assembly of cortical interneurons in the establishment of functional circuits and the inability of the developing organism to induce adaptive responses that completely correct the defects.
Materials and Methods
Unless otherwise noted, all chemicals and reagents were purchased from Sigma (St. Louis MO).
Animals. C57BL/6J mice were purchased from The Jackson Laboratory (Bar Harbor, ME).uPAR−/− mice were a generous gift from P. Carmeliet (Center for Transgene Technology and Gene Therapy, Flanders Interuniversity Institute for Biotechnology, KU Leuven, Belgium). The mice were genotyped via PCR as described previously (Suh et al., 1994; Dewerchin et al., 1996) using the primer set 5′- GATGATAGAGAGCTGGAGGTGGTGAC-3′ (nucleotides 5054–5079) and 5′-CACCGGGTCTGGGCCTGTTGCAGAGGT-3′ (nucleotides 5201–5175). All mice used in the experiments were littermates that had been obtained from heterozygous matings. TheuPAR+/− mice were backcrossed onto the C57BL/6J background strain for >15 generations.
Behavior experiments. Mice were housed in a central animal facility with a 12 hr light cycle (from 7:00 A.M. to 7:00 P.M.) withad libitum access to food and water. Before all behavioral testing, mice were acclimated to the behavior facility for at least 1 hr. At least six male mice of each genotype were tested between the ages of postnatal day 90 (P90) and P120. Each animal was evaluated once for each test, beginning with open field, then light–dark anxiety assessment, and finally elevated plus maze. In all tests, the observer was blinded to the genotypes of the mice. Sample sizes are noted in figure legends.
Open-field exploration test. Mice were placed in the center of a 25 × 25 cm activity arena (TruScan; Colbourn Instruments, Allentown, PA) equipped with a computerized laser photobeam tracking system. Horizontal and vertical movements of the subject were automatically recorded. Activity of each mouse was assessed for 10 min in a brightly lit room between 9:00 A.M. to 12:00 P.M. Measurements of total distance traveled and time spent moving were calculated and analyzed with a Student's t test. Ethological parameters such as amount of defecation and time spent grooming were recorded manually.
Light–dark exploration test. The activity arena was partitioned into a darkened area with a black Plexiglas insert (Colbourn Instruments). The mouse was placed in the brightly lit area of the box at the start of the test and was allowed to explore both the light and dark sides for 10 min. The position of the subject was automatically recorded with the computerized laser photobeam tracking system. The time spent on each side was calculated and analyzed with a Student's t test.
Elevated plus maze exploration test. A standard elevated maze (San Diego Instruments, San Diego, CA) designed for mice was used. All arms were 50 cm long and 10 cm wide, with two arms enclosed by 40-cm-high opaque walls. The maze was raised 50 cm from the floor. The mouse was placed in the center of the maze and allowed to explore for 5 min. Each session was recorded on videotape and scored by at least two observers who were blinded to the genotype of the animals. Each mouse was allowed to explore the maze once; if the mouse fell off the maze, it was disqualified from the study. The position of the mouse in the maze was noted every 5 sec to calculate the percentage of time the mouse was located in the open arms, closed arms, or center of the maze. Statistical differences were evaluated with a two-way ANOVA followed by Student–Newman–Keuls post hoc analysis. Ethological parameters such as rearing and grooming also were recorded.
Electrocorticographic recordings. Adult mice were anesthetized with Avertin (0.02 ml/gm, i.p.) and Teflon-coated silver wire electrodes soldered to a microminiature connector positioned on the skull were implanted bilaterally into the subdural space. After several days of recovery, simultaneous digital EEG and video recordings of awake, freely moving mice were obtained during multiple 2–4 hr sessions taken over a 2 week period.
Pentylenetetrazol susceptibility. Pentylenetretrazol (PTZ) dissolved in buffered saline was administered subcutaneously at a dose of 50 mg/kg. Animals were monitored for up to 30 min after injection. Behavioral responses were scored using the following scale: 0, no signs of motor seizure; 1, isolated twitches; 2, tonic–clonic convulsions; 3, tonic extension or death (Erickson et al., 1996). The latency to the onset of the first seizure was recorded. Mice that did not develop seizures during the observation period were excluded from the latency analysis. The seizure severity data were analyzed for significance with an ANOVA test, whereas the seizure latency data were evaluated with a Student's t test.
