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The Journal of Neuroscience, October 1, 1998, 18(19):7768-7778
Increased Neurogenesis in the Dentate Gyrus After Transient
Global Ischemia in Gerbils
Jialing
Liu1,
Karen
Solway1,
Robert O.
Messing2, and
Frank R.
Sharp1
1 Departments of Neurology and Neurosurgery, University
of California at San Francisco and San Francisco Veterans Affairs
Medical Center, San Francisco, California 94121, and
2 Department of Neurology, Ernest Gallo Clinic and Research
Center and Graduate Programs in Neuroscience and Biomedical Sciences,
University of California at San Francisco, San Francisco,
California 94110
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ABSTRACT |
Neurogenesis in the dentate gyrus of adult rodents is regulated by
NMDA receptors, adrenal steroids, environmental stimuli, and seizures.
To determine whether ischemia affects neurogenesis, newly divided cells
in the dentate gyrus were examined after transient global ischemia in
adult gerbils. 5-Bromo-2'-deoxyuridine-5'-monophosphate (BrdU)
immunohistochemistry demonstrated a 12-fold increase in cell birth in
the dentate subgranular zone 1-2 weeks after 10 min bilateral common
carotid artery occlusions. Two minutes of ischemia did not
significantly increase BrdU incorporation. Confocal microscopy
demonstrated that BrdU immunoreactive cells in the granule cell layer
colocalized with neuron-specific markers for neuronal nuclear
antigen, microtubule-associated protein-2, and calbindin
D28k, indicating that the newly divided cells
migrated from the subgranular zone into the granule cell layer and
matured into neurons. Newborn cells with a neuronal phenotype were
first seen 26 d after ischemia, survived for at least 7 months,
were located only in the granule cell layer, and comprised ~60% of BrdU-labeled cells in the granule cell layer 6 weeks after ischemia. The increased neurogenesis was not attributable to entorhinal cortical
lesions, because no cell loss was detected in this region. Ischemic
preconditioning for 2 min, which protects CA1 neurons against
subsequent ischemic damage, did not prevent increased neurogenesis in
the granule cell layer after a subsequent severe ischemic challenge.
Thus, ischemia-induced dentate neurogenesis is not attributable to CA1
neuronal loss. Enhanced neurogenesis in the dentate gyrus may be a
compensatory adaptive response to ischemia-associated injury and could
promote functional recovery after ischemic hippocampal injury.
Key words:
neurogenesis; dentate gyrus; granule neuron; cerebral
ischemia; hippocampus; CA1; NMDA receptor; entorhinal cortex; neural
stem cells; BrdU; NeuN; GFAP; MAP-2; calbindin; spreading depression; subependyma; erythropoietin; FGF; BDNF
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INTRODUCTION |
Neural stem cells, with self-renewal
and multilineage potential, have been identified in the embryonic and
adult mammalian brain (Weiss et al., 1996 ; McKay, 1997). Neurogenesis
in the adult mammalian brain is limited to two regions, the dentate
gyrus of the hippocampus and the olfactory bulb (Altman and Das, 1967; Kaplan and Hinds, 1977; Kaplan and Bell, 1983, 1984). The progenitor cells giving rise to new neurons for these areas are located in the
dentate gyrus and subependyma, respectively. Hippocampal progenitor cells from adult rat brain proliferate and differentiate into neurons
and glia in vitro when maintained in medium containing FGF-2
(Gage et al., 1995). Progenitor cells that are grafted into the adult
brain develop into mature neurons, with morphological and biochemical
features characteristic of the surrounding neurons. This suggests that
CNS stem cells are capable of responding to environmental cues in the
adult host (Suhonen et al., 1996). The ability of neural stem cells to
integrate into various brain regions offers hope for the development of
restorative therapies for ischemic, traumatic, and degenerative brain
diseases. Understanding factors that control stem cell growth and
regional differentiation will help achieve such a goal. Grafts of fetal
CNS tissue that include CA1 hippocampal cells reverse learning deficits
produced by global ischemic damage to CA1 pyramidal neurons in adult
rats (Hodges et al., 1996). This finding, along with many similar
transplant studies, demonstrates the potential for the anatomical and
functional integration of grafts of specific cell types, even in the
adult nervous system.
