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The Journal of Neuroscience, April 1, 2000, 20(7):2618-2625
Emx2 Is Required for Growth of the Hippocampus But
Not for Hippocampal Field Specification
Shubha
Tole1,
Guy
Goudreau2,
Stavroula
Assimacopoulos1, and
Elizabeth A.
Grove1
1 Department of Neurobiology, Pharmacology, and
Physiology, University of Chicago, Chicago, Illinois 60637, and
2 Max Planck Institute of Biophysical Chemistry, D-37077
Goettingen, Germany
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ABSTRACT |
The vertebrate Emx genes are expressed in a nested
pattern in early embryonic cerebral cortex, such that a medial strip of cortex expresses Emx2 but not Emx1. This
pattern suggests that Emx genes could play a role in
specifying different areas or fields of the cortex along the
mediolateral axis. Such a role has been supported by the observation
that in mice lacking functional Emx2 the hippocampus is
shrunken and the most medial field of the cortex, the hippocampal
dentate gyrus, appears by cytoarchitecture to be missing
(Pellegrini et al., 1996 ; Yoshida et al., 1997). Use of
region-specific molecular markers shows, however, that hippocampal fields are specified and correctly positioned in the
Emx2 mutant. In particular, a dentate cell population is
generated, although it fails to form a morphological gyrus. This
failure may be part of a more widespread medial cortical defect in the
mutant. Examination of cortical cell proliferation and differentiation
indicates a disruption of the maturation of the medial cortex in the
absence of Emx2. Thus, Emx2 is required
for normal growth and maturation of the hippocampus but not for the
specification of cells to particular hippocampal field identities.
Key words:
Emx2; hippocampus; patterning; specification; cortical maturation; cortical hem
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INTRODUCTION |
The hippocampus, like the rest of
the cerebral cortex, is divided into cytoarchitectonic areas or fields
(Nauta and Feirtag, 1986). Both classic neuronal birth-dating and
migration studies, and more recent studies of region-specific gene
expression, indicate that the hippocampus is patterned into fields
during neurogenesis (Caviness, 1973; Stanfield and Cowan, 1979;
Nowakowski and Rakic, 1981; Rakic and Nowakowski, 1981; Tole et al.,
1997; Tole and Grove, 1998). However, little is known about the
molecular mechanisms that initiate this patterning. It is therefore
intriguing that the homeobox genes Emx1 and Emx2 are
expressed in a nested pattern in the embryonic cortex, so that a medial
strip of cortex is defined by expression of Emx2 but not
Emx1 (Simeone et al., 1992a,b). In the hindbrain,
nested expression of HOX genes reflects a role in
regulating rhombomere identity (Lumsden and Krumlauf, 1996). Nested
expression of Emx genes therefore suggests a function in specifying divisions in medial cortex in which the hippocampus develops. Supporting this hypothesis, in mice lacking functional Emx2 the hippocampus is shrunken and the dentate gyrus
appears by cytoarchitecture to be missing (Pellegrini et al., 1996;
Yoshida et al., 1997). A possible explanation is that nested
Emx gene expression is required to specify the
neuroepithelium that generates the dentate gyrus. In the absence of
Emx2, regional identity is not correctly specified and the
dentate gyrus is lost (Pellegrini et al., 1996; Yoshida et al.,
1997).
Reports that specific mutations lead to morphological defects in the
hippocampus (Xuan et al., 1995; Pellegrini et al., 1996; Porter et al.,
1997; Yoshida et al., 1997) raise a need for molecular markers of
different hippocampal fields. Analysis by cytoarchitecture alone may be
misleading in that the cells that make up a particular field may be
present in a mutant but reduced in number or abnormally organized so
that the field cannot be detected histologically. This distinction is
significant because the complete and selective loss of a field suggests
that the mutated gene is needed to specify cells to a particular field
identity. In contrast, reduction of the size of a field,
particularly in the context of general cortical shrinkage or
dysmorphology, suggests a different role for the gene in question,
perhaps in hippocampal growth or assembly.
Using a panel of region- and field-specific hippocampal molecular
markers, we reanalyzed the Emx2 mutant mouse line described by Pellegrini et al. (1996). Because the hippocampus in the
Emx2 mutant mouse is smaller than in wild-type mice
(Pellegrini et al., 1996; Yoshida et al., 1997), we asked not only
whether dentate gyrus cells are missing, but whether additional fields
are lost. We report that cells are specified to form all the major
hippocampal fields, including a dentate field. Emx2 is thus
not required to specify cells to a dentate field identity but is
required for the formation of a morphological dentate gyrus. Further
observations suggest a general requirement for Emx2 for the
timely growth and maturation of the hippocampus and adjacent medial neocortex.
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MATERIALS AND METHODS |
Emx2 mutant mice were generated and genotyped as
described previously (Pellegrini et al., 1996). In brief, the
Emx2 gene was mutated by homologous recombination to produce
mutant C57BL/J6 mice carrying a null allele. The targeting construct
used was a classical replacement vector designed so that the neomycin
resistance gene replaced the second and part of the third helix of the
Emx2 homeobox domain (for details, see Pellegrini et al.,
1996). Homozygous Emx2 mutant embryos (Emx2
 / mice) and their littermates were
recovered for gene expression analysis at embryonic day 14.5 (E14.5),
E16.5, or E18.5. Additional wild-type mice were harvested at E10.5 and
E12.5 to analyze expression of Emx1 and Emx2.
Midday of the day of vaginal plug discovery was considered E0.5. Birth,
for the mouse strains examined, occurs at approximately E19.5.
