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The Journal of Neuroscience, November 15, 2001, 21(22):8798-8808
disabled-1 Functions Cell Autonomously during
Radial Migration and Cortical Layering of Pyramidal Neurons
Vicki
Hammond1,
Brian
Howell2,
Leanne
Godinho1, and
Seong-Seng
Tan1
1 Howard Florey Institute, The University of Melbourne,
Parkville 3010, Victoria, Australia, and 2 National
Institute for Neurological Diseases and Stroke, National Institutes of
Health, Bethesda, Maryland 20892
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ABSTRACT |
Genetic mosaics offer an excellent opportunity to analyze complex
gene functions. Chimeras consisting of mutant and wild-type cells
provide not only the avenue for lineage-specific gene rescue but can
also distinguish cell-autonomous from non-cell-autonomous gene
functions. Using an independent genetic marker for wild-type cells, we
constructed Dab1+/+  Dab1 / chimeras with the aim of
discovering whether or not the function of Dab1 during neuronal
migration and cortical layering is cell autonomous.
Dab1+/+ cells were capable of radial
migration and columnar formation in a
Dab1/environment. Most
Dab1+/+ cells segregated to the
superficial part of the mutant cortex, forming a multilayered
supercortex. Neuronal birth-dating studies indicate that supercortex
neurons were correctly layered, although adjacent mutant cortex neurons
were in reversed order. Immunocytochemistry using Emx1, a marker for
pyramidal neurons, indicates that the vast majority of
Dab1+/+ neurons in the supercortex
were Emx1 immunoreactive. Confirmation of the pyramidal phenotype was
demonstrated by the absence of GABA immunoreactivity among
Dab1+/+ cells in the supercortex.
Myelin staining using 2'3'-cyclic nucleotide 3'-phosphodiesterase showed the supercortex was supported by a secondary white matter from which thick fiber tracts appear connected to the underlying mutant white matter. The presence of
Dab1+/+ cells failed to rescue inversion
of cortical layers and the abnormal infiltration of the marginal zone
by Dab1/ cells. Conversely, mutant
cells did not impose a mutant phenotype on adjacent wild-type neurons.
These results suggest that Dab1 functions cell autonomously with
respect to radial migration and cortical layering of pyramidal neurons.
Key words:
disabled-1; Reelin; development; cortex; Emx-1; radial migration
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INTRODUCTION |
Neurons that assemble to form the
cerebral neocortex migrate in multiple waves after their birth in the
ventricular zone. Early-born neurons are the first to reach the
outermost aspects of the cortical plate (CP), but these become
displaced inward as later-born neurons migrate past them (Angevine and
Sidman, 1961 ; Rakic, 1974). In this manner, cohorts of neurons born at different times become organized into precise cortical layers. The
genetic mechanisms behind this inside-out order of cortical layering
have been under intense scrutiny, stimulated in part by the recent
discovery of reelin, the gene responsible for the classic
mouse mutant reeler (D'Arcangelo et al., 1995). Mutations in reelin give rise to inversion of cortical layers
(Caviness and Sidman, 1973), in addition to other abnormalities in the
hippocampus and cerebellum that are associated with the typical reeling
gait and motor defects (Goldowitz et al., 1997). Whereas the Reelin protein is secreted by Cajal-Retzius cells in the marginal zone (MZ)
(Ogawa et al., 1995; D'Arcangelo et al., 1997), neurons arriving into
the adjacent CP are devoid of Reelin (Rice et al., 1998). Instead, CP
neurons express a number of other proteins, some of which function
downstream of Reelin (for review, see Rice and Curran, 1999). Together,
these proteins form the Reelin signaling pathway, and disruption of
some of these components, either spontaneously or by
gene-targeting, results in the reeler-like phenotype with behavioral ataxia and inversion of cortical layers (Howell et al.,
1997b; Sheldon et al., 1997; Ware et al., 1997; Trommsdorff et al.,
1999).