Adrenal steroids (Cameron and Gould, 1994) and excitatory amino acids
(Cameron et al., 1995) regulate neurogenesis in the adult dentate gyrus
subgranular zone (SGZ). Adrenalectomy, glutamatergic deafferentation,
and NMDA receptor antagonists increase neurogenesis in the SGZ, whereas
spreading depression (Dziewulska et al., 1996) and adrenal steroids
(Gould et al., 1992, 1997; Cameron and Gould, 1994) decrease
neurogenesis. Seizures increase dentate granule cell neurogenesis in
association with sprouting of mossy fibers into the inner molecular
layer of the dentate gyrus (Parent et al., 1997). The present studies
were undertaken to determine whether global ischemia, which influences
NMDA and other glutamate receptors (Westerberg et al., 1989), also
affects dentate neurogenesis. Using immunohistochemistry to detect the
incorporation of the thymidine analog
5-bromo-2'-deoxyuridine-5'-monophosphate (BrdU) into newly synthesized
DNA, a marked increase in cellular proliferation in the SGZ of the
dentate gyrus was observed 1-2 weeks after global ischemia. The
majority of newborn cells that migrated into the granule cell layer
(GCL) expressed neuronal markers, whereas some of the cells that
migrated from the SGZ into the dentate hilus became astrocytes. The
results indicate that hippocampal progenitor cells give rise to dentate
granule cell neurons and hilar astrocytes in response to ischemic
injury.
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MATERIALS AND METHODS |
Reagents. The following antibodies and final
concentrations were used: mouse anti-BrdU (0.25 µg/ml; Boehringer
Mannheim, Indianapolis, IN); rat anti-BrdU (2 µg/ml; Accurate
Chemicals, Westbury, NY); mouse anti-proliferative cell nuclear antigen
(PCNA) (1 µg/ml; Boehringer Mannheim); mouse anti-neuronal
nuclear antigen (NeuN) (1 µg/ml; Chemicon, Temecula, CA); mouse
anti-microtubule-associated protein 2 (MAP-2) (1 µg/ml; Boehringer
Mannheim); rabbit anti-calbindin-D28k (1:500; SWANT,
Bellinzona, Switzerland); and mouse anti-GFAP (1 µg/ml; Chemicon).
Biotinylated sheep anti-mouse IgG (5 µg/ml; Amersham, Cleveland, OH)
served as the secondary antibody for BrdU and NeuN peroxidase
immunohistochemistry. The avidin-peroxidase complex solution (Vector
laboratories, Burlingame, CA) was used at a dilution of 1:100.
ExtrAvidin-fluorescein 5'-isothiocyanate (FITC) (10 µg/ml; Sigma,
St. Louis, MO), Cy-3-labeled goat anti-mouse IgG (1 µg/ml;
Amersham), and Cy-3-labeled goat anti-rabbit IgG (1 µg/ml; Amersham)
were used as fluorescent labels. Three different antibodies to neuronal
proteins were used because of the concern that ischemia might induce
neuronal proteins in non-neuronal cells (Toyoshima et al., 1996).
Transient global ischemia. Adult male Mongolian gerbils
(11-13 weeks of age; Simmonson, Gilroy, CA) were used for these
studies. The animals were anesthetized with 3% isoflurane in 20%
O2-77% N2. After bilateral neck incisions,
both common carotid arteries (CCAs) were exposed and occluded with
aneurysm clips for 2-10 min. The clips were then removed to restore
cerebral blood flow. The rectal temperature was maintained at 37° ± 0.5°C with a heating blanket until the animals recovered from
surgery. After recovery, the animals were monitored for an additional 2 hr to prevent hypothermia. Sham-operated animals were treated
identically, except that the CCAs were not occluded after the neck
incisions. A separate group of gerbils was anesthetized and underwent
ischemic preconditioning produced by bilateral occlusion of the CCAs
for 2 min (Kirino et al., 1991; Kitagawa et al., 1991; Liu et al.,
1997). Three days later, these animals were reanesthetized, and both
CCAs were occluded for 5 min.
BrdU labeling. The thymidine analog BrdU was administered
intraperitoneally (50 mg/kg; Sigma, St. Louis, MO). Two injection paradigms were used. In some experiments (see Figs. 1, 2, 6), we gave a
single dose of BrdU and killed the animals the next day. This
allowed us to measure the number of cells that incorporated BrdU during
a 24 hr period and provided an index of the rate of cell birth at a
specific time point after ischemia. In other experiments (see Figs. 3,
4; Table 1), we gave injections of BrdU (50 mg/kg) twice daily for 4 consecutive days during the peak of cell proliferation 9-12 d after
ischemia. This allowed us to investigate the phenotype, survival, and
migration pattern of newborn cells.