Immunocytochemistry. Adult mice (>P90) were transcardially perfused using a fixative of 2% paraformaldehyde, 2% glutaraldehyde, and 0.2% picric acid in 0.1 m sodium phosphate, pH 7.2, and the brains were postfixed overnight at 4°C. Coronal sections were cut on a vibratome at 50 μm and stained using previously published protocols (Stanwood et al., 2001). Primary antibodies were used at the following dilutions: rat anti-GABA (1:1500; Protos Biotech, New York, NY), mouse anti-parvalbumin (PV) (1:1500; Sigma), rabbit anticalretinin (anti-CR) (1:2000; Sigma), and rabbit antisomatostatin (anti-SST) (1:5000; Bachem, Torrance, CA). Appropriate Cy3- or Cy2-conjugated secondary antibodies (Jackson ImmunoResearch, West Grove, PA) were used at a 1:3000 dilution. Sections were counterstained with 4′,6′-diamidino-2-phenylindole (DAPI) to visualize cell nuclei and cytoarchitecture. Images were obtained with an Olympus Optical (Melville, NY) Provis confocal microscope (with Fluoview version 3.0 software; Olympus Optical) and extended views through 25 μm depth-of-section were shown.
Cell counting. Profiles of immunoreactive cells were counted in four areas of cortex: anterior cingulate, parietal (motor and somatosensory), piriform (at bregma levels +1.50, +0.50, −0.50, and −1.50 mm), and visual (at bregma levels −3.00, −3.50, −4.00, and −4.50 mm) using stereotaxic coordinates (Paxinos and Franklin, 2001). For each area, a 200 μm strip of cortex from the white–gray matter interface to the pial surface was counted on a Nikon (Tokyo, Japan) E800 microscope equipped with epifluorescent illumination. Brains from at least five different mice were counted for each genotype. All sections were coded such that the observer was blinded to the genotype. Statistical analysis was performed using a two-way ANOVA followed by a Student–Newman–Keuls post hocanalysis. Sample sizes are noted in the figure legends.
Results
uPAR−/− mice show increased anxiety
The uPAR−/− mouse has been reported to be grossly normal, without an obvious phenotype, thus enabling behavioral testing (Dewerchin et al., 1996; Crawley, 2000). Behavior of uPAR−/− mice and their wild-type (WT) littermates was assessed in a standard open-field paradigm. Both WT anduPAR−/− mice moved similar distances, 2004 ± 102 cm and 1950 ± 109 cm, respectively (Fig. 1A). The time spent moving was also equivalent: 410 ± 7 sec for WT mice compared with 417 ± 10 sec foruPAR−/− mice. Thus, theuPAR−/− mutation did not affect generalized motor activity. In addition, the percentage of time that mice spent at the margin of the arena (within 6 cm of the wall) compared with the center of the arena was calculated. WT mice occupied the margin for 66% of the time and the center for 34%, whereasuPAR−/− mice were found in the margin area for 76% of the time and the center 24% of the experiment time, which is significantly different from that of WT mice (p < 0.01). The decrease in time thatuPAR−/− mice spent in the center of the arena indicates decreased exploratory behavior and can be interpreted as an increase in anxiety (Crawley and Davis, 1982;Crawley, 1985; Crawley and Paylor, 1997).
Anxiety was also assessed with the classic light–dark avoidance test and the elevated plus maze paradigms. In both assays, the test provides a conflict between the desire to explore an unknown area and the aversion of a brightly lit open space (Crawley and Davis, 1982; Zhuang et al., 1999; Crawley, 2000; Sibille and Hen, 2001). In the light–dark avoidance test, WT mice spent equivalent time (50%) between the light and dark sides of the open field. In contrast,uPAR−/− mice explored only the light part of the open field for 25% of the time, preferring the less aversive, darkened area (Fig. 1B), suggesting that uPAR−/− mice displayed a more anxious phenotype (Crawley and Davis, 1982).
