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The Journal of Neuroscience, August 15, 1999, 19(16):6733-6739
Mapping Loci for Pentylenetetrazol-Induced Seizure Susceptibility
in Mice
Thomas N.
Ferraro1, 2,
Gregory T.
Golden1, 4,
George G.
Smith1, 4,
Pamela
St.
Jean5,
Nicholas J.
Schork5, 6, 7, 8,
Nicole
Mulholland1,
Christos
Ballas1,
Jörg
Schill1,
Russell J.
Buono1, and
Wade H.
Berrettini1, 3
Departments of 1 Psychiatry,
2 Pharmacology, and 3 Genetics, University of
Pennsylvania, Philadelphia, Pennsylvania 19104, 4 Research
Service, Department of Veterans Affairs Medical Center, Coatesville,
Pennsylvania 19320, Departments of 5 Biostatistics and
Genetics and 6 Epidemiology, Case Western Reserve
University, Cleveland, Ohio 44106, 7 Department of
Biostatistics, Harvard University, Boston, Massachusetts, and
8 The Jackson Laboratory, Bar Harbor, Maine 04609
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ABSTRACT |
DBA/2J (D2) and C57BL/6J (B6) mice exhibit differential sensitivity
to seizures induced by various chemical and physical methods, with D2
mice being relatively sensitive and B6 mice relatively resistant. We
conducted studies in mature D2, B6, F1, and F2 intercross mice to
investigate behavioral seizure responses to pentylenetetrazol (PTZ) and
to map the location of genes that influence this trait. Mice were
injected with PTZ and observed for 45 min. Seizure parameters included
latencies to focal clonus, generalized clonus, and maximal seizure.
Latencies were used to calculate a seizure score that was used for
quantitative mapping. F2 mice (n = 511) exhibited a
wide range of latencies with two-thirds of the group expressing maximal
seizure. Complementary statistical analyses identified loci on proximal
(near D1Mit11) and distal chromosome 1 (near D1Mit17) as having the
strongest and most significant effects in this model. Another locus of
significant effect was detected on chromosome 5 (near D5Mit398).
Suggestive evidence for additional PTZ seizure-related loci was
detected on chromosomes 3, 4, and 6. Of the seizure-related loci
identified in this study, those on chromosomes 1 (distal), 4, and 5 map
close to loci previously identified in a similar F2 population tested
with kainic acid. Results document that the complex genetic influences
controlling seizure response in B6 and D2 mice are partially
independent of the nature of the chemoconvulsant stimulus with a locus
on distal chromosome 1 being of fundamental importance.
Key words:
seizure; quantitative trait loci; epilepsy; mice; pentylenetetrazol; genetics
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INTRODUCTION |
Human epilepsies are complex
neurobehavioral disorders resulting from abnormal excitability of
neurons in various brain regions. The origin of abnormal excitability
in a specific subset of neurons, an epileptic "focus", and its
subsequent propagation to secondary brain regions determines a specific
clinical seizure phenotype. Although family (Beck-Mannagetta et
al., 1989 ; Ottman et al., 1989) and twin studies (Berkovic et
al., 1996) provide compelling evidence for genetic influences in
epilepsy, the clinical and genetic heterogeneity characteristic of the
epilepsies as a group have hindered the search for causative genes.
Nonetheless, a number of significant genetic linkages have been
reported (Leppert et al., 1989; Lehejoski et al., 1991; Lewis et al.,
1993; Liu et al., 1995; Phillips et al., 1995), and several of these
have led to the identification of mutated genes (Steinlein et al.,
1995; Pennacchio et al., 1996; Biervert et al., 1998; Charlier et al., 1998). However, whereas human epilepsy genes isolated to date are
involved in clinical syndromes inherited largely in Mendelian fashion,
the majority of seizure disorders in humans are genetically complex.
This provides a rationale for developing strategies to conduct a search
for seizure-related genes of partial effect.
Identification and characterization of strain differences in complex
phenotypic traits using experimental models provides a starting point
for dissecting genetic influences involved in complex traits in humans.