Tissue preparation and immunohistochemistry. Animals were
anesthetized with ketamine (80 mg/kg; Parke-Davis, Morris Plains, NJ)
and xylazine (20 mg/kg; Butler, Columbus, OH). They were perfused transcardially with 0.9% saline, followed by 4% paraformaldehyde (PFA) in 0.1 M phosphate buffer, pH 7.4 (PB). The brains
were removed, post-fixed for 6 hr in 4% PFA-PB, and placed in 40%
sucrose overnight. Fifty micrometer coronal sections were cut on a
vibratome and stored in PB. Representative sections were placed on
gelatin-coated slides and stained with cresyl violet.
For immunocytochemical detection of BrdU-labeled nuclei, DNA was
denatured to expose the antigen. Before incubation in anti-BrdU primary
antibody, free-floating brain sections were pretreated in 50%
formamide-2× SSC at 65°C for 2 hr and then incubated at 37°C for
30 min in 2N HCl. Finally, sections were rinsed for 10 min at 25°C in
0.1 M boric acid, pH 8.5. Sections were then incubated overnight at 25°C in primary antibody diluted in PB with 1% sheep serum, 0.1% bovine serum albumin, and 0.3% Triton X-100. After being washed in PB, sections were incubated in biotinylated secondary antibody for 2 hr at 25°C. After three 5 min rinses in PB, sections were placed in avidin-peroxidase complex solution containing
avidin-peroxidase conjugate for 2 hr. After two more 5 min washes,
sections were incubated for 2 min in a peroxidase reaction solution
(0.25 mg/ml diaminobenzidine, 0.01%
H2O2, and 0.04%
NiCl2). Peroxidase staining was examined using a
Leitz (Wetzlar, Germany) Orthoplan microscope.
Immunofluorescence. Sections were incubated overnight with
rat anti-BrdU and then for 2 hr in biotinylated sheep anti-rat antibody. Sections were then incubated with ExtrAvidin-FITC conjugate for 2 hr. After two 5 min PB washes, they were incubated with mouse
anti-NeuN, mouse anti-MAP-2, rabbit anti-calbindin, or mouse anti-GFAP
antibodies overnight. This was followed by incubation for 2 hr with
Cy-3-labeled goat anti-mouse or goat anti-rabbit secondary antibodies.
Sections were washed in PB and then mounted with coverslips on glass
slides. Fluorescence was detected using a Bio-Rad (Richmond, CA) MRC
1024 confocal imaging system equipped with a krypton-argon laser and a
Nikon Diaphot microscope. Images (512 × 512 pixels) were obtained
by averaging six scans and were processed by Adobe Photoshop (Adobe
Systems, Mountain View, CA).
Cell counting. The number of BrdU immunoreactive nuclei in
the SGZ was counted in five to seven coronal hippocampal sections (50 µm) per animal. The sections were spaced 200 µm apart and spanned
the septal (dorsal) hippocampus. Each microscope image was digitized.
BrdU immunoreactive nuclei were counted on a computer monitor to
improve visualization and in one focal plane to avoid over-sampling.
The area of the dentate gyrus, including the hilus, SGZ, and inner
third of the GCL, was measured on each section using a computer-based
microcomputer imaging device imaging system (Imaging Research, Inc.,
Ontario, Canada). The density of BrdU immunoreactive cells in each
section was calculated by dividing the number of BrdU-positive nuclei
by the area of the dentate gyrus. Density for the five to seven
sections were averaged to obtain a mean density value for each animal.
Differences between mean values for each treatment group were analyzed
using the Kruskal-Wallis ANOVA on ranks, followed by post
hoc tests using Dunn's method (SigmaStat; Jandel Scientific, San
Rafael, CA). Differences were considered significant when
p < 0.05.
Colocalization of NeuN or GFAP immunoreactivity with BrdU
immunoreactivity was examined in the GCL, SGZ, and dentate hilus. The
number of BrdU immunoreactive cells in each region was counted using a
fluorescent microscope. To obtain the proportion of BrdU-labeled cells
that were neurons or astrocytes, we used confocal microscopy to detect
the percentage of BrdU-labeled cells immunoreactive for NeuN or GFAP.
This was done by examining cells in 7-10 random fields within each
brain region per animal. Estimates of the numbers of neurons and
astrocytes were calculated by multiplying these percentages by the
total number of BrdU-labeled cells in each region (see Table 1).