Brains were fixed and processed for two-color whole-mount in
situ hybridization, or sectioned and processed for single-color in situ hybridization as described previously (Tole and
Patterson, 1995; Grove et al., 1998). Probes used for in
situ hybridization were specific for Emx1,
Emx2, class III  -tubulin,
TTR, Wnt2b, Wnt3a, SCIP,
KA1, NK3, Ephb1, Steel, and
iGluR7 (Shigemoto et al., 1990; Simeone et al.,
1992b; Tole et al., 1997; Grove et al., 1998; Tole and Grove,
1998; Lee et al., 2000). Dividing cells in mouse embryos were labeled
with 5-bromo-2'-deoxyuridine (BrdU) (100 mg/kg; Roche Diagnostics
Corp., Indianapolis, IN) delivered intraperitoneally to pregnant mice
2-4 hr before they were killed. Nucleotide incorporation on
tissue sections was detected with antibody M0744 (Dako, Carpinteria,
CA), followed by diaminobenzidine peroxidase immunohistochemistry. For
Nissl staining, embryo heads or brains were dehydrated and embedded in
paraffin, and 10 µm coronal sections were obtained with a rotary
microtome. Sections were stained with cresyl violet.
A total of 29 Emx2 / mouse
brains were analyzed at E14.5 (n = 4), E16.5
(n = 7), or E18.5 (n = 18) and compared
with equal numbers of wild-type or heterozygote mutant littermate mice.
E18.5 is 1 d before birth and was selected as the primary age of
analysis for several reasons. First, Emx2
/ mice lack kidneys and die within a
few hours of birth (Pellegrini et al., 1996; Yoshida et al.,
1997). Thus, selecting E18.5 for analysis allows the hippocampus
to develop as long as possible and gives the best opportunity of
identifying different hippocampal fields in the mutant. The major
hippocampal fields are readily identifiable by either cytoarchitecture
or molecular markers at E18.5. A morphological dentate gyrus is evident
in wild-type mice by E16.5, and a range of molecular markers
distinguish different hippocampal fields and subregions by E15.5
(Caviness, 1973; Stanfield and Cowan, 1979; Tole et al., 1997; Tole and
Grove, 1998). Finally, previous analyses of hippocampal morphology in
Emx2 / mice were made at
E18.5-E19.5 (Pellegrini et al., 1996; Yoshida et al., 1997). Thus, our
observations could be compared directly with previous findings.
Additional litters were harvested at younger ages to compare the
overall development of the cerebral cortex in mutant and control mice.
No differences were observed in cortical morphology or gene expression
patterns between wild-type and heterozygote Emx2 mutant
mice, which were therefore pooled as controls.
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RESULTS |
During the early period of corticogenesis, Emx2 is
expressed in the ventricular zone (VZ) of the embryonic cerebral
hemisphere (Simeone et al., 1992a,b; Gulisano et al., 1996). The
gross morphology of the Emx2
/ brain is consistent with this
pattern of Emx2 expression. The cerebral hemispheres of
Emx2 / mice are reduced in size
compared with wild-type mice (Pellegrini et al., 1996; Yoshida et al.,
1997), and these gross changes are apparent by E11.5 (Yoshida et al.,
1997).
In Nissl-stained sections, the medial part of the Emx2
/ mutant cerebral cortex shows
particularly marked defects (Pellegrini et al., 1996; Yoshida et al.,
1997; Fig. 1). At E16.5, the hippocampal pyramidal layer appears shorter in the mutant than in wild-type mice
(Fig. 1, compare A, C, sections matched for
rostrocaudal level). In wild-type mice at this age, both the embryonic
dentate gyrus and the fimbria fornix are beginning to develop (Fig.
1A), but in the Emx2
/ mutant, no dentate gyrus can be seen
and the fimbria fornix is barely detectable (Fig. 1C). At
E18.5, the size difference between the mutant and wild-type hippocampus
is more striking (Fig. 1, compare B, D, sections
matched for rostrocaudal level). A morphological dentate gyrus is clear
in the wild-type hippocampus (Fig. 1B) but still
cannot be distinguished in the mutant (Fig. 1D).
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Figure 1.
The hippocampus is reduced in size in the
Emx2 mutant and has no morphologically identifiable
dentate gyrus. A-D, Nissl-stained coronal sections
through the hippocampus of wild-type (A,
B) or Emx2 homozygous ( /) mutant mice
(C, D). Arrows indicate
the approximate boundary between the embryonic hippocampal pyramidal
cell layer and the adjacent subiculum. A,
C, Sections from E16.5 littermate mice, matched for
rostrocaudal level. The hippocampal pyramidal cell layer is shorter in
the Emx2 mutant (C) than in the
wild-type embryo (A). The dentate gyrus
(dg) and fimbria fornix
(ff) have begun to develop in the
wild-type embryo (A), but no dentate gyrus can be
identified in the mutant and the fimbria fornix is severely shrunken
(C). B, D, Sections
from E18.5 mice, matched for rostrocaudal level. The size of the
hippocampus is markedly different between a wild-type embryo
(B) and an Emx2 mutant
(D). At E18.5, a morphological dentate gyrus is
clearly identifiable in the wild-type embryo (B)
but not detectable in the mutant (D).
Arrowhead in D indicates a small patch of
cells that may represent a residual dentate cell population (compare
cells indicated by arrows in Fig.
2K,L). Scale bar:
A-D, 150 µm.
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To analyze further the development of fields and subregions in the
hippocampus in the Emx2 /
mutant, we assembled a panel of molecular markers. These markers allow
the hippocampal CA fields and the dentate gyrus to be identified and
distinguished from one another in the embryonic mouse hippocampus beginning between E14.5 and E15.5 (Table
1) (Tole et al., 1997). Some markers are
permanently expressed in particular fields. For example, beginning at
E14.5-E15.5 and continuing into adulthood, KA1 and
SCIP are expressed in the pyramidal neurons of CA3 and CA1,
respectively, and expression of Steel marks the granule cell layer of the dentate gyrus (Fig.