A key player in this molecular tapestry is disabled-1
(Dab1), a mouse relative of Drosophila disabled,
that encodes an intracellular protein with properties of an adapter
molecule in protein kinase signaling (Howell et al., 1997a). Dab1 lacks
catalytic activity, but is required for Reelin signal transduction.
After extracellular binding of Reelin to lipoprotein receptors [very
low-density lipoprotein receptor (VLDLR) and apolipoprotein E receptor
2 (ApoER2)], increased tyrosine phosphorylation of Dab1 is
observed (D'Arcangelo et al., 1999; Hiesberger et al., 1999; Howell et
al., 1999). In addition, there is accumulation of Dab1 in cortical
neurons of either reelin / or
ApoER2//VLDLR/
mice, suggesting failure of Dab1 degradation in the absence of Reelin
pathway activation (Rice et al., 1998; Trommsdorff et al., 1999). The
role for Dab1 tyrosine phosphorylation in Reelin signaling is further
supported by mice that express a mutant form of Dab1 that is not a
tyrosine kinase substrate. These mutant mice have a phenotype
reminiscent of the Reeler mice and Dab1 null mutants, suggesting that
correct Dab1 phosphorylation is a crucial event for correct neuronal
positioning (Howell et al., 2000).
Apart from ApoER2/VLDLR receptors, Reelin has also been shown to bind
to a number of other cell surface molecules present in migrating
neurons, including cadherin-related neuronal receptors and
 3 1 integrin (Senzaki et al., 1999; Dulabon et al., 2000). Mutations in a number of other genes also cause cortical laminar inversions (e.g., Cdk5 and p35) and abnormalities (e.g., 3
integrin), suggesting multiple pathway involvement in lamina
formation and that components of the Reelin pathway, although
necessary, may not be sufficient for layer specification. The question
then arises whether the Reelin pathway, acting through Dab1, functions
cell autonomously during two key morphogenetic processes involved in cortical development: cortical neuron migration and layer
specification. If the answer is yes, then restoration of
Dab1 gene function by introducing
Dab+/+ cells into a
Dab1/
environment should produce wild-type phenotypes in
Dab1/ cells. In addition, there would
be failure of rescue of mutant phenotypes among adjacent
Dab1/ neurons. Conversely,
non-cell-autonomous function of Dab1 would result in extension of gene
function beyond cells expressing the original mutant phenotype,
resulting in some Dab1+/+ neurons assuming
the mutant phenotype, although other
Dab1/ neurons may be rescued.
To distinguish between these possibilities, we constructed
Dab1+/+ Dab1/ chimeras with the aim of
undertaking lineage-specific gene rescue (Rossant and Spence, 1998).
Using an independent lacZ marker for Dab1+/+ cells, we found that
Dab1+/+ cells formed a supernumerary
"supercortex" above the Dab1/
cortex [not to be confused with the superplate (SPP) (Caviness, 1982)], and there was no rescue of layer inversion among adjacent Dab1/ neurons. Despite comprising a
minority of cortical cells, the Dab1+/+
neurons were able to form an inside-out cortical structure with respect
to their birth dates. This structure bore some of the hallmarks of a
"minicortex," including staining for the pyramidal neuron marker
Emx1 and extensive myelination of a secondary subcortical white matter.
These results led us to conclude that Dab1 signaling in cortical
neurons is cell autonomous with respect to the establishment of
cortical layers among radially migrating neurons of the pyramidal class.
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MATERIALS AND METHODS |
Chimeras. To generate
Dab1+/+ Dab1/ chimeras
(Dab1/ chimeras), we introduced
embryonic stem (ES) cells carrying the lacZ reporter gene
into Dab1/ blastocysts. The latter
were produced from Dab1+/ heterozygous
crosses (maintained on C57BL/6J × DBA hybrid background), and
Dab1/ offspring were identified by
genotyping. The ES cells have normal Dab1 alleles (confirmed
by PCR) and were derived from the H253 transgenic mouse line with the
XlacZ/XlacZ
genotype (Tan et al., 1993; Sturm et al., 1997). Previous experiments using this cell line have shown that the injection of one to two ES
cells per blastocyst is sufficient to confer chimerism in the CNS, and the genetically marked cells migrated in essentially the same patterns as host cells (Tan et al., 1998; Reese et al., 1999).