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RESULTS |
Upregulation of cell proliferation in the dentate gyrus after
global ischemia
There was a basal level of BrdU incorporation into cells in the
SGZ of control animals 24 hr after labeling (Fig.
1A). This is an area in
which neurogenesis normally persists in adult animals (Kaplan and
Hinds, 1977; Stanfield and Trice, 1987; Cameron et al., 1993).
BrdU-labeled nuclei in the SGZ of both control and ischemic brains
appeared as irregularly shaped clusters located exclusively in the SGZ
(Fig. 1). This pattern is characteristic of dentate gyrus progenitor
cells (Cameron et al., 1995; Gould et al., 1997). The number of
BrdU-labeled cells was not changed by sham operation or 2 min of global
ischemia (Fig. 2B),
demonstrating that the stress of surgery did not increase cell
proliferation.
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Figure 1.
Ischemia increases cell proliferation in the
dentate gyrus of adult gerbils. Animals were subjected to 10 min of
global ischemia. BrdU was administered 1 d before the animal was
killed, and brains were processed for BrdU immunohistochemistry.
A, Control untreated gerbil. B-F,
Ischemic gerbils killed 8 d (B), 2 weeks
(C), 3 weeks (D), 4 weeks
(E), or 5 weeks (F) after
ischemia. Scale bar, 250 µm.
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Figure 2.
Time course of cell proliferation after global
ischemia and effect of ischemia duration on proliferation in the SGZ.
In both sets of experiments, BrdU was administered 24 hr before the
animal was killed. A, The number of BrdU immunoreactive
nuclei in the SGZ of animals killed 6 d (n = 12), 9 d (n = 8), 11 d
(n = 7), 2 weeks (n = 6), 3 weeks (n = 7), 4 weeks (n = 8),
or 5 weeks (n = 6) after 10 min of global ischemia
( ). Control animals (n = 10) were untreated
( ). B, BrdU-positive nuclei in the SGZ of animals
killed 8 d after 2 (n = 8), 3 (n = 6), 4 (n = 6), 5 (n = 6), or 10 (n = 8) min of
ischemia. Data are mean ± SEM. Error bars are omitted where they
extend beyond the symbols. *p < 0.05 compared with
control.
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BrdU incorporation did not significantly increase during the first
6 d after global ischemia (Fig. 2A). Thereafter,
cell proliferation increased markedly and was maximal 11 d after
ischemia, with a 12-fold increase in BrdU immunoreactive nuclei per
square millimeter dentate gyrus compared with control animals. Cell
proliferation decreased by 14 d after ischemia but was still
greater than control (Figs. 1C, 2A).
Although the number of dividing cells appeared to return to control
levels in most animals 3-5 weeks after ischemia (Fig.
2A), a few animals continued to demonstrate increased
cell birth at these times (Fig.
1D,E).
To examine the relationship between the duration of ischemia and cell
proliferation, gerbils were subjected to global ischemia for 2-10 min
and allowed to recover. They were injected with BrdU (50 mg/kg) 8 d later and killed the next day (Fig. 2B). There was
no increase in the number of labeled cells after 2 min of ischemia.
However, there was a steep rise in the number of BrdU immunoreactive
cells, as the duration of ischemia increased to 4 min. When ischemia
was prolonged to 10 min, there was only a slight increase in the number
of BrdU-labeled cells compared with 4 min (Fig.
2B).
Ischemia-induced neurogenesis in the dentate gyrus
To determine whether proliferating cells in the SGZ became
neurons, we examined hippocampal sections from animals killed 15-40 d
after a single 10 min episode of ischemia (Fig.
3, Table
1). For these studies, animals received
multiple BrdU (50 mg/kg) injections 9-12 d after ischemia to maximally
label proliferating cells (Fig. 2A). Fifteen days
after ischemia, labeled cells did not express neuronal or astrocyte
markers (Table 1). However, 26 d after ischemia, 27% of the BrdU
immunoreactive cells in the GCL and SGZ expressed NeuN (Table 1). The
percentage of NeuN-expressing BrdU immunoreactive cells (Fig.
3B) increased to 61% (Table 1) 40 d after ischemia. At
this time, the majority of the BrdU-labeled nuclei in the GCL
colocalized with calbindin-D28k (Fig. 3A), NeuN (Fig. 3B), and MAP-2 (Fig. 3C) immunoreactive
cells. Some BrdU-labeled cells did not express these neuronal markers
(Fig. 3A, arrowhead). A similar increase in the
percentage of BrdU-labeled cells expressing NeuN was observed in
control animals over time (Table 1).