The well documented difference in seizure sensitivity between DBA and
C57 mice is largely independent of the mode of seizure induction (Hall,
1947; Schlesinger et al., 1968; Taylor, 1976; Marley et al., 1986;
Freund et al., 1987; Engstrom and Woodbury, 1988; Kosobud and Crabbe,
1990; Ferraro et al., 1995, 1997, 1998a) and offers a unique
opportunity to study how differences between common allelic variants
influence behavioral seizure responses. Use of seizure models involving administration of pentylenetetrazol (PTZ) are integral components in
the process used to identify clinically useful anticonvulsant drugs
(Porter et al., 1984) and, as such, the identification of murine genes
involved in determining sensitivity to PTZ may provide important
insight into the pathogenesis of certain forms of epilepsy in humans.
Moreover, if genetic loci that influence seizure response to PTZ
overlap loci that influence response to other convulsants, then it may
be possible to localize genes of fundamental importance in controlling
seizures in these strains of mice and, in doing so, provide candidate
genes for examination in human epilepsy.
We have undertaken a systematic evaluation of PTZ-induced seizure
responses in D2 and B6 mice and their F1 and F2 progeny. Previous work
in our laboratory has identified genetic loci that influence the
differential seizure response of these strains of mice to kainic acid,
the locus of greatest effect mapping to the distal region of chromosome
1 (Ferraro et al., 1997). Results presented here confirm previous work
on the relative seizure sensitivity of D2 mice compared to B6 mice and
document that the differential response of these strains to PTZ is
highly heritable with a multilocus determinism. Furthermore, several
PTZ seizure-related loci detected in this study are in the same genomic
vicinity as those mapped using a kainic acid seizure screening model,
including the locus of largest effect on distal chromosome 1 (Ferraro
et al., 1997).
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MATERIALS AND METHODS |
Animals
DBA/2J (D2) and C57BL/6J (B6) mice of both genders were
purchased from the Jackson Laboratory (Bar Harbor, ME) at ages 5-6 weeks and bred in-house to propagate mice for these studies. Male D2
mice were crossed with female B6 mice to produce an F1 generation. F2
progeny were produced via F1 intercross. Mice were generally weaned at
4 weeks of age and then group housed (three or four mice per cage) by
gender. Mice were maintained on a 12 hr light/dark schedule with food
and water available ad libitum. All experiments were
approved by Animal Care and Use Committees governing the participating laboratories.
Seizure testing
Testing was conducted when mice were 8-10 weeks of age using a
single subcutaneous injection of PTZ (Sigma, St. Louis, MO). Mice were
taken from their home cages and placed individually into Plexiglas
cubicles (width, 15 cm; length, 20 cm; height, 30 cm) with a wire mesh
floor for 30 min before PTZ injection. After injection, they were
returned immediately to the cubicle and observed for 45 min. Latencies
to focal (partial clonic), generalized (generalized clonic), and
maximal (tonic-clonic) behavioral seizures were recorded. Three mice
were observed simultaneously with seizure latencies derived using
individual digital timing devices. A dose-response survey was
conducted with male mice from each of the two parental strains
(n = 7-20 per dose per strain) in order to determine a
dose of PTZ that best distinguished their seizure sensitivity. Based on
the results of these experiments (Table
1), testing of F1 (n = 20) and F2 (n = 511) generation mice was conducted with
a dose of 80 mg/kg, s.c. At the end of the 45 min observation period,
mice were killed by cervical dislocation. Brain and liver were
harvested and frozen at  70°C. Nuclear DNA was extracted
(Lahiri and Nurnberger, 1991) from liver, quantified using the 280/260
UV absorbance ratio, and diluted with deionized water to a final
concentration of 15 ng/µl.
PTZ seizure phenotype
We defined four phases in the continuum of behavioral response
to subcutaneous PTZ injection.
Phase 1. Hypoactivity. This phase was characterized by a
progressive decrease in motor activity until the animal came to rest in
a crouched or prone position with abdomen in full contact with cage bottom.
