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The Journal of Neuroscience, January 1, 1999, 19(1):133-146
Heparin-Binding Epidermal Growth Factor-Like Growth Factor in
Hippocampus: Modulation of Expression by Seizures and Anti-Excitotoxic
Action
Lisa A.
Opanashuk1,
Robert J.
Mark1, 2,
Julie
Porter1,
Deborah
Damm3,
Mark P.
Mattson1, 2, and
Kim B.
Seroogy1
1 Department of Anatomy and Neurobiology and
2 Sanders-Brown Research Center on Aging, University of
Kentucky, Lexington, Kentucky 40536, and 3 Scios
Inc., Mountain View, California 94043
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ABSTRACT |
The expression of heparin-binding epidermal growth factor-like
growth factor (HB-EGF), an EGF receptor ligand, was investigated in rat
forebrain under basal conditions and after kainate-induced excitotoxic
seizures. In addition, a potential neuroprotective role for HB-EGF was
assessed in hippocampal cultures. In situ hybridization
analysis of HB-EGF mRNA in developing rat hippocampus revealed its
expression in all principle cell layers of hippocampus from birth to
postnatal day (P) 7, whereas from P14 through adulthood, expression
decreased in the pyramidal cell layer versus the dentate gyrus granule
cells. After kainate-induced excitotoxic seizures, levels of HB-EGF
mRNA increased markedly in the hippocampus, as well as in several other
cortical and limbic forebrain regions. In the hippocampus, HB-EGF mRNA
expression increased within 3 hr after kainate treatment, continued to
increase until 24 hr, and then decreased; increases occurred in the
dentate gyrus granule cells, in the molecular layer of the dentate
gyrus, and in and around hippocampal pyramidal CA3 and CA1 neurons. At
48 hr after kainate treatment, HB-EGF mRNA remained elevated in
vulnerable brain regions of the hippocampus and amygdaloid complex.
Western blot analysis revealed increased levels of HB-EGF protein in
the hippocampus after kainate administration, with a peak at 24 hr. Pretreatment of embryonic hippocampal cell cultures with HB-EGF protected neurons against kainate toxicity. The kainate-induced elevation of [Ca2+]i in hippocampal
neurons was not altered in cultures pretreated with HB-EGF, suggesting
an excitoprotective mechanism different from that of previously
characterized excitoprotective growth factors. Taken together, these
results suggest that HB-EGF may function as an endogenous
neuroprotective agent after seizure-induced neural activity/injury.
Key words:
HB-EGF; hippocampus; neuroprotection; epilepsy; excitotoxicity; in situ hybridization; kainic acid; calcium
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INTRODUCTION |
Heparin-binding epidermal growth
factor-like growth factor (HB-EGF) is a member of the epidermal growth
factor (EGF) family of structurally related polypeptides that include
EGF, transforming growth factor- (TGF), amphiregulin, and
betacellulin (Higashiyama et al., 1991 , 1992; Watanabe et al., 1994;
Barnard et al., 1995). Each family member activates the EGF receptor
(EGF-R), a 170 kDa transmembrane glycoprotein with intrinsic tyrosine
kinase activity (Besner et al., 1992). HB-EGF and other EGF-R ligands
are synthesized as membrane-anchored precursors that during proteolytic
cleavage produce diffusible factors that mediate their effects on
various cellular processes (Raab et al., 1994; Cook et al., 1995).
HB-EGF and amphiregulin can be distinguished from other members of the EGF family by the presence of a heparin-binding domain, which interacts
with membrane-bound heparin sulfate proteoglycans and may thereby
enhance EGF receptor activation. HB-EGF mRNA is expressed in brain
(Abraham et al., 1993), and its precise cellular distribution is
beginning to be elucidated (Opanashuk et al., 1995; Mishima et al.,
1996). EGF-R mRNA and protein are expressed in brain where they are
localized to many different cell populations, including neurons and
astrocytes (Gomez-Pinilla et al., 1988; Faundez et al., 1992; Tucker et
al., 1993; Seroogy et al., 1994, 1995; Kornblum et al., 1995, 1997a).
Cultured embryonic neurons and glia from rodent brain also express
EGF-R (Mazzoni and Kenigsberg, 1994; Yamada et al., 1997).
Both TGF and EGF promote survival and/or process outgrowth of
cultured neurons from several brain regions (Morrison et al., 1987,
1988; Kornblum et al., 1990; Casper et al., 1991; Ferrari et al., 1991;
Alexi and Hefti, 1993), indicating possible neurotrophic functions for
EGF-R agonists. EGF promotes hippocampal long-term potentiation (Terlau
and Seifert, 1989; Abe et al., 1991, 1992) and protects dopaminergic
neurons against glutamate (Casper and Blum, 1995) and
1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) (Park and
Mytilineau, 1992; Schneider and DiStefano, 1995) toxicity, suggesting
potential neuromodulatory and neuroprotective roles for EGF-R ligands.
Because HB-EGF interacts with the EGF-R, it is reasonable to
consider that HB-EGF serves roles overlapping those of EGF and
TGF.
Administration of the excitotoxin kainate to adult rodents induces
seizures and a stereotyped pattern of neuronal degeneration involving
limbic and cortical structures, with certain hippocampal neurons being
particularly vulnerable (Nadler et al., 1978; Sperk et al., 1983;
Ben-Ari, 1985). During and after seizures induced by kainate, the
expression of several neurotrophic factors and cytokines increases,
including NGF (Gall and Isackson, 1989; Gall et al., 1991), basic
fibroblast growth factor (bFGF) (Humpel et al., 1993; Gall et
al., 1994), brain-derived neurotrophic factor (BDNF) (Isackson et al.,
1991; Dugich-Djordjevic et al., 1992), glial cell line-derived
neurotrophic factor (GDNF) (Humpel et al., 1994), and tumor necrosis
factor- (TNF) (Bruce et al., 1996). Such injury-responsive
neurotrophic factors and cytokines may function to prevent neuronal
death (for review, see Mattson and Scheff, 1994; Mattson and Lindvall,
1997). In the present study we examined the cellular expression of
HB-EGF in hippocampus, cortex, and limbic structures under basal
conditions and after kainate-induced seizures, and we tested the
hypothesis that HB-EGF serves an excitoprotective role.