2A,C,I;
Table 1) (Motro et al., 1991; Wisden and Seeburg, 1993; Frantz et al.,
1994; Tole et al., 1997; Lee et al., 2000). Other markers are
transient, distinguishing hippocampal subregions only in the embryo and
neonate (Table 1). For example, at E18.5, the embryonic age selected
for primary analysis of the Emx2 mutant, NK3 is
expressed in a region that consists of parts of CA1 and CA3,
Wnt5a and iGluR7 are expressed in the developing
dentate gyrus, and the ephrin receptor Ephb1 is expressed in
the dentate gyrus and a contiguous part of CA3 (Fig.
2B,D,J; Table 1).
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Figure 2.
Field specification is preserved in the
hippocampus of Emx2 mutant mice, and a dentate cell
population is present. A-L, Coronal sections through
the hippocampus of E18.5 control (c)
(A-D, I, J) or
Emx2 homozygous (/) mutant mice
(E-H, K, L) processed for
in situ hybridization. Medial is to the
left. A-D, In control brains, expression
of SCIP appears in CA1 and adjacent extrahippocampal
cortex (A), NK3 in contiguous
parts of CA1 and CA3 (B), KA1 in
CA3 (C), and Ephb1 in the dentate
gyrus and a part of CA3 close to the dentate (D).
E-H, In Emx2 mutant brains,
SCIP, NK3, KA1, and
Ephb1 are expressed in the same relative positions as in
control brains, but each marked territory or field is smaller in the
mutant. I-L, In the hippocampus of control mice, the
developing dentate gyrus (dg) is marked by expression of
Steel (I) and
iGluR7 (J). Steel
expression, in particular, reveals the developing V-shape of the
dentate gyrus. In the Emx2 mutant hippocampus,
Steel (K) and
iGluR7 (L) mark patches of dentate
cells (arrows) that do not form a gyrus. Scale bar:
A-D, 150 µm; E-H, K,
L, 120 µm; I, J, 200 µm.
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Region- and field-specific hippocampal markers were detected by
in situ hybridization at E18.5 in each Emx2
/ mutant brain examined
(n = 16), and expression of each marker appeared in the
correct relative position, despite marking a much smaller territory
than in control brains (Table 1; Fig. 2E-H). In particular, markers of the dentate pole of the hippocampus appeared.
These included expression of Ephb1 (Fig.
2H), as well as specific markers of the dentate
gyrus: Steel, iGluR7, and Wnt5a (Table
1; Fig. 2K,L). Thus,
interdigitating expression of SCIP, NK3,
KA1, Ephb1, Steel, iGluR7,
and Wnt5a indicates that CA1, CA3, and dentate fields are
developing in the Emx2 mutant but that each field is smaller
than in control brains. Specification of cells for each hippocampal
field, including the generation of a dentate gyrus cell population,
therefore appears to be preserved in the mutant.
Despite the presence of a dentate gyrus cell population, the gyrus
itself, a gross morphological structure, cannot be identified in the
Emx2 mutant (Pellegrini et al., 1996; Yoshida et al., 1997) (Fig. 1) The dentate cells that are labeled with molecular markers in
the E18.5 mutant appear in amorphous patches rather than forming a
distinct gyrus as in control mice (Fig. 2). Could this defect reflect a
widespread dysmorphology in the Emx2 mutant cortex, or one
that is specific to the dentate? To address this question, several
features of general cortical development were compared between
Emx2 mutants and wild-type mice at a range of ages.
Analysis of SCIP expression suggests a shared defect in the
hippocampus and neocortex of the Emx2
/ mutant. In wild-type mice,
SCIP expression labels a subpopulation of postmitotic
neurons in both hippocampus and neocortex (He et al., 1989; Frantz et
al., 1994; Tole et al., 1997). Initially, SCIP-expressing
cells are arrayed in a diffuse, broad band as they leave the VZ and
migrate toward the cortical plate (Frantz et al., 1994; Tole et al.,
1997). At E18.5, however, most SCIP-expressing cells have
settled in the cortical plate, indicated by a dense band of
SCIP labeling in both neocortex and hippocampus (Fig. 3C). In contrast, in the
Emx2 mutant cortex at E18.5, SCIP labeling is
diffuse (Fig. 3F), resembling the pattern seen 2-3 d
earlier in control brains (Fig. 3, compare F,
I). This abnormal pattern of SCIP labeling
could result from a misregulation of SCIP in the Emx2
/ mutant. However, an alternative
explanation is that cells express SCIP correctly in the
Emx2 / mutant but that
neuronal migration is disrupted or delayed, giving the pattern of
SCIP expression an immature appearance.
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Figure 3.
Disruptions of medial cortical development
in the Emx2 mutant. A-O, Coronal
sections through the hippocampus of control (A-C,
G-I, J-L) or Emx2 mutant
mice (D-F, M-O). B,
E, H, L, and
O show portions of A, D,
G, K, and N, respectively,
at higher magnification. A, B,
D, E, G, H,
Dividing cells were labeled with BrdU 4 hr before brains were fixed.
BrdU-labeled cells appear dark brown; light
brown staining is non-specific. In a control mouse at E16.5,
BrdU-labeled cells mark a narrow ventricular zone (vz)
in the hippocampus and neocortex (A, B).
Above the vz in neocortex, scattered BrdU-labeled cells appear in the
developing subventricular zone (svz), a second germinal
layer that generates glia (A, B). The
subventricular zone is not prominent in the hippocampus
(A, B). In an Emx2 mutant
at E16.5, in contrast, BrdU-labeled cells mark a broad vz in the
hippocampus and neocortex, and a separate subventricular zone is hard
to distinguish (D, E). A similarly broad
vz relative to the total thickness of the embryonic cortex is seen at
E14 in a control mouse (G, H).
Arrows in B, E, and
H indicate the rough boundaries of the vz, on either
side of the ventricle, in the hippocampus and an overlying part of
neocortex. Arrowhead in A indicates a
population of BrdU-labeled cells likely to represent a secondary
dentate precursor pool that develops late in hippocampal neurogenesis.