Phase 2. Partial clonus: clonic seizure activity affecting face,
head, and/or forelimb or forelimbs. Partial or focal seizures were
brief, typically lasting 1 or 2 sec, and often accompanied by
vocalizations. Partial seizures occurred either individually or in
multiple discrete episodes before generalization.
Phase 3. Generalized clonus: sudden loss of upright posture,
whole body clonus involving all four limbs and tail, rearing, and
autonomic signs. At times phase 3 also included wild running and
jumping, although typically these latter signs signaled the onset of a
maximal seizure. The duration of generalized seizures was variable but
typically involved behavioral changes lasting for 30-60 sec followed
by a quiescent period. Most mice exhibited multiple generalized
seizures irrespective of their subsequent status for tonic hindlimb extension.
Phase 4. Tonic-clonic (maximal) seizure: generalized seizure
characterized by tonic hindlimb extension. Tonic-clonic maximal seizures were associated with death, although this could be avoided through the use of artificial respiratory techniques. Some mice recovered spontaneously. It was not unusual for mice to exhibit multiple episodes of tonic hindlimb extension within the 45 min observation period.
Seizure score
Latencies (inverse) to partial clonus (PC), generalized clonus
(GC), and tonic-clonic (TC) seizures were summed to assign each mouse a
seizure score that was used as a quantitative trait measure for mapping
according to the following equation:
Seizure score = (0.2) (1/PC latency) + (0.3) (1/GC latency) + (0.5) (1/TC latency).
At the dose of PTZ used, all F2 mice exhibited partial and generalized
clonic seizures. Only the most severely affected mice developed
tonic-clonic seizures. The weighting factors (0.2, 0.3, and 0.5) were
included as a means of incorporating a measure of the progressive
nature of the PTZ-induced seizure phenotype into the severity rating
because generalized clonus is regarded as a more significant event than
partial clonus, and tonic hindlimb extension is regarded as the most
severe component of the phenotype. In this way, the seizure score
reflects the degree of progression of the seizure syndrome in each
mouse. This strategy is similar to that used for mapping loci
influencing kainic acid-induced seizures (Ferraro et al., 1997).
Genotyping
DNA markers used for genotyping were chosen from recently
published maps based on a set of DNA microsatellite polymorphisms (Dietrich et al., 1996) with a spacing of 10-20 cM. An effort was made
to use markers with alleles that differed in size between strains by
>8 bp. For such markers, PCR-amplified sequences were analyzed by
agarose gel electrophoresis with ethidium bromide staining (Ferraro et
al., 1998b). After electrophoresis, genotypes were recorded from
Polaroid 667 (3000 ISO) black and white prints by two independent
readers and entered into a database for subsequent error checking
through comparison of the two readings. Discrepancies were resolved by
reference to a third reader. Irreconcilable discrepancies were
discarded from analysis with the genotype listed as unknown. Alternatively, gels were analyzed with a digital gel documentation system (Gel Doc 1000; Bio-Rad, Hercules, CA) that provides thermal prints of digitized images from ethidium bromide-stained gels. For
marker loci having alleles with <8 bp strain difference, genotyping involved the use of P32 end-labeled primers, PAGE, and
autoradiography as described previously (Ferraro et al., 1997).
Data analysis
Latencies to the first partial and generalized seizure and to
tonic hindlimb extension were recorded by a trained observer. All data
were entered into a Microsoft Excel (Office 97) workbook, and
statistical evaluation of seizure phenotypes was carried out with the
Excel Analysis Toolpak or with Truepistat (Richardson, TX) statistics
software. Results from dose-response experiments were analyzed with
two-way ANOVA for strain, dose, and strain-by-dose interaction effects.
Strain differences in expression of tonic hindlimb extension (maximal
seizure) were investigated using Fisher's Exact test. Gender
differences were examined in F2 generation mice by comparison of
percentages of males and females exhibiting a maximal seizure using
contingency analysis and also by comparison of gender-specific means
for each of the latency measures and the total seizure score using
Student's t test. Additionally, F2 mice were divided into
two groups based on the presence or absence of tonic hindlimb extension
(maximal seizure), and focal and generalized seizure latencies and
seizure scores were compared in these groups using Student's
t test.