The elevated plus maze serves as another measure of anxiety based on the same naturalistic conflict of exploring a novel, brightly lit, elevated region (open arms) versus the defined space of the closed arms (Pellow et al., 1985; Lister, 1987). Both WT anduPAR−/− mice actively traveled in the maze for the majority of the test period. Although WT mice explored the open arms for ∼25–30% of the test period, theuPAR−/− mice ventured into the open space <5% of the time (Fig. 1C), and none of theuPAR−/− mice explored the most distal end of the open arms. By all measures,uPAR−/− mice display behaviors consistent with increased anxiety compared with their WT littermates.
uPAR−/− mice display spontaneous seizures
Of >200 uPAR−/− mice observed, 5.9% were noted to exhibit overt convulsive activity, compared with none of their WT littermates. In a few instances the seizures were lethal. These observations were made during short (1–2 min), routine handling procedures. Although 24 hr surveillance of mice was not performed, the electroclinical correlation of these episodes was also explored with chronic video/electrographic recordings of freely moving uPAR−/− mice that had previously demonstrated convulsive activity. The baseline cortical activity of the mice showed periods of normal, low-amplitude desynchronized EEG with the frequent appearance of abnormal slow waves and interictal discharges (Fig.2A). A spontaneous bilateral tonic clonic seizure lasting ∼75 sec was captured, revealing an orderly buildup of periodic interictal discharges and the abrupt initiation of high-voltage rhythmic spike and spike-wave seizure discharges, terminating abruptly with no postictal depression (Fig.2B). During the electrographic seizure, mice maintained a tonic posture of flexion with an arched back and intermittent truncal myoclonus, some bilateral clonic forelimb movements accompanied by a Straub tail, followed by behavioral arrest until the seizure terminated.
uPAR−/− mice have an increased susceptibility for PTZ-induced seizures
uPAR−/− mice were challenged with the convulsant PTZ, a GABA antagonist. After a single threshold dose (50 mg/kg, s.c.), all (n = 10) of theuPAR−/− mice displayed motor convulsions, compared with only 50% of their WT littermates (Fig.3A). The severity of the seizure activity was also characterized using a 0–3 rating system with 0 defined as no signs of motor seizure, 1 as isolated limb twitches, 2 as tonic–clonic convulsions, and 3 as tonic extension or death (Erickson et al., 1996). WT animals received scores of either 1 (50%) or 2 (50%), with no animals exhibiting tonic extension, whereas 90% of the uPAR−/− mice had seizures scored as tonic extension. The time to the first forelimb clonus was also recorded, with theuPAR−/− mice exhibiting a significantly decreased latency of 67% (456 ± 60 sec) compared with that of WT mice (681 ± 19 sec) (Fig. 3B).
Neocortical GABAergic interneurons are decreased inuPAR−/− mice
Increased anxiety behavior and susceptibility to spontaneous and induced seizures suggested a defect in the balance between excitatory and inhibitory neurotransmission in the forebrain. Several transgenic mouse lines in which GABA modulation is altered, such as theGAD65 and NPY null mutants (Asada et al., 1996;Erickson et al., 1996; Kash et al., 1997), exhibit behavioral phenotypes similar to our observations of theuPAR−/− mouse. In addition, the uPAR−/− brain has a decrease in the number of neocortical GABAergic interneurons at birth (Powell et al., 2001). Gross anatomical observation of coronal brain sections with Nissl staining did not reveal any obvious morphological defects (Dewerchin et al., 1996) (Fig.4A,B). Nevertheless, immunocytochemical analysis of the cerebral cortex with anti-GABA antibodies demonstrated a substantial decrease in GABA-immunopositive cells in the adult uPAR−/− parietal cortex (Fig. 4D) compared with WT littermates (Fig. 4C). Although the decrease in GABA+ cells appeared uniform across all cortical laminas within the frontal cortex, regional variation in the reduction of GABA+ cells between frontal and visual cortices was evident.
The extent of GABA+ cell loss was quantified by counting 200 μm strips from the pial surface to the white–gray matter interface in several distinct cortical subregions. In the anterior cingulate and parietal regions, there was a reduction of ∼50% in GABA+ cells in theuPAR−/− mice compared with their WT littermates (Fig.5A). However, there were no significant differences in numbers of GABA+ cells in WT anduPAR−/− mice in either piriform or visual cortex (Fig. 5C,D). Thus, theuPAR mutation resulted in a selective deficit of GABA+ cells in distinct cortical areas, suggesting the possibility that specific interneuronal subtypes may be differentially impaired.