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MATERIALS AND METHODS |
Animals and kainate administration. Male and female
Sprague Dawley rats (Harlan Sprague Dawley, Indianapolis, IN) taken at postnatal day (P) 0, P7, P14, and P21, and adult ages (>60 d old, n = 4 for each age) were used to examine the in
situ hybridization localization of HB-EGF mRNA in hippocampus
during postnatal development. Rat pups taken at the day of birth (P0)
and at P7 were deeply anesthetized by hypothermia and decapitated.
Animals at the other ages were deeply anesthetized with sodium
pentobarbital before decapitation. The brains were rapidly dissected
out, quickly frozen over dry ice, and stored at  80°C until further
processing. Adult (>60 d old) male Sprague Dawley rats weighing
200-250 gm were used for the kainic acid experiments. Kainate (Sigma,
St. Louis, MO) was injected intraperitoneally at 12 mg/kg (dissolved in
0.9% saline, pH 7.0). Control animals received an equivalent volume of
saline. After kainate administration, rats were monitored for convulsive activity for 8 hr and rated on a scale of 1-5 as described previously (Sperk et al., 1983). Behavioral changes were evident within
30 min of kainate administration and consisted of "wet-dog shakes"
followed by staring spells, forehead-nodding, forelimb myoclonus,
rearing, and excessive salivation. Only animals achieving at least a
level of 3 (Sperk et al., 1983) were used for analyses. At various
survival periods after kainate injection (3, 6, 12, 24, and 48 hr),
rats (n = 3-4 per time point) were deeply anesthetized with an overdose of sodium pentobarbital and decapitated. The brains
were quickly removed and processed for mRNA or protein analyses as
described below.
RNA isolation and Northern blot analysis. Hippocampi were
rapidly removed and placed in Trizol reagent (Life Technologies BRL,
Gaithersburg, MD), and tissue was homogenized using a Polytron homogenizer. The homogenate was extracted twice with phenol/chloroform, and RNA was precipitated with isopropanol. The RNA pellet was air-dried
and dissolved in DEPC-treated water, and the RNA concentration was
determined by measuring OD260. RNA (20 µg) was separated
by electrophoresis through a 1.2% formaldehyde-agarose gel containing ethidium bromide. RNA was then transferred to nylon membranes by vacuum
transfer in 10× SSC (0.3 M sodium citrate, 3.0 M NaCl); RNA integrity and transfer efficiency were
visualized by UV light. Membranes were prehybridized in a solution
containing 2× SSC, 5× Denhardt's solution, and 2% SDS for 1 hr at
65°C. The antisense HB-EGF cRNA was transcribed from a pBluescript
vector containing a 258 base pair Kpn fragment (bp 1-258) from the 5'
end of the cloned rat cDNA (GenBank accession number L05389) using T3 RNA polymerase in the presence of [32P]-UTP (cDNA
was kindly provided by Judith Abraham, Scios Inc., Mountain View, CA).
The hybridization reaction was allowed to proceed for 20 hr at 65°C
in a solution containing 50% formamide, 2× SSC, 5× Denhardt's
solution, 10% dextran sulfate, 2% SDS, and the
[32P]-labeled probe at a concentration of 2 × 106 cpm/ml. After treatment with 1 µg/ml
ribonuclease A (RNase) at room temperature, membranes were sequentially
washed in decreasing concentrations of SSC containing 0.25% SDS at
65°C. The final wash in 0.1× SSC was performed at room temperature.
Membranes were exposed to X-OMAT film (Kodak, Rochester, NY) for 5-7
d, and specific hybridization was visualized by autoradiography. Membranes were stripped and reprobed with a
[32P]-labeled  actin probe (kindly provided by
James Hyde, University of Kentucky, Lexington, KY). HB-EGF mRNA levels
were quantified using NIH Image software and normalized relative to
actin mRNA levels. Control membranes were pretreated with 1 µg/ml
RNase for 30 min before hybridization or were hybridized with the
[32P]-labeled sense cRNA HB-EGF probe (transcribed
with T7 RNA polymerase). No specific hybridization was observed in
either case (data not shown). As a positive control, RNA was isolated
from rat lung, an organ known to express HB-EGF mRNA (Abraham et al.,
1993), and hybridized with both the antisense and sense HB-EGF cRNA
probes. The 2.5 kb transcript was detected on films from membrane
probed with the antisense cRNA probe, whereas membranes hybridized with sense probe were devoid of signal.
In situ hybridization. Coronal tissue sections through
the forebrain were cut using a cryostat (14 µm thickness for the
developmental studies, 10 µm thickness for the adult rat kainate
treatment experiments) and stored at 20°C. The slide-mounted
sections were processed for the localization of HB-EGF mRNA by in
situ hybridization as described previously (Seroogy et al., 1993,
1994, 1995; Seroogy and Herman, 1997). The antisense HB-EGF cRNA was
transcribed in vitro from a pBluescript vector containing a
258 bp fragment from the 5' end of the cloned rat cDNA using T3 RNA
polymerase in the presence of [35S]UTP.