Injected blastocysts were implanted into pseudopregnant foster females,
and chimeric pups were reared for 14-16 d before genotype analysis and
processing for
5-bromo-4-chloro-3-indolyl--D-galactopyranoside (X-gal) histochemistry and immunocytochemistry. For immunocytochemistry against Dab1 and calretinin [a marker for the subplate (SP)], a
number of embryos (n = 33) were killed at
embryonic day 16.5 (E16.5), and brains were fixed as whole mounts in a
solution of 4% paraformaldehyde.
To test whether Dab1+/+ and
Dab1/ neurons migrate correctly in the
chimeric cortices, mice were treated in utero (at
gestational ages E12.5, E13.5, or E16.5) with 5-bromodeoxyuridine
(BrdU) at a dose of 50 mg/kg body weight (intraperitoneally, dissolved
in sterile saline containing 0.007N NaOH). Neurons retaining the BrdU
label are presumed to have been born during the labeling period, when
they undergo the last S phase of their mitotic cycle.
Genotyping. To isolate DNA for PCR genotyping, tissue (toe,
tail, liver, or lung) was digested in 200 µl of PCR lysis buffer (50 mM KCl, 10 mM Tris-HCl, pH
8.3, 2 mM MgCl2, 0.45%
Nonidet P-40, and 0.45% Tween 20) with Proteinase K (200 µg/ml) at
56°C. DNA primers were used at a final reaction concentration of 10 ng/µl. Primers for Dab1 covering the deleted portion of
the gene (Howell et al., 1997b) and for neomycin
phosphotransferase (Neo) gene were used
(Dab1: forward, 5'GCGAAGCCACTTTGATAAAGA-3' and reverse,
5'-TAACTTGTCTCCCCGAGCTG-3'; Neo: forward,
5'-ATCAGGATGATCTGGA-CGAAGA-3' and reverse,
5'-CCACAGTCGATGAATCCAGAA-3'). Primer sequences for lacZ were
as follows: forward 5'-CCCATTACGG-TCAATCCGCCG-3', and reverse
5'-CCTGGCCGTAACCGACCCA-GCG-3').
The DNA-primer mixture was heated at 94°C for 10 min in a Gene Amp
PCR System (model 9600, PerkinElmer Life Sciences, Emeryville, CA). A reaction mix was then added to give a final concentration of 100 mM Tris-HCl, pH 8.3, 500 mM KCl (1× PCR
Buffer II; PerkinElmer Life Sciences), 1.5 mM
MgCl2, 100 µM dNTPs, and 1.25 U of
Taq DNA polymerase (PerkinElmer Life Sciences).
Amplification of the samples was performed by an additional 1 min at
94°C, followed by 36 cycles consisting of annealing at 62°C for 30 sec, extension at 72°C for 30 sec, and denaturing at 94°C for 30 sec. PCR products were analyzed on a 3% agarose gel with anticipated
81, 170, and 154 bp product sizes for Dab1, Neo,
and lacZ, respectively.
Histology. After a lethal injection of Avertin, chimeras
were perfused for 15 min by intracardial perfusion with 4%
paraformaldehyde in 0.1 M Sorensen's phosphate
buffer, pH 7.4, with 2 mM
MgCl2 and 5 mM EGTA, and
the brains were removed for 20 min after fixation. After cryoprotection
with 30% sucrose, brains were embedded in OCT (Tissue-Tek, Miles Inc.,
Torrance, CA) for cryosectioning. Coronal sections (60 µm) of the
cortex were obtained for X-gal histochemistry to visualize
-galactosidase (gal), and 14 µm coronal sections were prepared
for immunocytochemistry. Sections for X-gal histochemistry were
incubated overnight at 37°C in a solution of 0.1% X-gal containing 2 mM MgCl2, 5 mM EGTA, 0.01% (w/v) sodium deoxycholate, 0.02%
(w/v) Nonidet P-40, 5 mM
K3Fe(CN)6, and 5 mM
K4Fe(CN)6·6H2O
in 0.1 M Sorenson's phosphate buffer. The X-gal
was prepared as a 4% stock in dimethylformamide and was added to the
mixture just before use.