The approach used for mapping PTZ seizure-related loci involved
multiple analytic strategies used previously in studies of polygenic
seizure models (Ferraro et al., 1997) as well as other polygenic models
(Risch et al., 1993; McAleer et al., 1995; Schork et al., 1995). The
first strategy involved evaluation of associations between genotypes
determined at 92 marker loci and tonic-clonic seizure response through
use of ANOVA and  2 contingency
procedures with marker locus genotypes taken as the grouping variables.
2 analysis determines the probability
that the distribution of genotypes within "seizure" and "no
seizure" subgroups of mice differs significantly from what would be
expected to occur, assuming independent segregation of alleles. Markers
found to be significant in univariate 2
analyses (threshold, p < 0.02) were evaluated to
determine which mode of inheritance gave best fit to the data.
Construction of simple genetic models for the effects of putative
seizure-related loci linked to each marker locus was carried out
through use of linear logistic regression analysis as described
previously (McAleer et al., 1995; Schork et al., 1995). The second
strategy employed stepwise multiple regression analysis to
simultaneously evaluate the influence of multiple locus (marker)
effects that surpassed a liberal statistical threshold
(p < 0.02) applied in the first strategy.
Multivariate regression allows the examination of effects of multiple
independent variables (genetic and phenotypic) on a quantitative or
qualitative outcome variable and also facilitates evaluation of locus
interactions. In the present study, the dependent variable for F2 mice
was a tonic-clonic (maximal) seizure, and thus, for both contingency
table and logistic regression analyses, F2 mice were grouped based on
expression (n = 335) or no expression (n = 176) of tonic hindlimb extension. One outcome
parameter of logistic regression analysis is an odds ratio that
reflects the chance that a specific mouse will express a PTZ-induced
maximal seizure if it harbors a specific genotype. The third analytic mapping strategy involved refining the position and effect of seizure-related loci through interval mapping using the standard (Lander et al., 1987; Lander and Botstein, 1989) and nonparametric (Kruglyak and Lander, 1995) Mapmaker programs with the overall seizure
score taken as the quantitative mapping trait. Because seizure
latencies served as quantitative parameters, and the presence of
tonic-clonic activity added a heavily weighted component to the overall
seizure score, mice expressing tonic-clonic seizures earned higher
scores that were graded by seizure latency. The final analytic strategy
involved investigating epistatic interactions between seizure-related
loci using a logistic regression model (Schork et al., 1995) but made
use of marker-based genetic models for loci evaluated in the second
strategy. We view these analyses as complementary approaches for the
dissection of a multilocus trait.
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RESULTS |
Dose-response studies and subsequent seizure testing documented
the relative seizure susceptibility of D2 mice to PTZ compared to B6
mice. Tonic-clonic seizure responses were observed for D2 mice over the
range of PTZ doses tested, whereas B6 mice were responsive only at the
highest dose (Table 1). Based on these results, screening of F1 and F2
intercross progeny was conducted using a dose of 80 mg/kg, s.c. Table
2 presents a summary of strain data for
the seizure latency traits and the overall seizure score. Heritability
estimates based on values for F1 and F2 variance indicated a
substantial genetic component for each measure (Table 3); however, these estimates are rough
because they are based on relatively small numbers of observations. The
distribution of F2 seizure scores is shown in Figure
1. F2 mice distinguished by the
expression of a tonic-clonic seizure were characterized by
significantly shorter latencies to partial and generalized clonus and
correspondingly greater seizure scores compared to F2 mice without
tonic-clonic seizures (Table 4). There
was no significant effect of weight (T = 0.495;
p = 0.31) or gender (F = 2.029;
p = 0.15, ANOVA) on latency measures or on expression of tonic-clonic seizure activity.
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Figure 1.
Distribution of seizure scores among F2 mice.
Scores were calculated as described in Materials and Methods. Other
population summary data are given in Tables 2 and 3.
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Table 4.
Comparison of clonic seizure latencies and seizure scores
in F2 generation mice as a function of maximal seizure
statusa
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Genome scanning used a total of 92 DNA markers with the mean (± SD)
interval for adjacent markers estimated to be 14.5 ± 6.5 cM. The
largest interval was 29 cM between markers D18Mit29 and D18Mit123.