Hybridization was accomplished at 60°C for 18-20 hr in a solution
containing the [35S]-labeled HB-EGF cRNA probe at
a concentration of 1 × 106 cpm/0.50 ml per
slide. After post-hybridization ribonuclease treatment and washes in
SSC, the distribution of hybridization was localized by film [(-Max
Hyperfilm; Amersham, Arlington Heights, IL) 10 d exposures for the
experimental/seizure series, 14 d exposures for the developmental
series] and then emulsion [(Kodak NTB2) 4 week exposures for the
experimental/seizure series, 6 week exposures for the developmental
series] autoradiography. The differences in exposure times were
chosen, on the one hand, to accentuate the normal developmental
distribution of HB-EGF mRNA, and, on the other hand, to emphasize the
effect between control and experimental/seizure-induced expression
without overexposing the film at certain time points. Control sections
were pretreated with ribonuclease A (45°C for 30 min) before
hybridization with the antisense probe or were hybridized with the
[35S]-labeled sense sequence (transcribed using T7
polymerase). No specific labeling was observed in tissue processed
under either control condition.
Western blot analysis. These methods were similar to those
described in our previous studies (Cheng et al., 1995). Hippocampal homogenates were prepared as detailed elsewhere (Cheng et al., 1995)
and assayed for protein content at 562 nm using a BCA kit (Pierce,
Rockford, IL) according to the manufacturer's protocol. Proteins were
separated by SDS-PAGE in 15% gel and then transferred electrophoretically to Hybond Membrane (Bio-Rad, Hercules, CA). The
membranes were blocked in TBS containing 5.0% nonfat milk and 0.1%
Tween-20, and then incubated overnight at 4°C in PBS containing
primary antibody (goat polyclonal anti-HB-EGF antibody 197; provided by
Judith Abraham, Scios Inc.) The membranes were then incubated
for 1 hr at room temperature in TBS containing a peroxidase-conjugated
rabbit anti-goat secondary antibody (Jackson ImmunoResearch
Laboratories, West Grove, PA) and processed further using a
chemiluminescence detection system (ECL system; Amersham). Human
recombinant HB-EGF (R&D Systems, Minneapolis, MN) and lung tissue were
used as positive controls for the HB-EGF antibody, and BSA was used as
a negative control. To verify equal protein gel loading, membranes were
stripped and reprobed with an anti-neurofilament (200 kDa) protein
antibody (1:500 dilution; Sternberger Monoclonals, Lutherville,
MD). Equivalent electrophoretic transfer of protein was verified on
membranes reversibly stained with Ponceau S dye.
Hippocampal cell cultures and quantification of neuronal
survival. Primary hippocampal cell cultures were established from embryonic rats (day 18 of gestation) as detailed elsewhere (Mattson et
al., 1995). Cultures were maintained in Eagle's Minimum Essential Medium supplemented with 10% (v/v) heat-inactivated fetal bovine serum
(Life Technologies), 20 mM KCl, and 1 mM
pyruvate. Experiments were performed in cultures that had been
maintained for 6-10 d. In these cultures, ~90% of the cells are
neurons, and the remaining cells are astrocytes, as judged by
characteristic morphology and differential immunoreactivity with
antibodies to neuron-specific (neurofilament, MAP2, and tau) and
astrocyte-specific (glial fibrillary acidic protein and S-100)
proteins (Mattson et al., 1993, 1995). Immediately before experimental
treatment, the culture maintenance medium was replaced with Locke's
solution containing (in mM): NaCl 154, KCl 5.6, CaCl2 2.3, MgCl2 1.0, NaHCO3 3.6, glucose 10, and HEPES buffer 5, pH 7.2. Cultures were pretreated for 16 hr with HB-EGF in Locke's solution before the addition of kainate (Sigma). Neuronal survival was quantified by counting the number of
viable neurons in premarked microscope fields before and at indicated
time points after exposure to experimental treatments as described
previously (Mattson et al., 1995).
Measurement of intracellular calcium levels. The
intracellular free calcium concentration
([Ca2+]i) in individual
neuronal cell bodies was quantified by ratiometric imaging of the
calcium indicator dye fura-2 acetoxymethyl ester as described
previously (Mark et al., 1995; Mattson et al., 1995). Cells were
pretreated for 16 hr with 100 ng/ml HB-EGF or vehicle and then
incubated at 37°C with fura-2 for 30 min. After rinsing, cultures
were placed in HBSS supplemented with 10 mM glucose
and 10 mM HEPES, pH 7.2. Cells were imaged using a Zeiss
Attofluor system, which included a Zeiss Axiovert microscope with a
40× oil objective and an Attofluor-intensified CCD camera. The dye was
excited at 340 and 380 nm, and images were taken of the emitted fluorescence after excitation at each wavelength. The method of Grynkiewicz et al. (1985) was used to calibrate the system and quantify
([Ca2+]i). The
[Ca2+]i in individual neuronal cell
bodies was monitored at 7 sec intervals for 1 min before, and 5 min
after, exposure to kainate. Values for peak
[Ca2+]i were determined and used for
statistical comparisons between control cultures and those pretreated
with HB-EGF.
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RESULTS |
Postnatal ontogeny of HB-EGF mRNA expression in rat hippocampus
and forebrain
As determined by in situ hybridization, expression of
HB-EGF mRNA was evident in hippocampal neurons at all ages examined (Fig. 1). From P0 to P7, labeling was
distributed within all principle cell layers of the hippocampus,
including stratum pyramidale fields CA1-CA3 and stratum granulosum of
the dentate gyrus. However, by P14 and through adulthood, hybridization
decreased substantially in the pyramidal cell layer to levels just
slightly above background. In contrast, levels of HB-EGF mRNA appeared
to slightly increase in stratum granulosum throughout development (Fig.