Cortical GABAergic interneurons can be identified using the molecular markers PV, CR, or SST (Kubota et al., 1994; Kawaguchi and Kubota, 1997). These subpopulations of interneurons possess distinct electrophysiological and neuroanatomical properties (Kawaguchi, 2001;Amitai et al., 2002; Pawelzik et al., 2002). Calbindin (CB) can be used as a marker for embryonic interneurons, but in adults, CB is expressed by both GABAergic and glutamatergic neurons, thus making it a poor marker for mature interneurons. The CB+interneuron subpopulation also overlaps with expression of PV and SST (Kubota et al., 1994). Immunocytochemical localization of either CR or SST showed no obvious difference in labeling between WT anduPAR−/− mice in any of the cortical areas examined (Fig. 4G,H and data not shown). However, the PV+ population was greatly diminished in the uPAR−/− parietal (Fig. 4E,F) and anterior cingulate cortex. Quantitative analysis demonstrated that the cingulate and parietal regions had a >90% decrease in the number of PV+ cells (Fig.6A,B). The PV+ subpopulation accounts for 45–50% of the GABAergic interneurons in the WT rodent cortex (Kawaguchi and Kubota, 1993; Kubota et al., 1994) (Table1). Thus, the near complete loss of the PV+ population may account for the missing 50% of the GABA+ cells in theuPAR−/− cingulate and parietal cortical regions.
To test the hypothesis that the absent GABA+ cells in theuPAR−/− cortex were comprised specifically of the PV+ subtype, we performed double-label immunohistochemistry and counted the number of cells that expressed combinations of GABA and PV, GABA and CR, and GABA and SST (Fig. 7 and Table 1). In WT mice, ∼46% of the GABA+ cells were also PV+, 12% were CR+, and 11% were SST+. InuPAR−/− mice, the PV+ subtype comprised only 2% of the GABA+ cells (Table 1). Because theuPAR−/− parietal cortex exhibited a 50% reduction in the total number of GABA+ cells but the same absolute number of CR+ and SST+ cells as that in WT mice, the percentage of GABA+ cells that also double-labeled with either CR or SST would be expected to double compared with that of WT mice. However, the percentage of GABA+/CR+cells decreased significantly from 12 to 7%. The GABA+/SST+fraction was not affected. Thus, it appears that some neurons that express calcium-binding protein markers do not produce detectable quantities of GABA in theuPAR−/− mouse.
The double-labeled sections were counted to determine the number of cells that coexpressed PV, CR, or SST and GABA. In the WT parietal cortex, 83% of the PV+ cells and 88% of the SST+ cells were also GABA+, whereas only 51% of CR+ cells demonstrated GABA immunoreactivity. These values are in close agreement with previous studies in prefrontal areas of the rat (Kawaguchi and Kubota, 1993;Kubota et al., 1994). InuPAR−/− mice, the degree of colocalization of the calcium-binding marker proteins with GABA was decreased for all subtypes. Only 11% of the remaining PV+ cells expressed GABA, whereas 18% of CR+ and 45% of SST+ cells were GABA+ (Table 1). The shift in subtypes from GABA-expressing to GABA-nonexpressing is shown visually in Figure7. The data suggest that theuPAR−/− mouse parietal cortex has an overall decrease in GABA+interneurons, which is attributable both to a drastic reduction in the number of PV+ cells and to a decrease in detectable GABA immunoreactivity in the PV+, CR+, and SST+ subtypes.
Discussion
The present study provides behavioral and neuroanatomical evidence that deletion of the gene encoding uPAR causes developmental defects in interneuron maturation and long-term disruption of cortical circuit function. Initial characterization studies reported no obvious phenotype inuPAR−/− mice; however, slight deficits in immune responses were observed during challenges with infectious agents (Gyetko et al., 2000, 2001). Our analysis ofuPAR−/− mice demonstrated no gross anatomical abnormalities (Powell et al., 2001). Behavioral testing showed overall normal levels of motor activity, but increased anxiety in three paradigms: the open field, light–dark exploration, and the elevated plus maze.uPAR−/− mice also exhibited spontaneous myoclonic seizures and a greater susceptibility to pharmacologically induced convulsions. Morphological analyses uncovered a 50% deficit in GABA+ cells in both anterior cingulate and parietal cortical regions, with a highly preferential effect on the PV subtype, and a sparing of changes in visual and piriform areas. These data indicate that uPAR, in addition to being an active participant in the biochemical pathways mediating thrombolysis, angiogenesis, and metastasis, also plays a critical role during cortical development. The cortical interneuron deficit that we described previously inuPAR−/− mice at prenatal and perinatal periods (Powell et al., 2001) does not reflect merely a developmental delay, but rather a permanent absence of a specific interneuron population that is maintained in the adult and produces significant functional consequences.