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Figure 3.
Neuronal identity of newly divided cells in the
dentate gyrus after global ischemia. BrdU was administered twice daily
9-12 d after 10 min of global ischemia. Gerbils were killed 4 weeks
later, and brain sections were stained for BrdU immunoreactivity
(green) and cell-specific markers
(red). A, B,
Colocalization of BrdU with calbindin-D28k
(CalB) or NeuN is shown by yellow nuclei.
C, Colocalization of BrdU with MAP-2 is shown in cells
with red cytoplasm surrounding green
nuclei. D, No colocalization of GFAP and BrdU was
observed within the GCL. Scale bar, 10 µm.
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Table 1.
Quantitative analysis of BrdU immunoreactive cells and
their phenotypes in subregions of the dentate gyrus after BrdU
labelinga
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The location of BrdU-labeled cells changed over time. Fifteen days
after global ischemia, most labeled cells were located in the SGZ (Fig.
4A). Twenty-six days
after ischemia, some of the cells were still in the SGZ, but many were
found throughout the GCL (Fig. 4B). Forty (Fig.
4C) and 96 (Fig. 4D) d after ischemia, large numbers of newborn cells were found throughout the dentate GCL.
Many of these cells survived for at least 7 months after ischemia (data
not shown).
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Figure 4.
Distribution and morphology of BrdU-labeled cells
after global ischemia. BrdU was given twice daily 9-12 d after
ischemia. Animals were then killed 15 (A,
F), 26 (B, G), 40 (C, H), or 96 (D,
I) d after ischemia. The sham-operated gerbil was
killed 40 d (E, J) after
surgery. F-J, High-magnification view. Scale bars (in
E and F): A-E, 250 µm; F-J, 25 µm.
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There was also a marked change in the morphology of BrdU-labeled nuclei
in the dentate gyrus in the weeks after ischemia. By the fifteenth day,
most nuclei in the SGZ and the edge of the GCL were elongated in shape
(Fig. 4F). Forty days after ischemia, most
BrdU-labeled nuclei appeared round like those of surrounding granule
neurons (Fig. 4H). The intensity of BrdU labeling was less in some cells (Fig. 3A, arrows), suggesting
that they were derived from labeled precursors that had undergone
several divisions, resulting in dilution of BrdU-labeled DNA.
Unlike the dentate gyrus of animals subjected to pilocarpine-induced
seizures (Parent et al., 1997) and humans with epileptic damage
(Houser, 1990), there was no granule cell dispersion or ectopic granule
cell migration after ischemic injury. Some BrdU-labeled cells that
migrated a short distance into the dentate molecular layer (Fig.
4I, arrows) expressed NeuN (data not
shown). However, NeuN-positive neuronal nuclei were also observed short
distances from the GCL in control animals (Fig.
5B).
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Figure 5.
Lack of neuronal loss in the entorhinal cortex
after 10 min of global ischemia. A-C, Neuronal cells
detected in untreated control gerbils by NeuN immunohistochemistry in
striatum (A), hippocampus
(B), and entorhinal cortex
(C). D-F, Animals subjected to 10 min of ischemia and then examined for NeuN immunoreactivity in striatum
(D), hippocampus (E), and
entorhinal cortex (F) 8 d later. Scale bars:
(in D) A, D, 1 mm; (in
E) B, E, 200 µm; (in
F) C, F, 200 µm.
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Dentate gyrus progenitor cells give rise to astrocytes in
the hilus
An increasing number of BrdU-labeled cells also appeared in the
dentate hilus in the weeks after ischemia. Approximately 30% of cells
derived from dentate progenitor cells survived and migrated into the
dentate hilus by 26 d after ischemia (Table 1). Among the
BrdU-labeled population in the hilus, ~25% expressed GFAP 40 d
after ischemia. No BrdU-labeled cells in the dentate hilus expressed
NeuN at any time point examined.
Neuronal loss in the entorhinal cortex or CA1 is not required for
dentate neurogenesis after ischemia
Specific neurons of the entorhinal cortex project to the dentate
gyrus (Steward, 1976; Bartesaghi et al., 1995; Deller et al., 1996).