1). During development and in the adult, labeled cells were never
detected in the molecular layers of the hippocampus or in the hilus of the dentate gyrus. In neocortex, hybridization for HB-EGF mRNA was
localized to cell bodies in middle layers, with levels being greatest
at P7 and then declining through adulthood (Fig. 1). The pattern of
neocortical labeling appears to correspond to the region of
somatosensory cortex. HB-EGF mRNA was also moderately expressed
neonatally in other cortical areas, including entorhinal, piriform, and
retrosplenial cortices; hybridization levels decreased with increasing
age in these regions (data not shown). Moderate labeling for HB-EGF
mRNA was also present neonatally in the taenia tecta and within several
thalamic regions, including the dorsolateral and medial geniculate
nuclei and the ventrobasal complex (data not shown). Again,
hybridization levels in these latter regions declined substantially
throughout postnatal development to very low to undectectable levels in
the adult. Labeling for HB-EGF mRNA was never localized to regions of
white matter in the forebrain (i.e., corpus callosum, anterior
commissure, internal and external capsules, lateral olfactory tract,
optic tract, etc.) at any of the ages examined.
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Figure 1.
Expression of HB-EGF mRNA in developing
hippocampus. Autoradiograms showing the in situ
hybridization localization of HB-EGF mRNA in coronal sections through
the hippocampus at the indicated postnatal day ages. Note that at
P7, labeling is present throughout hippocampal fields
CA1 and CA3 and dentate gyrus stratum
granulosum (sg), whereas in older (P14, P21,
Adult) rats, HB-EGF mRNA expression is substantially reduced in
the pyramidal cell layer relative to the stratum granulosum. In
neocortex, HB-EGF cRNA hybridization is prominent in the middle layers
(arrowheads), with levels gradually declining from P7 to
adulthood. The bottom panel (sense)
demonstrates the lack of hybridization obtained with the control sense
cRNA probe in a section through the adult hippocampus. Film exposure,
14 d; section thickness, 14 µm. Scale bar, 1000 µm.
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HB-EGF mRNA expression in hippocampus after
kainate administration
To determine whether HB-EGF mRNA is modulated by neuronal
activity/injury, kainate was administered to adult rats (12 mg/kg, i.p.) to induce seizures, and rats were killed 3, 6, 12, 24 and 48 hr
later. We first assessed overall levels of HB-EGF mRNA in hippocampus
by Northern blot analysis (Fig. 2). An
increase in the 2.5 kb HB-EGF transcript was detected 3 hr after
kainate administration, and the level of HB-EGF mRNA continued to
increase through 6 and 12 hr, with peak expression occurring at the 24 hr time point. HB-EGF mRNA levels were declining toward control levels
at 48 hr after kainate administration (Fig. 2).
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Figure 2.
A, Northern blot analysis of HB-EGF
mRNA levels in adult rat hippocampus at various survival times (3-48
hr) after kainate administration. Total RNA (20 µg/lane) was
separated on a 1.2% agarose gel, transferred to nylon membrane, and
hybridized with an antisense 32P-cRNA HB-EGF probe
(top). Membranes were stripped and reprobed with a
32P-labeled actin cRNA to control for equal loading of
RNA (bottom). HB-EGF mRNA was detected by
autoradiography with an exposure time of 5 d. Levels of the 2.5 kb
transcript corresponding to HB-EGF mRNA were elevated 3 hr after
kainate treatment and continued to increase through the 24 hr time
point. By 48 hr, HB-EGF mRNA levels were declining. Con,
Control. B, Densitometric analysis of HB-EGF mRNA levels
at various times after kainate administration. HB-EGF mRNA levels were
normalized relative to actin mRNA levels. Data are expressed as
mean ± SEM of determinations made in three rats per time point
and were analyzed by one-way ANOVA with Duncan post hoc
analysis. *p < 0.05 compared with the control (0 hr) value.
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In situ hybridization analyses demonstrated an extensive
increase in HB-EGF mRNA within the hippocampus, as well as in other limbic and cortical structures, after kainate treatment (Fig. 3; see summary in Table
1). In the hippocampus, there was a
pronounced increase in HB-EGF cRNA hybridization in the stratum
granulosum of the dentate gyrus that was evident at 3 hr, reached
maximal levels at 6 hr, and declined to control levels by 48 hr after kainate administration (Figs. 3, 4). By
the 6 hr time point, increased expression was no longer restricted to
the dentate granule cells such that labeled perikarya were now
scattered in the hilus and molecular layer of the dentate gyrus (Fig.
4C). The densely labeled cells were most numerous in these
regions between 12 and 24 hr after kainate treatment (Figs.
3D,E, 4D); by 48 hr, HB-EGF
cRNA-hybridizing cells were no longer detected in the dentate hilus and
molecular layer (Fig. 4E), as in control brains.
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Figure 3.
Kainate-induced increase of HB-EGF mRNA expression
in hippocampus. Autoradiograms demonstrating the in situ
hybridization localization of HB-EGF mRNA in coronal sections through
the hippocampus in a saline-injected control rat
(A) and in rats killed 3 (B), 6 (C), 12 (D), 24 (E), and 48 hr
(F) after kainate administration. Expression of
HB-EGF mRNA is upregulated in the granule cell layer [stratum
granulosum (sg)] of the dentate gyrus 3-6 hr after
kainate treatment (B, C) but then declines to control
levels by 48 hr (F). Kainate treatment induces
prominent hybridization in and around the pyramidal cell layers of
hippocampal subfields CA1 and CA3 at the
12 and 24 hr time points (D, E); by 48 hr, labeling is
restricted to the CA1 region in the hippocampus
(F). In neocortex (nc), HB-EGF
mRNA expression increases from 3 to 12 hr after kainate treatment
(B-D) and then decreases to control levels by 48 hr (E, F). Note that hybridization signal is also
present in and around areas of kainate-induced cell loss at the 24 and
48 hr time points (E, F), including regions of
the dorsal lateral thalamus (arrows in
F), amygdaloid complex (amg), and
piriform cortex (pc). Film exposure, 10 d;
section thickness, 10 µm. Note that because of thinner sectioning and
shorter exposure time, the control section in A cannot
be directly compared with the normal adult section in Figure 1. Scale
bar, 1000 µm.
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Figure 4.