Several studies report a critical role for the plasminogen system in brain development and function, including HGF/SF (also known as plasminogen-related growth factor 1) (Achim et al., 1997; Thewke and Seeds, 1999; Powell et al., 2001) and tissue-type plasminogen activator (tPA) (Baranes et al., 1998; Thewke and Seeds, 1999). The present study provides an additional role for the plasminogen system. Although uPA and tPA are both expressed in the developing forebrain (Seeds et al., 1992) and both can activate plasminogen and HGF/SF (Pepper et al., 1992), each system appears to have distinct roles. tPA has been shown to be important in the establishment of long-term potentiation in the hippocampus, whereas no role was found for uPA (Qian et al., 1993). The tPA null mouse is distinct in a number of ways from theuPAR−/− mouse. For example, the tPA mutant does not exhibit an anxious, seizure-prone behavioral phenotype, and it is less sensitive to pharmacologically induced hippocampal seizures, with reduced excitotoxic cell death and mossy fiber sprouting (Tsirka et al., 1995). In addition, thetPA null mouse does not appear to have a deficit in cortical GABAergic interneurons (Tsirka et al., 1995; Baranes et al., 1998). In contrast, uPA is the main ligand for uPAR, and uPA mRNA was increased after kainate-induced seizures (Masos and Miskin, 1997). These data demonstrate critical yet distinct roles for the tPA and uPA/uPAR systems in cortical development and function.
Role of uPAR in cerebral cortical interneuron development
We previously reported a migration defect of the interneurons in the uPAR−/− forebrain at embryonic and early postnatal ages (Powell et al., 2001). The number of GABAergic interneurons, assessed by calbindin immunoreactivity, was diminished by >50% in frontal and parietal neocortices at E16.5 and P0, whereas the cells appeared to differentiate and remain in or near the ganglionic eminence. uPAR can mediate cell migration in non-neuronal cells through either proteolytic- or nonproteolytic-mediated mechanisms (Blasi, 1993; Waltz et al., 2000). uPAR, via interactions with several α- and β-integrin subunits, increases cell migration in vitro and possibly in vivo during metastasis (Chapman et al., 1999). Lack of uPAR reduces neutrophil migration, a process normally mediated through uPAR–integrin interactions (Gyetko et al., 2000). uPAR, as the receptor for uPA, mediates the proteolytic activity of uPA and tPA, thus increasing the activated concentrations of the zymogen plasmin and several matrix metalloproteases, which can then digest extracellular matrix molecules to clear a pathway for migrating cells. In addition, zymogens can activate latent growth factors such as HGF/SF into their active forms (Naldini et al., 1992; Mars et al., 1993), which then can function as a motogenic or differentiation factor. HGF/SF is expressed in a pattern that is consistent with a role in directing interneurons from their subpallial origins in the ganglionic eminence into the neocortex (Powell et al., 2001). HGF/SF activation, by either uPA or tPA (Seeds et al., 1992), is more efficient in the presence of uPAR (Blasi, 1993). Thus, in the absence of uPAR during forebrain development, the levels of active HGF/SF are dramatically decreased, which we have suggested is a mechanism that leads to defects in prenatal interneuron migration (Powell et al., 2001).
In addition to its role in mediating migration, HGF/SF may also participate in neuronal differentiation. Postnatally, GABAergic interneurons complete migration into the cortical plate and undergo differentiation and synapse formation. HGF/SF and its cognate receptor c-met are expressed in a caudal–rostral (high-low) gradient at early postnatal ages (Thewke and Seeds, 1999). Thus, areas of anterior cingulate and parietal cortices exhibit lower expression of HGF/SF than the visual cortex. Expression also is robust in the piriform cortex (Achim et al., 1997; Powell et al., 2001) (data not shown). We suggest that the reduced transcript and protein levels of HGF/SF that we measured in theuPAR−/− mouse (Powell et al., 2001) may have their greatest effects on interneuron differentiation or survival in the cingulate and parietal cortex, because HGF/SF levels in these regions may drop below threshold.