Only sparse BrdU-labeled cells appear in a corresponding position in
the Emx2 mutant hippocampus (arrowhead in
D). C, F,
I, In a control cortex at E18.5,
SCIP-expressing cells form a compact cortical plate
(C). SCIP-expressing cells in an
Emx2 mutant cortex are more dispersed
(F), as are SCIP-expressing cells in a control
cortex 3 d earlier, at E15.5 (I).
J, M, At E14.5, in a control brain,
embryonic CA3 is marked by expression of KA1 (arrow in
J). KA1 is not yet expressed in the hippocampus
of an Emx2 mutant at this age (arrow in
M) but is expressed in the thalamus
(th). K, L,
N, O, At E14.5, in a control cortex, a
broad, dense band of cells expresses class III -tubulin mRNA
(dark blue), a marker of neuronal differentiation
(K). Beneath this dense band, numerous, more
scattered cells also express class III -tubulin
(arrows indicate some of these cells in
L). The dense band of differentiating neurons
is less developed in a large medial region of the cortex in an
Emx2 mutant (compare cortex medial to marked
lines in K and N). Only
sparse cells beneath this dense band express class III -tubulin
(arrows in O). Scale bar:
A, C, D, F,
G, I, 230 µm; B,
E, H, 175 µm; J,
K, M, N, 200 µm;
L, O, 70 µm.
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Because cortical neurons take 2-3 d to migrate from the VZ to the
cortical plate (Altman and Bayer, 1990c), defects in the cortex at
E18.5 could be attributable to abnormalities in corticogenesis occurring at least 2 d earlier. To identify cells that would
generate the postmitotic cells labeled with our panel of markers at
E18.5, we injected BrdU into pregnant mice at E14 or E16.5 and
harvested the labeled embryos 2-4 hr later. This labeling protocol
provides a snapshot of cells that were dividing just before tissue harvest.
The pattern of cell proliferation in the Emx2 mutant mouse,
like the pattern of SCIP expression, appears disrupted and
perhaps delayed. At E16.5, cortical neurogenesis is almost over in the mouse (Angevine, 1965). In both the hippocampus and neocortex of
control mice, a compact band of BrdU-labeled cells is all that remains
of the VZ (Fig. 3A,B). In contrast,
in Emx2 / mutants at E16.5, the
BrdU-labeled VZ represents a large proportion of the total thickness of
the embryonic cortex (Fig. 3D,E).
Such a pattern of BrdU labeling in which the zone of dividing VZ cells is broad relative to the total thickness of the embryonic cortex is
reminiscent of the pattern seen 2-3 d earlier in control mice (Fig. 3,
compare D, E with G,
H). The abnormally broad VZ at E16.5 could be
generated in several ways, including a delay in cortical neurogenesis
or a failure of cells to leave the cell cycle on schedule and migrate
away from the VZ. Whatever the cause, the cortex again displays an
immature appearance in the Emx2 mutant compared with
littermate controls.
Neurons continue to be generated for the dentate gyrus into postnatal
life, and late-born dentate cells are generated from secondary germinal
zones rather than from the VZ (Angevine, 1965; Caviness, 1973;
Stanfield and Cowan, 1979; Altman and Bayer, 1990a,b). In E16.5 control
brains labeled with BrdU, many BrdU-positive cells appear along the
subpial face of the hippocampus (Fig. 3A) in which a
secondary dentate germinal population has been identified (Angevine,
1965; Caviness, 1973; Stanfield and Cowan, 1979; Altman and Bayer,
1990a,b). Only sparse BrdU-labeled cells are detectable in a
corresponding location in the Emx2 mutant (Fig.
3D), suggesting that this late-dividing progenitor
population is still small. The dentate cells identifiable at E18.5 in
the mutant may therefore have been generated almost exclusively by
primary progenitors in the VZ, partially explaining the small size of
the dentate cell population.
These observations indicate that the dentate field of the hippocampus
is specified in the Emx2 mutant mouse but suggest that its
development may be retarded. Consistent with this interpretation, the
appearance of another hippocampal field is also retarded in the mutant.
At E14.5, embryonic CA3 is identifiable by KA1 expression in
control brains (Fig. 3J). In contrast, CA3 cannot be
detected by KA1 expression at E14.5 in the Emx2
mutant brain (Fig. 3M), although this field is
readily detected in the mutant at E18.5 (Fig. 2G).
Slowed appearance of a CA3 field marker may reflect a general slowing
of cortical neuronal differentiation in the Emx2
/ mutant. The peak of such
differentiation in the mouse occurs between E11 and E18 (Caviness,
1973; Caviness and Sidman, 1973) when postmitotic neurons migrate from
the VZ to form an increasingly thick preplate-cortical plate. In
control brains at E14.5, the forming preplate-cortical plate is
indicated by dense expression of class III -tubulin, a general
neuronal marker (Fig. 3K,L). Beneath this dense band of labeling, numerous more dispersed neurons, presumably in the process of migrating away from the VZ, also express
class III -tubulin (Fig. 3L). In Emx2
/ mutant cortex at the same age, the
class III -tubulin-dense band is thinner (Fig.
3N,O), and there are fewer
dispersed -tubulin-expressing cells (Fig. 3O,
arrows). A diminished preplate-cortical plate characterizes
a large medial region of the mutant cortex that includes both
hippocampus and dorsal neocortex (Fig. 3, compare K,
N).