Kainate-induced increase of HB-EGF mRNA in dentate
gyrus. Dark-field photomicrographs showing the cellular distribution of
HB-EGF mRNA in sections through the dentate gyrus in a saline-injected
control rat (A) and in rats killed 3 (B), 6 (C), 24 (D), and 48 hr (E) after
kainate administration. Note that kainate treatment initially increased
HB-EGF cRNA hybridization in the granule cell layer [stratum
granulosum (sg)] at the 3 hr time point
(B). However, from 6 to 24 hr after kainate
injection, numerous labeled cells (arrowheads indicate
several examples) were distributed throughout the hilus
(h) and molecular layer (ml)
(C, D). By 48 hr, cellular expression of HB-EGF mRNA was
barely detectable within the dentate gyrus (E).
Scale bar, 50 µm.
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Between 12 and 24 hr after kainate administration, HB-EGF cRNA
hybridization was prominently elevated in perikarya within and around
stratum pyramidale of the hippocampus (Fig. 3D,E). In and
adjacent to region CA3, labeling was highest at 12 hr and declined to
control levels by 48 hr. Cells expressing HB-EGF mRNA were observed
within region CA1 and were scattered in the molecular layers
surrounding CA1 (strata oriens and radiatum) by 12 hr after kainate
administration (Figs. 3D,
5C). However, at later
survival periods, the labeled cells were located in successively closer proximity to the pyramidal cell layer of CA1 (Fig. 5D) such
that by 48 hr, expression was restricted to cells dispersed within or
along the edge of the CA1 cell layer (Figs. 3F,
5E).
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Figure 5.
Kainate-induced increase of HB-EGF mRNA in
hippocampal region CA1. Dark-field photomicrographs show the
autoradiographic localization of HB-EGF cRNA in situ
hybridization in the CA1 region of hippocampus in a saline-injected
control rat (A) and in rats killed 3 (B), 12 (C), 24 (D), and 48 hr (E) after
kainate administration. Note that by 12 hr after kainate injection,
labeling for HB-EGF mRNA was induced in stratum pyramidale
(sp) and particularly within numerous cells scattered
throughout the stratum oriens (so) and stratum radiatum
(sr) molecular layers (C, arrowheads
indicate examples of labeled somata). By 24 hr, densely labeled cells
were situated in close proximity to the pyramidal cell layer
(D). At 48 hr after kainate treatment, perikarya
expressing HB-EGF mRNA were intermittently dispersed within and along
the edges of CA1 stratum pyramidale (E). Scale
bar, 50 µm.
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HB-EGF mRNA expression in extra-hippocampal regions after
kainate administration
Injection of kainate induced the expression of HB-EGF mRNA in
several forebrain limbic and cortical regions outside of the hippocampus (Table 1). In the neocortex, hybridization signal was
elevated in middle layers within 3 hr of kainate administration (Figs.
3B, 6B) and
peaked between 12 and 24 hr, at which time HB-EGF cRNA-hybridizing
cells appeared to encompass nearly all cortical laminae (Figs.
3D,E, 6C,D). However, by the 48 hr time point, labeled cells were again absent from the neocortex (Figs. 3F, 6E). Kainate treatment increased
HB-EGF mRNA levels in piriform cortex within 3 hr of administration
(Fig. 6), with highest levels of expression observed at the 12 and 24 hr time points (Fig. 6). In addition to the piriform cortex, transient
elevations in HB-EGF mRNA expression were found in other
olfactory-related areas, including the entorhinal cortex, amygdaloid
nuclei, olfactory tubercle, and anterior olfactory nuclei after kainate
treatment (Table 1). Kainate administration also induced dense
hybridization for HB-EGF mRNA in numerous perikarya of the lateral
septal nuclei, with peak expression found between 12 and 24 hr after
injection (Fig. 6). Transient increases in HB-EGF cRNA hybridization
were also noted in several thalamic and hypothalamic nuclei (Table 1). Finally, mainly at the 24 and 48 hr time points, perikarya densely labeled for HB-EGF mRNA surrounded prescribed areas of the perirhinal, piriform, and entorhinal cortices and amygdala, as well as several thalamic regions (Figs. 3, 6; Table 1).
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Figure 6.
Kainate-induced expression of HB-EGF mRNA in
septum and cortex. Autoradiograms demonstrating the regional
distribution of HB-EGF cRNA hybridization in coronal sections through
the septal nuclei in a saline-injected control rat
(A) and in rats killed at 3 (B), 12 (C), 24 (D), and 48 hr (E) after
kainate administration. Expression of HB-EGF mRNA is induced in the
lateral septal nuclei (ls), neocortex
(nc), and piriform cortex (pc) by
3 hr after kainate treatment (B), with peak
expression levels found between 12 and 24 hr after kainate treatment
(C, D). By 48 hr (E), labeling is
restricted to scattered cells within the lateral septum and piriform
cortex and to degenerating areas of perirhinal cortex
(asterisks). Film exposure, 10 d; section
thickness, 10 µm. Scale bar, 1000 µm.
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Relationships between kainate-induced neuronal degeneration and
HB-EGF mRNA localization
Systemic administration of kainate results in a characteristic
pattern of neuronal cell loss, which in the hippocampus involves regions CA1 and CA3 strata pyramidale, as well as hilar neurons (Nadler
et al., 1978; Sperk et al., 1983; Ben-Ari, 1985). As expected, this
pattern of cell loss was observed in the present study. At the 48 hr
survival time, HB-EGF mRNA-labeled cells were consistently present in
the proximity of vulnerable regions of hippocampus (Figs. 3, 5). In
addition, degenerating regions of amygdala, piriform cortex, and
related areas of cortex and thalamus were encircled by HB-EGF
cRNA-hybridizing cells 24-48 hr after kainate administration (Figs. 3,
6, 7). An example of this hybridization
pattern can be seen in Figure 7 where HB-EGF mRNA-expressing perikarya
are lining the medial edge of the amygdala, a structure that has
undergone extensive cell loss 48 hr after kainate treatment.