Other intervals greater than 20 cM included D4Mit303 D4Mit189 (27.5 cM), D6Mit159D6Mit243 (23.5 cM), D8Mit287D8Mit69 (23 cM), D12Mit182D12Mit114 (27 cM), and D16Mit9D16Mit13 (23.6 cM).
Contingency analysis conducted to examine the association between
genotype and tonic-clonic seizure phenotype detected groups of linked
markers on chromosomes 1, 5, and 6 with additional individual markers detected on chromosomes 3 and 18 (Table
5). Logistic regression analysis revealed
significant or suggestive evidence for linkage on chromosomes 1, 3, 5, and 6 (Table 6). As expected for a
polygenic trait, PTZ seizure susceptibility loci are derived from both
"sensitive" (D2) and "resistant" (B6) strains with D2-derived
susceptibility alleles on chromosomes 1 and 6 and B6-derived
susceptibility alleles on chromosomes 3 and 5.
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Table 5.
PTZ-induced seizure-related loci: univariate contingency
table analysis of allele frequencies and seizure response in F2
generation mice
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Multipoint interval mapping conducted on the full dataset demonstrated
significant or suggestive evidence for linkage on three chromosomes,
supporting results from logistic regression analysis for loci on
chromosomes 1 and 5. In addition to corroborating locus effects that
were detected by multivariate regression, interval mapping also yielded
suggestive evidence for a B6-derived susceptibility locus on chromosome
4. Logarithm of odds (LOD) plots for chromosomes 1, 4, and 5 are
shown in Figure 2A-C.
The peak LOD score on chromosome 1 (Fig. 2A) was
associated with more distal markers D1Mit30 and D1Mit16 (LOD = 12.7, with 14.7% of total variance explained), whereas a second LOD
peak was detected more proximally, near markers D1Mit7 and D1Mit11
(LOD = 10.3 with 11.6% of total variance explained). This result
is consistent with retention of both proximal and distal chromosome 1 markers in the logistic regression analysis and suggests the presence
of at least two distinct seizure-susceptibility loci on chromosome 1. Analyses conducted using the nonparametric version of Mapmaker/QTL
yielded similar evidence for linkage on chromosome 1 (data not shown).
Interestingly, the location of the distal chromosome 1 LOD peak
coincides closely with the peak LOD score obtained in a previously
reported study of kainic acid (KA)-induced seizure susceptibility in
these two strains of mice (Ferraro et al., 1997). The KA LOD plot for
chromosome 1 markers is redrawn in Figure 2A for
purposes of comparison with the PTZ plot. Genome-wide interval mapping
also revealed the presence of a significant PTZ seizure-related locus
on chromosome 5 (LOD = 4.18 with 5.8% of the total variance
explained) and a suggestive locus on chromosome 4 (LOD = 3.14 with
4.6% of the variance explained).
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Figure 2.
Genetic maps indicating interval LOD scores for
linkage to loci controlling PTZ-induced seizure susceptibility in F2
mice. LOD scores were determined with Mapmaker/QTL using seizure score
as the trait measure. Scores represent the results of model-independent
analyses. A, Chromosome 1 [for comparison, this plot
also contains data on kainic acid seizure susceptibility redrawn from
Ferraro et al., (1997)]; B, chromosome 4;
C, chromosome 5.
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Epistatic interactions between mapped loci were evaluated in a stepwise
logistic regression model (Table 7). The
main effects fixed in this analysis were the five markers from Table 5.
Overall the results indicate two significant interactions involving
D3Mit268, one with D1Mit17 and another with D5Mit398. As is evident,
the main effects from these three loci are diminished in this model because their effects are explained by epistasis. Thus, with regard to
the D2-derived major susceptibility allele on distal chromosome 1, its
effect to increase PTZ-induced seizure risk is only observed in the
presence of a B6-derived allele at D3Mit268.
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Table 7.