These and previous observations (Pellegrini et al., 1996; Yoshida et
al., 1997) suggest that Emx2 is directly required for the
normal growth and maturation of the medial cortex. A formal possibility, however, is that the small size and immature appearance of
the cerebral hemispheres and hippocampus in particular is part of a
systemic effect of the Emx2 mutation that leads to general shrinkage and developmental delay. Arguing against this possibility, other brain regions, such as the brainstem, are not grossly smaller in
size in Emx2 / mutants than in
wild-type mice (Pellegrini et al., 1996; Yoshida et al., 1997). To test
this possibility further, we measured the body size of Emx2
/ embryos and littermate controls and
compared their general morphological development using the staging
system of Theiler (1989). No size differences were found between
Emx2 / mutant bodies and
heterozygotes or wild-type embryos; furthermore, mutant and control
embryos were indistinguishable with respect to stage-specific external
features described by Theiler (1989), such as digit and skin development.
Findings of the present study suggest that the Emx2 mutation
disrupts medial cortical development, but that the dentate gyrus is not
selectively affected. Perhaps, however, early nested expression of
Emx genes defines a cortical region other than the
developing dentate gyrus, and it is this structure that is selectively
affected when nested Emx1/2 expression is lost. To address
this possibility, we characterized the region of medial cortex that
expresses Emx2 but not Emx1 at E10.5-E12.5,
early in the period of cortical neurogenesis. At E12.5, the medial edge
of the cerebral hemisphere has begun to differentiate into choroid
plexus epithelium (CPe), which is marked by strong transthyretin (TTR)
expression from the earliest stages of its development (Thomas and
Dziadek, 1993). The CPe therefore serves as an easily identifiable
medial landmark with which the borders of Emx1 and
Emx2 expression can be compared. Two-color
Emx1-TTR in situ hybridization at E12.5 reveals
a band of Emx1-poor neuroepithelium dorsal and caudal to the
CPe (Fig. 4A).
Emx2 is expressed in this Emx1-poor band, but not
in the CPe or in junctional epithelium at the border of the CPe (Fig. 4D). The outline of the Emx1-poor band
(Fig. 4A) strongly resembles that of the cortical
hem, an embryonic structure that expresses multiple Wnt
genes (Grove et al., 1998). Two-color Emx1-Wnt2b in
situ hybridization confirms that this band is filled by
Wnt2b expression and is therefore the
Wnt-expressing cortical hem (Fig. 4B,C,E,F).
At E10.5, expression of Emx1 and Emx2 in the
dorsal telencephalon appears similarly nested, with Emx2
expression more extensive than Emx1 (Simeone et al.,
1992b). Expression of Wnt3a, which marks the
incipient cortical hem at this age, fills in the Emx2-positive/Emx1-negative zone (data not
shown).
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Figure 4.
Nested expression of Emx1 and
Emx2 at E12.5 defines the cortical hem.
A, B, D, E12.5 cerebral
hemispheres from wild-type mice, processed as whole mounts for
two-color in situ hybridization, viewed from the medial
side. Rostral is to the left. E, A higher
magnification view of one such hemisphere. C,
F, Coronal sections through a hemisphere at the
rostrocaudal levels marked in B. A,
D, The choroid plexus epithelium (cpe) is
marked by expression of TTR (brown). Emx1
expression (blue in A) avoids a band of
cortical neuroepithelium curving dorsal and caudal to the cpe
(arrows) and a rostral telencephalic region
(asterisk). Emx2 (blue in
D) is expressed in both of these
Emx1-poor regions. Emx2 is not expressed
in the cpe or in a narrow strip of junctional epithelium
(white in D) adjacent to the cpe
(D). B, C,
E, F, Wnt2b expression
(brown) fills the curving band of cortical
neuroepithelium that is Emx1-poor (B,
C, E, F) and
defines the cortical hem. At the boundary of the cortical hem,
Wnt2b and Emx1 expression may overlap by
one or two cell widths, best seen at higher magnification
(E). The rostral telencephalic region that is
also Emx1-negative (asterisks in
A and D) is not part of the cortical hem.
Scale bar: A, B, D, 500 µm; E, 65 µm; C, F,
170 µm.
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At early stages of cortical neurogenesis, therefore, the region of
dorsomedial cortical neuroepithelium that expresses Emx2 but
not Emx1 is the cortical hem (Fig.
5). The cortical hem has not been fate
mapped; thus, the cell types it generates have not been definitively
identified. However, the cortical hem does not include regions of
neuroepithelium described previously as generating hippocampal neurons
(Angevine, 1965; Caviness, 1973; Stanfield and Cowan, 1979; Altman and
Bayer, 1990a,b,c). Most relevant, the identified primary and secondary
dentate neuroepithelia (Angevine, 1965; Caviness, 1973; Stanfield and
Cowan, 1979; Altman and Bayer, 1990a,b) lie outside the cortical hem
(Grove et al., 1998). Thus, the lack of a selective effect on a
particular subfield of the hippocampus in the Emx2 mutant
may be consistent with the normal early patterns of expression of
Emx1 and Emx2.
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Figure 5.
Summary of gene expression patterns with respect
to the cortical hem. Schematic coronal sections through an E12.5
cerebral hemisphere at midrostral (A) and caudal
(B) levels. At E12.5, the ventricular zone of the
embryonic cerebral cortex expresses Emx2. The
territories of Emx1, Wnt2b,
Wnt3a, and Wnt5a expression are nested
within the region of Emx2 expression.
Wnt2b, Wnt3a, and Wnt5a
are expressed in the cortical hem only; expression of
Emx1 fills most of the cortical neuroepithelium, but not
the cortical hem. Expression of at least two other transcription
factors, BF-1 and Lhx2, resembles that of
Emx1 in avoiding the cortical hem. Selectively low
expression of these genes may in part reflect the fate of the cortical
hem to shrink with respect to the rest of the cortical neuroepithelium
(see Discussion). cpe, Choroid plexus epithelium;
hem, cortical hem; je, junctional
epithelium adjacent to the differentiating cpe.
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|
The cortical hem may, however, regulate the development of adjacent
structures by secreting Wnt and Bmp proteins (Furuta et al., 1997;
Grove et al., 1998). In particular, even if the cortical hem does not
contribute neurons directly to the hippocampus, a Wnt3a signal from the
hem is required for normal hippocampal development (Lee et al., 2000).