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Figure 7.
Kainate-induced expression of HB-EGF mRNA in
extra-hippocampal regions of neuronal cell loss. Dark-field
photomicrograph shows HB-EGF cRNA-hybridizing cells lining the medial
edge of the amygdaloid complex (amg) in a rat killed 48 hr after kainate administration. Scale bar, 90 µm.
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HB-EGF protein expression in hippocampus after
kainate administration
Western blot analysis was used to examine alterations in HB-EGF
protein levels in hippocampus at various survival times after kainate
treatment. Consistent with previous studies (Ono et al., 1994; Kim et
al., 1995; Davis et al., 1996), HB-EGF protein was identified as four
species, with apparent molecular weights ranging from 14 to 27 kDa
(Fig. 8); none of the four bands were
present when the primary antibody was preincubated with excess (50 ng) recombinant human HB-EGF (data not shown). Levels of the 14 and 27 kDa
isoforms increased after 3 hr and peaked at 24 hr after kainate
treatment. Levels of HB-EGF protein declined but were still above
control levels 48 hr after kainate administration (Fig. 8). By 72 hr
after kainate treatment, expression of the 14 kDa HB-EGF isoform
remained elevated.
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Figure 8.
Western blot analysis of HB-EGF protein
in rat hippocampus (top panel), in a
saline-injected control rat (Con), and in rats killed at
the indicated time points after kainate administration. Protein (100 µg/lane) was separated by SDS-PAGE, transferred to Hybond (Amersham)
membrane, and probed with a polyclonal antibody to HB-EGF (kindly
provided by Judith Abraham, Scios Inc.). Proteins were visualized by
enhanced chemiluminescence. Recombinant human HB-EGF (10 ng) was used
as a positive control. Four bands corresponding to HB-EGF with apparent
molecular weights of 27, 24, 17, and 14 kDa are detected in hippocampal
extracts. Similar results were obtained in three different rats
for each time point. Membranes were also probed with a monoclonal
antibody for neurofilament protein (bottom panel)
to ensure equivalent gel loading.
|
|
HB-EGF protects hippocampal neurons against kainate toxicity
Exposure of cultures to kainate (10-50 µM for 12 hr) resulted in concentration-dependent decreases in neuronal survival
(Fig. 9). Approximately 40 and 85% of
rat hippocampal neurons degenerated after exposure to 10 and 50 µM kainate, respectively. Neuronal survival was increased
in a concentration-dependent manner after pretreatment with HB-EGF.
When cultures were pretreated with HB-EGF (10-100 ng/ml) for 16 hr,
there was a dramatic reduction in kainate-induced neuronal damage when
compared with cultures not receiving growth factor. Shorter
pretreatments with HB-EGF (2-6 hr exposures to 100 ng/ml HB-EGF) did
not protect neurons against kainate toxicity (data not shown). The
protection against kainate toxicity afforded by HB-EGF was sustained
for at least 48 hr (Fig. 9B), indicating that HB-EGF
prevented neuronal death rather than just delaying the death. Calcium
influx has previously been shown to play an important role in neuronal
injury induced by kainate (Choi, 1987; Giusti et al., 1995). To
determine whether HB-EGF protects against neurotoxicity by suppressing
the kainate-induced rise in
[Ca2+]i, calcium levels were
measured in cultured hippocampal neurons by ratiometric imaging of the
fluorescent calcium indicator dye fura-2. Cultures were pretreated with
100 ng/ml HB-EGF for 16 hr and then challenged with 50 µM
kainate for 5 min. After exposure to kainate the
[Ca2+]i in neurons was increased to
~350 nM compared with 100 nM
[Ca2+]i in neurons exposed to vehicle
(Fig. 10). The elevation in
[Ca2+]i in response to kainate was not
attenuated by pretreatment with HB-EGF.
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Figure 9.
HB-EGF protects against kainate neurotoxicity in
hippocampal cell cultures. A, Cultures were pretreated
with 1-100 ng/ml human recombinant HB-EGF for 16 hr and were then
exposed to either 10 or 50 µM kainate. Neuronal survival
was assessed 12 hr after kainate treatment. Values represent the
mean ± SEM of determinations made in five separate experiments.
Pair-wise comparisons were made by ANOVA with Scheffé's
post hoc analysis. *p < 0.01 compared with the value for vehicle-treated cultures not exposed to
HB-EGF; **p < 0.01 compared with values for
cultures pretreated with either 0 or 1 ng/ml HB-EGF and then exposed to
the same concentration of kainate. B, Cultures were
pretreated with 100 ng/ml HB-EGF for 16 hr and then exposed to vehicle
or 10 µM kainate. Neuronal survival was assessed at the
indicated time points after kainate administration. Values are the
mean ± SEM of determinations made in three separate experiments.
Pair-wise comparisons were made by ANOVA with Scheffé's
post hoc analysis. *p < 0.01, **p < 0.001 compared with each of the other values
at that time point.
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Figure 10.
HB-EGF does not affect kainate-induced elevations
in [Ca2+]i. Hippocampal cultures were
pretreated with 100 ng/ml HB-EGF for 16 hr, and the
[Ca2+]i in neurons was then determined
(time 0). Cells were then exposed to 50 µM kainate for 5 min, and the [Ca2+]i was again
measured in the same neurons. Values are the mean ± SEM of
determinations made in four separate cultures (15-22 neurons per
culture).
|
|
| |
DISCUSSION |
The principal findings of the present study reveal that HB-EGF
mRNA and protein are dramatically upregulated in the hippocampal formation after seizure-induced neuronal activity/injury. Sustained HB-EGF expression was also induced in forebrain areas vulnerable to
degeneration after seizures. Moreover, our in vitro data
indicate that HB-EGF is neuroprotective for hippocampal neurons against kainate toxicity, with an excitoprotective mechanism different from
that of previously characterized excitoprotective trophic factors.