Lesions of entorhinal cortex, which remove afferent input to granule
neurons, increase neurogenesis in the dentate gyrus (Cameron et al.,
1995). To determine whether ischemia-induced hippocampal neurogenesis
was associated with injury to entorhinal cortex, we examined brain
sections using NeuN immunohistochemistry, cresyl violet staining, and
terminal deoxynucleotidyl transferase-mediated biotinylated UTP nick
end labeling (TUNEL). There was extensive neuronal loss in the lateral
striatum (Fig. 5D) and in the CA1 sector of the hippocampus
(Fig. 5E) after 10 min of global ischemia. There was also
neuronal loss in neocortical layers II-V in most ischemic animals (data
not shown). However, there was no cell loss in the entorhinal cortex of
ischemic (Fig. 5F) compared with control (Fig.
5C) brains. In addition, there were no TUNEL-labeled or
darkly stained pyknotic cells in the entorhinal cortex 1-5 d after
global ischemia (data not shown). These results indicate that
entorhinal cell death is not associated with 10 min of global ischemia
and is unlikely to be the cause of ischemia-induced neurogenesis in the
gerbil hippocampus.
Because ischemia caused loss of CA1 neurons (Fig. 5E), we
considered whether increased dentate neurogenesis was attributable to
this. Therefore, cell proliferation was studied in a model of ischemic
tolerance. Five minutes of global ischemia alone produced marked CA1
neuronal loss (Fig. 6C). When
animals were preconditioned with 2 min of global ischemia and then
subjected to 5 min of global ischemia 3 d later, ~50% of the
animals appeared to have no CA1 neuronal loss (Fig.
6D). This agrees with other studies (Kirino et al.,
1991; Kitagawa et al., 1991; Liu et al., 1997). However, there was
still a marked increase in neurogenesis in the dentate gyrus of the
preconditioned animals that did not show CA1 loss (Fig.
6E). In contrast, 2 min of ischemia alone did not
significantly increase proliferation of dentate progenitor cells (Fig.
6E). These results indicate that neurogenesis in the
dentate gyrus is not reduced by ischemic preconditioning and does not
require CA1 neuronal loss.
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Figure 6.
Ischemia increases dentate neurogenesis in
ischemic-tolerant animals. Animals received 2 (B)
or 5 (C) min of global ischemia or 2 min of
ischemic preconditioning followed by 5 min of global ischemia
(D) compared with untreated control
(A). Hippocampal sections were obtained 8 d
after the sham operation or the last ischemic insult and analyzed by
NeuN immunohistochemistry. Approximately 50% of the preconditioned
gerbils showed intact CA1 morphology. Only these animals that lacked
CA1 damage were analyzed for dentate neurogenesis. Scale bar, 200 µm.
E, Animals were subjected to 2 (n = 8) or 5 (n = 6) min of ischemia. The
Tolerant group of animals was subjected to 2 min of
ischemic preconditioning, followed by 5 min of ischemia 3 d later
(n = 9). BrdU was given 8 d after ischemia,
and the animals were killed 1 d later. BrdU was given 24 hr before
the control animal was killed (Control)
(n = 10). Data shown are mean ± SE.
*p < 0.05 compared with control.
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DISCUSSION |
This study provides the first evidence for increased birth of
dentate progenitor cells after global ischemia in an adult rodent. Most
of these precursor cells migrated out into the GCL from the SGZ,
developed into mature neurons, and appeared to integrate into the
dentate GCL. Because most BrdU-positive cells did not express NeuN
within the first week after BrdU pulse labeling, these cells appear to
have required several days to become mature neurons. This delay in
maturation contrasts with the more rapid development of ventral horn
motor neurons and cerebellar granule cells, which express high levels
of NeuN immediately after terminal division of progenitor cells (Mullen
et al., 1992).
Within the dentate gyrus, most progenitor cells appeared to
differentiate into neurons expressing the neuronal markers NeuN, calbindin-D28k (Sloviter et al., 1989), and MAP-2
(Bernhardt and Matus, 1984). The percentage of BrdU immunoreactive
cells in the GCL expressing mature neuronal markers increased to >60%
during the first month after BrdU labeling in both control and ischemic animals. This is consistent with the observation of Cameron et al.
(1993), who found that the percentage of
[3H]thymidine-labeled cells in the GCL that
expressed neuron-specific enolase increased to 70% over 3 weeks after
[3H]thymidine injection. After ischemia, however,
not all BrdU progenitors became neurons. A subpopulation of newly
divided cells migrated into dentate hilus and became astrocytes. This
may have occurred because different environmental cues present in the
dentate gyrus and dentate hilus influenced the developmental fate of
CNS progenitors.