If nested expression of Emx genes plays a role in cortical
regional specification, the cortical hem might be selectively lost in
the Emx2 / mutant mouse,
and this, in turn, could lead to a smaller hippocampus. Expression of
Wnt2b, Wnt3a, and Wnt5a shows,
however, that the cortical hem is present in the mutant (Yoshida et
al., 1997; data not shown). The hem region appears expanded early in
development (Yoshida et al., 1997) but slightly shrunken at later
embryonic ages (data not shown), consistent with the overall reduction
of the Emx2 / cortical mantle.
Previous studies suggest that the cortical hem generates CPe cells and
glial cells of the fimbria fornix (Maruyama and D'Agostino,
1967; Sturrock, 1979; Zaki, 1981; Altman and Bayer, 1990b; MacKenzie et
al., 1991; Nicholson-Flynn et al., 1996). Consistent with such an
origin for the CPe, the Emx2 mutant has an abnormally small
CPe (Pellegrini et al., 1996; Yoshida et al., 1997; data not shown).
The fimbria fornix is also shrunken in the Emx2 mutant
(Pellegrini et al., 1996; Yoshida et al., 1997), although this is an
expected secondary effect of a reduced hippocampus. Thus, the cortical
hem and its likely derivatives are present in the Emx2 mutant.
| |
DISCUSSION |
Cytoarchitectural analysis of the Emx2 mutant shows a
dramatic loss of the hippocampal dentate gyrus and a shrinkage of the entire hippocampus (Pellegrini et al., 1996; Yoshida et al., 1997). Because nested Emx gene expression defines the most medial
portion of the embryonic cerebral cortex, a plausible hypothesis is
that nested Emx1/2 expression is important for specifying
the region that gives rise to part of the hippocampus, prominently
including the dentate gyrus. Thus, in the Emx2 mutant,
dentate cells, and perhaps cells for other hippocampal fields, are
never specified. Our observations indicate, however, that although each
field is smaller in the Emx2 mutant, populations of cells
are specified for each field, including the dentate. These populations
develop in the correct positions relative to one another. Additional
observations identify the region of dorsomedial cortical
neuroepithelium that is defined by nested Emx1/2 expression
as the Wnt-rich cortical hem. Wnt gene expression
indicates that this structure too is present in the Emx2
mutant. Thus, neither the nested expression of Emx1/2 nor
Emx2 itself are absolutely required to specify cells to
different regional identities at the medial edge of the cerebral cortex.
Although each of the major medial regions is present in the
Emx2 mutant, each region appears abnormally small
(Pellegrini et al., 1996; Yoshida et al., 1997; present study).
For the hippocampus, this defect could result in part from reduction of
growth signals from a slightly shrunken cortical hem. However, the
sector of medial cortex that is reduced in the Emx2 mutant
is larger than the hippocampus alone (Pellegrini et al., 1996; Yoshida
et al., 1997; present study), suggesting that the hippocampal
defect is part of a more widespread effect of the Emx2
mutation. The disproportionate reduction of medial compared with
lateral cortex (Pellegrini et al., 1996; Yoshida et al., 1997;
present study) may reflect the normal gradient of Emx2 protein, which
shows a caudomedial maximum in the embryonic cortex and a rostrolateral
minimum (Mallamaci et al., 1998).
The cellular mechanisms that underlie the decreased size of the
Emx2 mutant medial cortex, and of the cerebral hemispheres in general, are unclear. A simple explanation might be that
Emx2 regulates cortical neuron proliferation and that, in
the absence of Emx2, proliferation is reduced. For
comparison, smaller cerebral hemispheres are also seen in mice with
targeted disruption of the winged helix transcription factor,
BF-1. In these mice, cerebral hypoplasia results from
reduced cell proliferation, together with a precocious neuronal
differentiation that depletes the cerebral precursor pool (Xuan et al.,
1995). Thus, BF-1 mutant embryos have a thinner cerebral VZ
than wild-type littermates and a thicker layer of differentiating
neurons (Xuan et al., 1995). In contrast, Emx2 mutant
embryos have an abnormally thick VZ in the medial embryonic cortex, at
least at late stages of corticogenesis, and a thinner, less developed
cortical plate.
An alternative explanation, supported by our findings, might be that
the Emx2 mutation disrupts the timely maturation of the medial cortex rather than causing a frank decrease in cell
proliferation. Such a disruption could reduce the size of the
Emx2 mutant cerebral hemispheres and could also have more
specific consequences. One example might be the loss of a morphological
dentate gyrus in the Emx2 mutant. Although dentate gyrus
neurons begin to be generated by VZ cells as early as are CA field
neurons, major development of the dentate gyrus occurs in late
embryonic and early postnatal life (Angevine, 1965; Caviness, 1973;
Stanfield and Cowan, 1979; Altman and Bayer, 1990a,b). Thus, whereas
neurogenesis in the mouse CA fields is almost over by E16, neurogenesis
in the dentate gyrus increases sharply between E16 and E18 (Caviness,
1973). Because Emx2 mutant mice die at birth, any disruption
of the normal schedule of hippocampal development would have a
particular impact on the dentate gyrus.
By proliferating and differentiating on an abnormal schedule, cells in
the Emx2 mutant cortex might also miss interacting with a
variety of cellular and molecular cues that direct specific aspects of
their further development. For example, the laminar identity of
cortical neurons depends on precisely timed cues within the cortical VZ
(McConnell, 1995), and region-specific aspects of cortical development,
such as the formation of somatosensory barrel fields, require cues
provided by subcortical innervation (O'Leary et al., 1994). If such
cues are missed, several specific features of later cortical
development could be affected. Whether such effects occur in the
Emx2 mutant mouse remains to be determined.