Taken together, these results provide the first evidence that a member
of the EGF family may play a role in neuroprotection and in the
longer-term neuropathological changes associated with seizures.
The regional and temporal patterns of HB-EGF mRNA expression in
response to kainate-induced seizures exhibited features similar to
those described previously for other neurotrophic factors. Accordingly,
HB-EGF mRNA was robustly expressed in several limbic, cortical, and
subcortical regions after kainate administration. The earliest
alterations in HB-EGF mRNA levels occurred in hippocampus, followed by
a more gradual and widespread induction in cortical and septal areas.
In hippocampus, HB-EGF mRNA was rapidly induced in neurons of the
dentate gyrus granule cell layer followed by a more protracted
upregulation in the CA1-CA3 regions and molecular layers. The
alterations in hippocampal HB-EGF mRNA were accompanied by a
corresponding elevation in HB-EGF protein; both mRNA and protein levels
appeared to peak between 12 and 24 hr after kainate injection. These
findings demonstrate that HB-EGF expression is highly responsive to
neuronal activity/injury consistent with roles in neuronal plasticity
and injury responses.
The HB-EGF mRNA expression that occurred 24-48 hr after kainate
injection in regions of neuronal degeneration (CA1 region of
hippocampus, amygdala, piriform and entorhinal cortices) may represent
expression by reactive astrocytes, activated microglia, or infiltrating
macrophages. Indeed, HB-EGF was originally identified as a
macrophage-derived secretory product (Higashiyama et al., 1991). The
appearance of reactive astrocytes and infiltration of microglia has
previously been connected with kainic acid-induced neuronal damage
(Sperk et al., 1983; Marty et al., 1991; Sperk, 1994). Although
microglia may participate in inflammatory responses and can phagocytose
damaged cells, increasing data suggest that microglia also produce
neurotrophic substances. For example, activated microglia produce both
bFGF and TNF, both of which have been shown to protect neurons
against various insults (Mattson et al., 1989; Cheng and Mattson, 1991;
Cheng et al., 1994). Furthermore, it was recently reported that
microglia express TGF-1 in the hippocampus, particularly in areas
undergoing neurodegeneration after a systemic kainate injection (Morgan
et al., 1993). These findings led to the hypothesis that recruitment of
microglia and secretion of trophic factors may be important for early
repair processes after neuronal injury. Similarly, HB-EGF induction
after kainate-induced seizures may be indicative, in part, of activated microglia or astrocytes that respond to chemotactic factors released by
dying neurons. In this view, the upregulation of HB-EGF is an adaptive
response to neuronal activation and/or damage because induction
continues during the period of neuronal degeneration.
The spatial and temporal increases in HB-EGF mRNA levels raise
interesting questions regarding mechanisms of both gene and protein
regulation. Modulation of HB-EGF mRNA expression was most likely
stimulated by seizure-induced neuronal activity and/or cell death
elicited by the kainate treatment, because rats that did not exhibit
overt convulsive behavior failed to show elevated levels of HB-EGF mRNA
or protein (L. A. Opanashuk and K. B. Seroogy, unpublished
data). Regulation of some neurotrophic factors, for example BDNF, has
previously been tightly linked to an appropriate balance between
activation of GABA and glutamate receptors (Zafra et al., 1991). The
varying kinetics of regional HB-EGF expression are suggestive of
differential mechanisms of gene regulation. In some situations, HB-EGF
has been designated as an immediate early gene (Polihronas et al.,
1996) and might therefore serve functions similar to BDNF (Hughes et
al., 1993; Lauterborn et al., 1996). This may be the case in the
dentate gyrus granule cells because increases in HB-EGF protein were
evident within 3 hr of kainate administration, a time period too short
to permit de novo protein synthesis to take place before
upregulation of the HB-EGF gene. Furthermore, levels of both the
transmembrane and secreted forms of HB-EGF protein were moderately
elevated 3 hr after treatment, suggesting that both transcriptional and post-translational mechanisms may be important in the processing of
HB-EGF protein in the hippocampus. Alternative mechanisms may be
responsible for the more protracted increases in HB-EGF mRNA. For
example, other trophic molecules, peptides, or cytokines may mediate
the induction of HB-EGF mRNA. In support of the latter possibility,
HB-EGF gene expression was previously shown to be autoregulated
(Barnard et al., 1994) and was also upregulated in response to TNF,
thrombin, and TGF (Yoshizumi et al., 1992; Tan et al., 1994; Dlugosz
et al., 1995). Regardless of the mechanisms involved, it still remains
to be determined whether increases in HB-EGF mRNA are the result of
increased gene transcription rates or message stabilization.
Several findings in the present study suggest that HB-EGF serves an
excitoprotective role after seizures. First, levels of HB-EGF mRNA and
protein were increased in hippocampus within 3-6 hr of kainate
administration. Second, in situ hybridization analysis showed that HB-EGF was increased in cells in the CA3 and CA1 pyramidal cell layers, cells susceptible to excitotoxic injury. Third, HB-EGF protected cultured hippocampal neurons against kainate toxicity. Collectively, these findings are analogous to previous studies demonstrating that neurotrophic factors induced by insults that include
an excitotoxic component (e.g., ischemia) can protect neurons against
excitotoxicity (for review, see Mattson, 1996). For example, bFGF, NGF,
BDNF, platelet-derived growth factor, and TNF are induced by
seizures and other insults (Gall and Isackson, 1989; Gall et al., 1991,
1994; Isackson et al., 1991; Dugich-Djordjevic et al., 1992;
Rocamora et al., 1992; Iihara et al., 1994; Lauterborn et al.,
1994; Riva et al., 1994; Bruce et al., 1996); each factor can protect
cultured hippocampal neurons against excitotoxic and metabolic insults
(Mattson et al., 1989; Cheng and Mattson, 1991, 1994, 1995; Cheng et
al., 1994). Administration of bFGF (Nozaki et al., 1993), GDNF
(Martin et al., 1995), NGF (Shigeno et al., 1991), or BDNF (Beck
et al., 1994) into the brains of rodents protects neurons against
excitotoxic and/or ischemic injury, demonstrating their
anti-excitotoxic activities in vivo. Although it remains to
be established whether HB-EGF exhibits neuroprotective actions in
vivo, its increased expression in response to seizures and its
ability to protect cultured neurons against kainate toxicity are
consistent with this possibility.