A substantial number of BrdU-labeled cells in the dentate gyrus and
dentate hilus did not express neuronal or astrocytic markers after
ischemia. Many of these cells may have been undifferentiated because of
high rates of proliferation in some subsets of progenitor cells.
This is supported by the punctate appearance of BrdU labeling in many
cells (Fig. 3A, arrows), suggesting that the
label had been diluted by several cycles of cell division.
Alternatively, some of these cells may have been oligodendrocytes or
microglia that were not detected by antibodies against neuronal or
astrocytic markers.
In addition to the SGZ, cell proliferation occurs in other parts of
hippocampus after ischemia. Previously, we have observed numerous
BrdU-labeled cells in the stratum radiatum, molecular layer, and
hilus of the dentate gyrus (Liu et al., 1997) in ischemic gerbils.
However, these cells are mostly lectin-positive, suggesting that they
are dividing microglia.
BrdU is generally used as a marker for new DNA synthesis (Gage et al.,
1995). It is unlikely that cells with DNA strand breaks incorporate
enough BrdU to be detected by immunohistochemistry. TUNEL, which
detects DNA nicks and strand breaks that indicate DNA damage, labels
primarily CA1 neurons and not dentate granule cells after 5-10 min of
global ischemia in gerbils (Honkaniemi et al., 1996). This pattern of
labeling is dramatically different from the pattern observed with BrdU,
which primarily labeled cells in the dentate rather than CA1 1 week
after ischemia. To confirm that BrdU labeling reflected an increase in
cell birth, we also performed experiments using an antibody that
recognizes PCNA, which is expressed during cell division. Because this
antibody does not recognize PCNA in gerbils, we used mice for these
studies. Similar to what we observed for BrdU labeling in gerbils,
ischemic mice demonstrated increased numbers of PCNA immunoreactive
nuclei in the SGZ after 10 min of global ischemia.
Possible mechanisms for ischemia-induced neurogenesis in
the dentate gyrus
Neurogenesis in the developing and adult dentate gyrus is
regulated, at least in part, by NMDA receptors (Cameron et al., 1995;
Gould et al., 1994, 1997). Blockade of NMDA receptors increases the
birth rate in the dentate gyrus, even on postnatal day 5 when developmental neurogenesis is at its peak (Cameron and Gould, 1994;
Gould et al., 1994). Thus, it is possible that death of glutamatergic
neurons that project to progenitor cells induces neurogenesis. In
support of this possibility is the observation that removal of
excitatory input to granule cells by entorhinal cortical lesions
(Cameron et al., 1995; Gould et al., 1997) increases neurogenesis in
the dentate gyrus. However, we did not detect neuronal death in the
entorhinal cortex after 10 min of ischemia. This suggests that loss of
glutamatergic cells that give rise to the perforant pathway is not
responsible for increased neurogenesis in the dentate gyrus after
ischemia.
Changes in NMDA receptors may also mediate ischemia-induced
neurogenesis. In rats, there is a 20% reduction in NMDA receptor binding in the dentate gyrus 1 week after transient forebrain ischemia,
and 1 week later, NMDA receptor binding returns to control levels
(Westerberg et al., 1989; Ogawa et al., 1991). We observed that
ischemia-induced neurogenesis in gerbils reached a maximum 9-11 d
after ischemia (Fig. 2A) and declined toward control
levels 3 d later. The similarity of these time courses raises the
possibility that ischemia-induced decreases in NMDA receptor signaling
contribute to neurogenesis in the dentate gyrus. Further studies will
be needed to determine whether decreases in NMDA receptor density or
function contribute to ischemia-induced neurogenesis in the dentate
gyrus.
It is possible that neuronal death within the hippocampus provided a
stimulus for increased neurogenesis after ischemia. For example, limbic
seizures that cause apoptosis of granule cells (Bengzon et al., 1997)
increase dentate neurogenesis (Parent et al., 1997). In addition,
excitotoxic and mechanical lesions of the GCL also induce proliferation
of neuronal progenitors in the dentate gyrus of the adult rats (Gould
and Tanapat, 1997). Granule cell apoptosis was observed by some
researchers after forebrain ischemia in the rat (Li et al., 1997).