Epistatic interactions between PTZ-induced seizure-related
loci: multivariate stepwise logistic regression
analysisa
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DISCUSSION |
We have conducted a full genome scan to detect influences
mediating sensitivity to maximal seizures induced by PTZ and show that
a locus on distal chromosome 1 near markers D1Mit16 and D1Mit17 exerts
the most prominent genetic effect in this model. Based on recent
convention (Lander and Kruglyak, 1995), this locus surpasses criteria
for declaring significant linkage. In addition, the position of the
chromosome 1 locus reported in the present PTZ-induced seizure model
corresponds closely with the location of a chromosome 1 influence (near
D1Mit16) detected in a KA-induced seizure model (Ferraro et al., 1997)
consistent with the possibility that the underlying genes are
identical. The fundamental importance of the D2-derived seizure
susceptibility gene or genes represented by this distal chromosome 1 locus is underscored and given added biological significance by virtue
of the fact that the KA model of seizure induction is mechanistically
different from that using PTZ. Whereas PTZ-induced seizures are
initiated by blockade of brain GABA receptors (Olsen, 1981;
Ramanjaneyulu and Ticku, 1984), KA-induced seizures are initiated by
activation of glutamate receptors (Simon et al., 1976). It is likely
that a genetic locus that affects the broad function of the two main
neurotransmitter systems in the CNS may represent an important
component of a final common pathway for regulating neuronal
excitability. We also have preliminary results indicating that the
influence of the seizure susceptibility locus on distal chromosome 1 crosses over into a nonpharmacological seizure induction paradigm
involving maximal electroshock threshold (Ferraro et al., 1998a,c).
Additional evidence for a seizure-related influence on distal mouse
chromosome 1 comes from a recent report involving a model of ethanol
withdrawal (Buck et al., 1997) suggesting that the withdrawal severity
locus detected in that study may reflect a generally lower seizure
threshold in D2 compared to B6 mice rather than being related
specifically to physiological dependence on ethanol. Several other
polygenic mouse models of epilepsy have been studied, but none have
been shown to involve chromosome 1 loci (Frankel et al., 1994, 1995;
Martin et al., 1995). It is particularly noteworthy that none of the
loci for audiogenic seizure susceptibility map to chromosome 1 (Neumann
and Collins, 1991); however, since D2 mice develop resistance to
audiogenic seizures as they mature yet are sensitive to electroshock
and PTZ seizures, it is likely that different genes are involved, with
audiogenic seizure sensitivity mediated by genes whose expression is
under developmental control. This phenomenon might be related to a
brain region-specific alteration in gene expression because audiogenic seizures involve auditory and vestibular pathways that may not be
involved in maximal electroshock seizure threshold or PTZ
seizures. Another possibility is that the chromosome 1 locus does have
an influence on sensitivity to audiogenic seizures but that the effect is relatively small compared to Asp1, Asp2, and
Asp3 and escapes detection by the methods that were used for
study. Nonetheless, the possibility that the same distal chromosome 1 locus participates in controlling neuronal hyperexcitability in such
diverse models as PTZ, KA, and ethanol-withdrawal seizures provides
considerable impetus to identify the responsible gene or genes, and
those genes whose protein products are involved in transmembrane ion
flux represent logical candidates (Ferraro and Buono, 1999). Based on
this idea, candidates on distal chromosome 1 include genes for subunits
of Na,K-ATPase (Atp1a2, Atp1b1) and a potassium
channel gene (Kcnj10).
In addition to the distal chromosome 1 locus of significant effect, a
second chromosome 1 locus that also exceeds criteria for declaring
significant linkage (Lander and Kruglyak, 1995) was detected more
proximally. Although the interval mapping procedure inherent in the
Mapmaker/QTL program does not reliably distinguish two linked
trait-influencing loci from a single locus, the detection of two
discrete LOD peaks in the Mapmaker analysis (Fig. 2A)
is consistent with retention of two distinct chromosome 1 loci in the
multivariate regression analysis (Table 5) and suggests that there is
also a proximal seizure-related locus on chromosome 1 that influences
the differential response of D2 and B6 mice to PTZ. This locus was not
detected in the KA model (Ferraro et al., 1997) and has not been
reported to be involved in other multigenic seizure models to our
knowledge. A relevant candidate gene near this locus is
Slc4a3, the gene for an anoin transport protein. The use of
interval-specific congenic strains will help to dissect these two
potentially distinct chromosome 1 influences.