Several in vivo and in vitro studies have indicated that forebrain interneuron differentiation is mediated by a variety of growth factors, including basic FGF (FGF-2), BDNF, NT-3, and HGF/SF (Pappas and Parnavelas, 1998; Fiumelli et al., 2000;Korhonen et al., 2000). In fact, combinatorial effects of these factors on neuronal differentiation have been reported. For example, HGF/SF, when present with BDNF or NT-3, has a synergistic effect and increases the expression of calbindin or calretinin, respectively, compared with either growth factor alone (Fiumelli et al., 2000). Although its role in GABA expression has not been documented previously, it is possible that the decreased level of HGF/SF inuPAR−/− mice could disrupt the maturation of GABAergic interneurons. Thus, HGF/SF could play a pleiotropic role by regulating both migration and differentiation.
Pathophysiology resulting from developmental defects
Functional defects in GABAergic transmission are widely believed to cause epilepsy in humans. Migration defects, most obviously in the form of ectopias, are commonly observed in a subgroup of patients with epileptic seizures (Porter et al., 2002). It is often the case, however, that the cause of the seizures is not known and alterations in cortical lamination and cellularity are subtle.
Decreases in cells that are immunoreactive for the calcium-binding proteins PV, CB, CR, and SST have been reported in human epileptic tissue (temporal lobe) and in rodent models of epilepsy (Gruber et al., 1994; Spreafico et al., 2000; Andre et al., 2001;Sundstrom et al., 2001). However, defects in subcortical structures, including the amygdala and striatum, may also contribute to the behavioral phenotype ofuPAR−/− mice. Initial cursory examination of the striatum and amygdala does not display the same dramatic interneuron defect (data not shown).
Similar to the human epileptic phenotype,uPAR−/− mice show a major decrease in the expression of calcium-binding proteins in the cerebral cortex. However, mice null for PV, CB, CR, or the combination of PV/CB or PV/CR show grossly normal forebrain morphology and do not exhibit spontaneous seizures or increased vulnerability to kainic acid-induced seizures (Bouilleret et al., 2000). These data suggest that the most likely cause of the seizures observed inuPAR−/− mice is the lack of appropriate GABAergic inhibitory innervation, rather than changes in the expression of calcium-binding proteins. The spontaneous seizure activity in uPAR mutant mice, however, might contribute secondarily to an altered neuropeptide expression profile (Scotti et al., 1997; Vogt Weisenhorn et al., 1998; Porter et al., 1999). This is consistent with reports that expression of PV by interneurons is sensitive to abnormal levels of activity (Andre et al., 2001; Gorter et al., 2001). Thus, in uPAR−/− mice, the early disruption of the GABA phenotype in the developing cerebral cortex may combine with later onset seizure activity to produce the calcium-binding protein profile of interneurons in the adult.
A variety of genetic mutations affecting GABAergic synaptic transmission, including GAD65; GABAA receptor subunits α3, β3, and γ2; and neuropeptide Y, result in epilepsy and abnormal anxiety in humans and in experimental animal models (Homanics et al., 1997; Crestani et al., 1999; Kash et al., 1999;Baulac et al., 2001; Wallace et al., 2001). Although the increased anxiety and spontaneous seizures that we observed in theuPAR−/− mouse are similar to neurobehavioral deficits reported in other mutations of the GABAergic system, the uPAR−/− mutant phenotype is unique in its regional and interneuronal subtype specificity. Thus, as in human neurological and psychiatric diseases, there are likely to be numerous molecular pathways leading to pathophysiological states that share common features (Mirnics et al., 2000). Conditional deletions of the HGF/SF and plasminogen signaling systems, both temporally and spatially, will provide additional opportunities to dissect the molecular pathways responsible for interneuron migration, subsequent differentiation, and adaptive capacity of cortical circuits.
Footnotes
This work was supported by National Institute of Mental Health Grant MH65299 (P.L.), by National Institute of Neurological Disorders and Stroke Grants 29709 (J.L.N.) and HD 97-003 (J.L.N.), and by National Research Service Award Grant MH12651 (E.M.P.). We are grateful to Dr. Kathie Eagleson, Dr. Frank Middleton, Kyoko Koshibu, and Kristine Roy for their insightful discussions.
Correspondence should be addressed to Dr. Elizabeth M. Powell, 408 South Biomedical Science Tower, Department of Pathology, University of Pittsburgh, School of Medicine, 200 Lothrop Street, Pittsburgh, PA 15261. E-mail: epowell{at}pitt.edu.