Our cell survival and calcium imaging analyses, in cultured hippocampal
neurons exposed to kainate, suggest both similarities and differences
in the excitoprotective actions of HB-EGF and other previously
characterized neurotrophic factors. Pretreatment for 16 hr with HB-EGF
was required for protection against kainate toxicity; shorter
pretreatments (2-6 hr) were ineffective. This requirement for
pretreatment is similar to bFGF (Mattson et al., 1989), BDNF (Cheng and
Mattson, 1994), and TNF (Cheng et al., 1994), which appear to act by
altering gene expression. In particular, the neuroprotective mechanisms
of bFGF, BDNF, and TNF appear to involve modulation of the
expression of gene products involved in regulation of calcium
homeostasis and/or free radical metabolism (Cheng et al., 1994; Mattson
et al., 1995). We reported previously that pretreatment of cultured
hippocampal neurons with bFGF results in differential modulation of
calcium responses to activation of NMDA and AMPA/kainate receptors such
that NMDA responses are reduced and AMPA/kainate responses enhanced
(Cheng et al., 1995). In the present study we found that calcium
responses to kainate were neither suppressed nor enhanced in
hippocampal neurons pretreated for 16 hr with HB-EGF. Although
considerable further work will be required to establish the
excitoprotective mechanism of action of HB-EGF, it appears not to
result simply from a suppression of kainate-induced elevation of
[Ca2+]i. Another possible mechanism
whereby HB-EGF might protect neurons is by suppressing accumulation of
reactive oxygen species. Indeed, it was reported recently that EGF can
prevent oxidative stress-induced cell death in cultured cortical
neurons (Yamada et al., 1995).
In addition to the potential roles of HB-EGF in seizure responses, the
normal postnatal expression of HB-EGF in rat forebrain, and in the
cortex in particular, suggests possible roles for this factor in
modulating processes such as cell survival, neurite outgrowth, and
synaptogenesis. Levels of HB-EGF mRNA were maximal during the early
postnatal period, a time during which synaptogenesis is occurring.
Previous studies have shown that EGF promotes both cell survival and
neurite outgrowth of cultured neocortical neurons (Morrison et al.,
1987, 1988; Kornblum et al., 1990). Considering that levels of EGF mRNA
and protein are relatively low in cortex during the early postnatal
period (Fallon et al., 1984; Kudlow et al., 1989; Lazar and Blum,
1992), and that HB-EGF activates the EGF receptor [which is present at
high levels during early brain development (Seroogy et al., 1994, 1995;
Kornblum et al., 1997a)], it would not be unlikely that endogenous
HB-EGF could regulate neurite outgrowth and synaptogenesis in
vivo. Trophic actions on both neurons and glia are also suggested
by preliminary in vitro data showing that HB-EGF induces the
proliferation of astrocytes and pluripotent precursor cells and
increases the survival of neurons derived from the cortex of perinatal
rodents (Kornblum et al., 1997b) and induces the tyrosine
phosphorylation of EGF-R in primary cultures of rat cerebral astrocytes
(Elenius et al., 1997).
Consistent with a role for HB-EGF as a developmental and/or maintenance
factor, EGF-R has been detected in both neonatal and adult hippocampus
and neocortex (Gomez-Pinilla et al., 1988; Faundez et al., 1992; Tucker
et al., 1993; Okano et al., 1996; Seroogy, unpublished data).
Expression of HB-EGF persists in the rat neocortex, albeit at
relatively low levels, and in hippocampal dentate gyrus in the adult
brain. Because of the comparatively low levels of EGF in the adult
brain, our data suggest important roles for HB-EGF in both the normal
and injured adult CNS. It should be noted that in contrast to our data,
Mishima et al. (1996) recently reported widespread expression of HB-EGF
in most neuronal and glial cells throughout the normal adult rat brain.
Our data strongly suggest a more restricted expression of HB-EGF in
adult brain consistent with actions on a more limited set of neural populations.
Although little is known about the function of HB-EGF in the CNS,
findings in this study implicate various potential roles for HB-EGF in
response to limbic seizure activity. Considering that HB-EGF expression
has been closely associated with wound healing and tissue repair in
many tissues (Marikovsky et al., 1993), it could be predicted that this
trophic molecule participates in similar responses in the injured
nervous system. Overall, the present findings suggest that HB-EGF
serves as an injury-inducible maintenance/neuroprotective factor
involved in early cellular responses and tissue remodeling events
associated with seizures in the mammalian CNS.
| |
FOOTNOTES |
Received June 9, 1998; revised Oct. 9, 1998; accepted Oct. 12, 1998.
This research was supported by grants from National Institutes of
Health (NS35164) and the University of Kentucky Medical Center Research
Fund to K.B.S. and from National Institutes of Health (NS29001,
AG05119, and NS35253) to M.P.M. L.A.O. was supported by National
Institutes of Health postdoctoral fellowship NS10007. We thank Kerstin
Lundgren for expert technical assistance and Dr. James Herman for
helpful discussions and assistance with statistical analyses during the
preparation of this manuscript.
Correspondence should be addressed to Dr. Kim B. Seroogy, Department of
Anatomy and Neurobiology, University of Kentucky, 800 Rose Street,
Lexington, KY 40536.
Dr. Mark's present address: Lilly Research Laboratories, CNS
Research, Lilly Corporate Center, Indianapolis, IN 46285.
| |
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Abstract
Introduction