A role for Emx proteins in regulating cortical maturation might also
explain the nested expression of Emx genes at the cortical hem. In keeping with a time-limited functional role, the cortical hem
region shrinks as the rest of the embryonic cortex expands (Maruyama
and D'Agostino, 1967; Zaki and Van der Loos, 1980; Furuta et al.,
1997). The selectively low expression in the cortical hem of
Emx1 and other genes implicated in tissue growth, such as
BF-1 (Xuan et al., 1995) and Lhx2 (Porter et al.,
1997) (Fig. 5), could reflect the fate of the cortical hem to shrink
with respect to the rest of the cortical mantle. If Emx1 and
Emx2 play similar roles, both may be needed to support the
normal time course of cortical development, whereas Emx2
alone may be sufficient for the relatively slower growth of the
cortical hem.
A final explanation for the reduced size of hippocampal fields in the
Emx2 mutant could be that the mutation disrupts the regionalization of medial cortex in a different way from that examined
in the present study. Recent evidence indicates that the
Emx2 mutation affects neocortical regionalization along the rostrocaudal axis, resulting in an expansion of rostral neocortical areas and a reduction of caudal areas (Bishop et al., 1999). That field
boundaries might be shifted in the Emx2 mutant hippocampus, reducing the size of each field, is therefore an intriguing
possibility. Because cells are successfully specified to different
hippocampal field identities in the Emx2 mutant, this
interpretation would dissociate hippocampal patterning into at least
two processes; the mechanisms that specify cells to develop particular
field identities are not the same as those that specify the overall size of each field. Emx2 is evidently not required for the
first process but might be required for the second. However,
determining if fields are differentially reduced in the Emx2
mutant according to their position in the hippocampus is difficult
given their tiny size. More information may be gained from functional
experiments in which Emx proteins are overexpressed in the
hippocampus to determine whether these manipulations shift the
boundaries of hippocampal fields or alter more general processes of
hippocampal growth and maturation.
| |
FOOTNOTES |
Received July 13, 1999; revised Dec. 29, 1999; accepted Jan. 3, 2000.
This work was supported by grants from the Brain Research Foundation,
National Institutes of Health (E.G.), the March of Dimes (E.G.), the
Max-Planck-Society, and European Union Grant BIO4-CT96-0378 (P. Gruss). We thank Peter Gruss for the gift of Emx2 mutant
brains, P. Mason and C. Ragsdale for comments on this manuscript, and Amal Ting for technical assistance. cDNA reagents were provided by E. Boncinelli, G. Lemke, J. Boulter, C. Ragsdale, and S. Nakanishi.
Correspondence should be addressed to E. A. Grove, Department of
Neurobiology, Pharmacology, and Physiology, MC0926, University of
Chicago, Chicago, IL 60637. E-mail: egrove{at}drugs.bsd.uchicago.edu.
Dr. Tole's present address: Tata Institute of Fundamental Research,
Homi Bhabha Road, Colaba, Mumbai 400,005, India.
| |
REFERENCES |
-
Altman J,
Bayer SA
(1990a)
Migration and distribution of two populations of hippocampal granule cell precursors during the perinatal and postnatal periods.
J Comp Neurol
301:365-381[ISI][Medline].
-
Altman J,
Bayer SA
(1990b)
Mosaic organization of the hippocampal neuroepithelium and the multiple germinal sources of dentate granule cells.
J Comp Neurol
301:325-342[ISI][Medline].
-
Altman J,
Bayer SA
(1990c)
Prolonged sojourn of developing pyramidal cells in the intermediate zone of the hippocampus and their settling in the stratum pyramidale.
J Comp Neurol
301:343-364[ISI][Medline].
-
Angevine JB
(1965)
Time of neuron origin in the hippocampal region.
Exp Neurol Suppl
2:1-70.
-
Bishop KM,
Leingartner A,
Richards LJ,
O'Leary DDM
(1999)
Emx2 imparts area identity to mammalian neocortex.
Soc Neurosci Abstr
25:501.
-
Caviness VS
(1973)
Time of neuron origin in the hippocampus and dentate gyrus of normal and reeler mutant mice: an autoradiographic analysis.
J Comp Neurol
151:113-120[ISI][Medline].
-
Caviness VS,
Sidman RL
(1973)
Time of origin of corresponding cell classes in the cerebral cortex of normal and reeler mutant mice: an autoradiographic analysis.
J Comp Neurol
148:141-151[ISI][Medline].
-
Frantz GD,
Bohner AP,
Akers RM,
McConnell SK
(1994)
Regulation of the POU domain gene SCIP during cerebral cortical development.
J Neurosci
14:472-485[Abstract].
-
Furuta Y,
Piston DW,
Hogan BL
(1997)
Bone morphogenetic proteins (BMPs) as regulators of dorsal forebrain development.
Development
124:2203-2212[Abstract].
-
Grove EA,
Tole S,
Limon J,
Yip L,
Ragsdale CW
(1998)
The hem of the embryonic cerebral cortex is defined by the expression of multiple Wnt genes and is compromised in Gli3-deficient mice.
Development
125:2315-2325[Abstract].
-
Gulisano M,
Broccoli V,
Pardini C,
Boncinelli E
(1996)
Emx1 and Emx2 show different patterns of expression during proliferation and differentiation of the developing cerebral cortex.
Eur J Neurosci
8:1037-1050[ISI][Medline].
-
He X,
Treacy MN,
Simmons DM,
Ingraham HA,
Swanson LW,
Rosenfeld MG
(1989)
Expression of a large family of POU-domain regulatory genes in mammalian brain development.
Nature
340:35-42[Medline].
-
Lee SM,
Tole S,
Grove EA,
McMahon AP
(2000)
A local Wnt3a signal is required for development of the mammalian hippocampus.
Development
127:457-467[Abstract].
-
Lumsden A,
Krumlauf R
(1996)
Patterning the vertebrate neuraxis.