Ischemic loss of CA1 neurons might also be a factor, but because
dentate neurogenesis was increased in ischemia-tolerant animals
in the absence of CA1 cell death, it appears that loss of CA1 pyramidal
neurons is not required for dentate neurogenesis. Ischemia also
increases the number of TUNEL-labeled cells in the dentate hilus
(Johansen et al., 1987; Hsu and Buzsaki, 1993; Honkaniemi et al., 1996;
Bering et al., 1997) and causes death of dentate hilar interneurons
(Sugimoto et al., 1993; Mody et al., 1995). However, this is apparent
after only 2 min of ischemia (Sugimoto et al., 1993), which is not long enough to stimulate dentate neurogenesis (Fig. 2B).
Thus, although death of hilar interneurons may contribute to dentate
neurogenesis, it clearly is not sufficient to be the sole cause.
Growth and mitogenic factors could play a role in dentate neurogenesis
after ischemia. BDNF and FGF increase the growth and differentiation of
dentate granule neurons in culture (Lowenstein and Arsenault, 1996).
Basic FGF immunoreactivity increases in hippocampal glial cells
7 d after ischemia (Endoh et al., 1994). Basic FGF
immunoreactivity is also increased in astrocytes in the dentate gyrus
after entorhinal lesions (Gomez-Pinilla et al., 1992), which can induce
neurogenesis. In addition, FGF receptors are induced in the dentate
gyrus after pilocarpine-induced seizures (Gomez-Pinilla et al., 1995),
which can upregulate dentate neurogenesis (Parent et al., 1997). Last,
hypoxia and erythropoietin stimulate CNS stem cell proliferation in
culture (Sorokan and Weiss, 1997). Cerebral hypoxia that accompanies
ischemia could induce the expression of erythropoietin in astrocytes
(Semenza and Wang, 1992), resulting in erythropoietin-mediated
increases in neurogenesis in the dentate gyrus. Hence, ischemia-induced
changes in FGF, FGF receptors, and other growth factors and their
receptors could stimulate increased cell birth observed after
ischemia.
Functional consequences of increased dentate neurogenesis
after global ischemia
Neurogenesis has been described in the brains of several adult
mammals, including rats and monkeys (Altman and Das, 1967; Bayer et
al., 1982; Eckenhoff and Rakic, 1988; Cameron et al., 1993, 1995; Kuhn
et al., 1996; Gould et al., 1997). There appears to be neurogenesis in
adult human brain, as well (Kirschenbaum et al., 1994). Increased
neurogenesis in the dentate gyrus after ischemia could increase the
number of granule neurons. There is a substantial increase in the
number of dentate granule cells as rodents develop from newborn to
adult (Bayer et al., 1982). The NMDA receptor antagonist CGP37849
increases the rate of cell birth in SGZ and the number of granule
neurons, without affecting the rate of cell death (Cameron et al.,
1995). Mice living in an enriched environment demonstrate increased
neurogenesis and have more granule neurons in the dentate gyrus, which
correlates with improved learning (Kempermann et al., 1997). In this
study, global ischemia increased the birth rate of neural cells with a
long survival time in dentate gyrus. This could have resulted in
increased numbers of dentate granule cells, at least over the short
term. Further quantitative studies will be required to determine whether dentate cell number increases after global ischemia.
The hippocampus plays a pivotal role in learning and memory (Milner et
al., 1998). Animals and humans demonstrate memory impairment after
ischemic injury to the hippocampus (Zola-Morgan et al., 1992; Squire
and Zola-Morgan, 1996). Because cell transplants can reduce
memory deficits caused by ischemic hippocampal injury (Hodges et al.,
1997; Sinden et al., 1997), it is possible that increased neurogenesis
after global ischemia contributes to memory improvement in patients
recovering from cerebral ischemia. Newly formed granule cell neurons
could extend axons (Stanfield and Trice, 1987), form new synapses on
CA3 neuronal targets, and promote recovery of hippocampal function.
Long-term studies will be needed to determine whether newly generated
neurons form appropriate synapses and if this correlates with
improvement function after ischemic damage to the
hippocampus.
| |
FOOTNOTES |
Received May 29, 1998; revised July 22, 1998; accepted July 23, 1998.
This work was supported by National Institutes of Health Grants
R01 NS28167, NS14543, and HL53040 (F.R.S.). We thank Drs. Jack
Parent and Steve Massa for their suggestions and comments and Dr.
Holger Wille and Mr. Ed Caballero for assistance with the
photography.
Correspondence should be addressed to Dr. Jialing Liu, Departments of
Neurology and Neurosurgery (V127), University of California at San
Francisco and Department of Veterans Affairs Medical Center, 4150 Clement Street, San Francisco, CA 94121.
| |
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Top
Abstract
Introduction