Among other loci that meet proposed criteria for significant or
suggestive linkage (Lander and Kruglyak, 1995), the locus on chromosome
5 near marker D5Mit398 represents another influence whose location
overlaps that of a KA seizure-related locus (Ferraro et al., 1997). In
the present study, the chromosome 5 locus was detected both with
interval mapping procedures as well as with multivariate analysis.
Consistent with results from the KA model, the chromosome 5 seizure-susceptibility allele is derived from the relatively
seizure-resistant B6 strain and functions in a recessive mode. Although
the location of this locus appears to map slightly more distal than
that reported in the KA study, it is nonetheless within a 1-LOD
confidence interval and may reflect the same genetic influence. To our
knowledge, this locus does not coincide with seizure susceptibility
loci reported by other investigators. Relevant candidate genes near
this locus include Gabra2 and Gabrb1, which code
for subunits of GABA receptors.
Novel QTLs detected in this study include a D2-derived susceptibility
factor on chromosome 6 near D6Mit102 and a B6-derived susceptibility
factor on chromosome 3 near D3Mit268. Although these regions have not
been identified as harboring susceptibility factors in other polygenic
seizure models, the chromosome 6 influence maps to the general vicinity
of genes studied in several knock-out mice with seizure-related
phenotypes, including the neuropeptide Y gene Npy (Erickson
et al., 1996), a potassium channel gene, Kcna1 (Smart et
al., 1998), a gene for an inositol triphosphate receptor,
Itpr1 (Matsumoto et al., 1996), and the tumor necrosis factor receptor genes Tnfrsf1a and Tnfrsf1b
(Bruce et al., 1996). The possibility that these genes represent genes
of partial effect in controlling seizure responsiveness in
multifactorial models deserves investigation with regard to natural
variation in sequences between B6 and D2 mice.
Interval mapping also yielded suggestive evidence for a seizure-related
locus on the proximal part of chromosome 4. This effect is relatively
weak and might be expected to occur by chance frequently enough in a
genome scan as to be regarded as a potential false-positive result.
Interestingly, a proximal chromosome 4 locus was also detected in the
KA study, however in that case, the seizure susceptibility allele
originated in the B6 strain (Ferraro et al., 1997), whereas in the
present study, higher PTZ seizure scores are associated with the
presence of D2 alleles. It is possible that the locus detected here may
be related to the audiogenic seizure susceptibility locus
Asp-2, a D2-derived susceptibility factor mapped to this approximate chromosome 4 region (Neumann and Collins, 1991) or to a D2
susceptibility locus for ethanol withdrawal-induced seizures also
recently mapped to this area (Buck et al., 1997). The possibility that
this locus influences such diverse seizure phenotypes suggests that it
too may represent a fundamentally important gene involved in neuronal hyperexcitability.
In summary, we continue to characterize the genetic factors that
mediate the dramatic difference in seizure response between D2 and B6
mice. Based on results of this and previous studies (Ferraro et al.,
1997), we conclude that, like susceptibility to kainic acid-induced
seizures, sensitivity to PTZ-induced seizures is a multifactorial trait
with the strongest genetic influence originating from the distal region
of chromosome 1. Isolation of the gene or genes responsible for this
effect may lead to fundamental new insights into the control of
neuronal excitability and the understanding of seizure disorders.
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FOOTNOTES |
Received Feb. 9, 1999; revised May 19, 1999; accepted May 26, 1999.
This work was supported by National Institutes of Health Grant NS33243.
We thank Lisa Tarrantino for assistance with nonparametric Mapmaker analyses.
Correspondence should be addressed to Dr. Thomas N. Ferraro, University
of Pennsylvania, Department of Psychiatry, Center for Neurobiology and
Behavior, Room 127 CRB, 415 Curie Boulevard, Philadelphia, PA
19104-6140.
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