Science
274:1109-1115[Abstract/Free Full Text].
-
MacKenzie A,
Ferguson MW,
Sharpe PT
(1991)
Hox-7 expression during murine craniofacial development.
Development
113:601-611[Abstract].
-
Mallamaci A,
Iannone R,
Briata P,
Pintonello L,
Mercurio S,
Boncinelli E,
Corte G
(1998)
EMX2 protein in the developing mouse brain and olfactory area.
Mech Dev
77:165-172[ISI][Medline].
-
Maruyama S,
D'Agostino AN
(1967)
Cell necrosis in the central nervous system of normal rat fetuses. An electron microscopic study.
Neurology
17:550-558[Free Full Text].
-
McConnell SK
(1995)
Constructing the cerebral cortex: neurogenesis and fate determination.
Neuron
15:761-768[ISI][Medline].
-
Motro B,
van der Kooy D,
Rossant J,
Reith A,
Bernstein A
(1991)
Contiguous patterns of c-kit and steel expression: analysis of mutations at the W and Sl loci.
Development
113:1207-1221[Abstract].
-
Nauta WJH,
Feirtag M
(1986)
In: Fundamental neuroanatomy. New York: Freeman.
-
Nicholson-Flynn K,
Hitchcock-DeGregori SE,
Levitt P
(1996)
Restricted expression of the actin-regulatory protein, tropomyosin, defines distinct boundaries, evaginating neuroepithelium, and choroid plexus forerunners during early CNS development.
J Neurosci
16:6853-6863[Abstract/Free Full Text].
-
Nowakowski RS,
Rakic P
(1981)
The site of origin and route and rate of migration of neurons to the hippocampal region of the rhesus monkey.
J Comp Neurol
196:129-154[ISI][Medline].
-
O'Leary DD,
Schlaggar BL,
Tuttle R
(1994)
Specification of neocortical areas and thalamocortical connections.
Annu Rev Neurosci
17:419-439[ISI][Medline].
-
Pellegrini M,
Mansouri A,
Simeone A,
Boncinelli E,
Gruss P
(1996)
Dentate gyrus formation requires Emx2.
Development
122:3893-3898[Abstract].
-
Porter FD,
Drago J,
Xu Y,
Cheema SS,
Wassif C,
Huang SP,
Lee E,
Grinberg A,
Massalas JS,
Bodine D,
Alt F,
Westphal H
(1997)
Lhx2, a LIM homeobox gene, is required for eye, forebrain, and definitive erythrocyte development.
Development
124:2935-2944[Abstract].
-
Rakic P,
Nowakowski RS
(1981)
The time of origin of neurons in the hippocampal region of the rhesus monkey.
J Comp Neurol
196:99-128[ISI][Medline].
-
Shigemoto R,
Yokota Y,
Tsuchida K,
Nakanishi S
(1990)
Cloning and expression of a rat neuromedin K receptor cDNA.
J Biol Chem
265:623-628[Abstract/Free Full Text].
-
Simeone A,
Acampora D,
Gulisano M,
Stornaiuolo A,
Boncinelli E
(1992a)
Nested expression domains of four homeobox genes in developing rostral brain.
Nature
358:687-690[Medline].
-
Simeone A,
Gulisano M,
Acampora D,
Stronaiuolo A,
Rambaldi M,
Boncinelli E
(1992b)
Two vertebrate homeobox genes related to the Drosophila empty spiracles gene are expressed in the embryonic cerebral cortex.
EMBO J
11:2541-2550[ISI][Medline].
-
Stanfield BB,
Cowan WM
(1979)
The development of the hippocampus and dentate gyrus in normal and reeler mice.
J Comp Neurol
185:423-459[ISI][Medline].
-
Sturrock RR
(1979)
A morphological study of the development of the mouse choroid plexus.
J Anat
129:777-793[ISI][Medline].
-
Theiler K
(1989)
In: The house mouse. New York: Springer.
-
Thomas T,
Dziadek M
(1993)
Capacity to form choroid plexus-like cells in vitro is restricted to specific regions of the mouse neural ectoderm.
Development
117:253-262[Abstract].
-
Tole S,
Grove EA
(1998)
Early regional patterning of the medial telencephalon.
Soc Neurosci Abstr
24:785.
-
Tole S,
Patterson PH
(1995)
Regionalization of the developing forebrain: a comparison of FORSE-1, Dlx-2 and BF-1.
J Neurosci
15:970-980[Abstract].
-
Tole S,
Christian C,
Grove EA
(1997)
Early specification and autonomous development of cortical fields in the mouse hippocampus.
Development
124:4959-4970[Abstract].
-
Wisden W,
Seeburg PH
(1993)
A complex mosaic of high-affinity kainate receptors in rat brain.
J Neurosci
13:3582-3598[Abstract].
-
Xuan S,
Baptista CA,
Balas G,
Tao W,
Soares VC,
Lai E
(1995)
Winged helix transcription factor BF-1 is essential for the development of the cerebral hemispheres.
Neuron
14:1141-1152[ISI][Medline].
-
Yoshida M,
Suda Y,
Matsuo I,
Miyamoto N,
Takeda N,
Kuratani S,
Aizawa S
(1997)
Emx1 and Emx2 functions in development of dorsal telencephalon.
Development
124:101-111[Abstract].
-
Zaki W
(1981)
Ultrastructure of the choroid plexus and its development in the mouse.
Z Mikrosk Anat Forsch
95:919-935[ISI][Medline].
-
Zaki W,
Van der Loos H
(1980)
[A new concept about the morphogenesis of the prosencephalon in mammals (translated from French)].
Arch Anat Microsc Morphol Exp
69:123-134[ISI][Medline].
Copyright © 2000 Society for Neuroscience 0270-6474/00/2072618-08$05.00/0
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ABSTRACT
INTRODUCTION