For nuclear staining after X-gal histochemistry, sections were rinsed
in PBS and then stained in 50 µg/ml Hoescht 33342 (Sigma, St. Louis,
MO) for 2 min. Fluorescent cell nuclei were visualized using a
UV filter.
Immunocytochemistry. For double-immunofluorescence studies,
14 µm coronal sections were mounted on
3-aminopropyltreithoxy-silane-coated slides and dried for 2 hr before
incubating in primary antibodies. To obtain double labeling of gal
with BrdU, NeuN, calbindin, or 2'3'-cyclic nucleotide
3'-phosphodiesterase (CNPase), sections were processed for
immunocytochemistry using either standard one-step or two-step
avidin-biotin procedures. To expose the BrdU, tissues were
preincubated with 2N HCl at 37°C for 45 min before addition of the
primary antibody. All primary antibodies were diluted in 0.1 M PBS with 0.3% Triton X-100. Primary antibodies
included the following: a purified rabbit polyclonal antibody to gal
(1:100 dilution; 5 Prime 3 Prime Inc., Boulder, CO); a mouse
monoclonal antibody to gal (1:250 dilution; Promega, Melbourne,
Australia); a mouse monoclonal antibody to BrdU (1:30 dilution; Becton
Dickinson, San Jose, CA); a mouse monoclonal antibody to NeuN (1:200
dilution; Chemicon, Temecula, CA); a mouse monoclonal antibody to
CNPase (1:200 dilution; Chemicon); a rabbit antibody to calretinin
(1:200 dilution; Swant, Bellinzona, Switzerland); a rabbit polyclonal antibody to calbindin (1:1000 dilution; Swant); and a rabbit polyclonal antibody to Dab1 (Howell et al., 1997a). Secondary antibodies were
biotinylated anti-rabbit (1:200 dilution; Vector Laboratories, Burlingame, CA), donkey anti-mouse Cy3 (1:1000 dilution; Jackson ImmunoResearch, West Grove, PA), and Alexa Fluor 594-conjugated goat
anti-rabbit IgG (1:500 dilution; Molecular Probes, Eugene, OR). With
BrdU, NeuN, and CNPase antigens, simultaneous visualization of gal
was achieved with fluorescein-avidin D (1:200 dilution; Vector
Laboratories). Incubation with primary antibody overnight was followed
by 1 hr in secondary antibodies before coverslipping with Fluoromount-G
(Southern Biotechnology, Birmingham, AL).
For simultaneous detection of gal and Emx1 or gal and
GABA, we used a method that allows discrimination of primary
antibodies raised in the same species, in this case the rabbit
(Shindler and Roth, 1996). This method works on the rationale that
primary antisera against one antigen (Emx1 or GABA) is used at such
dilute levels that only tyramide signal amplification (TSA) allows for its detection. The second primary antiserum against gal is used at
normal concentration and is detected by conventional
immunocytochemistry. The secondary antibody used to detect the rabbit
IgG against gal is incapable of detecting the rabbit IgG against
Emx1 (or GABA) by virtue of the extreme dilution of the latter.
Sections were blocked in 10% normal horse serum (CSL Ltd., Melbourne,
Australia) in PBS for 1 hr and then in 0.5% blocking reagent
(Renaissance TSA Indirect; NEN, Boston, MA) in buffer containing 0.1 M Tris-Cl and 0.15 M NaCl, pH 7.6, for 30 min
at room temperature. Incubation with rabbit anti-Emx1 (1:6000 dilution; gift of J. Parnavelas, University College, London, UK) or rabbit anti-GABA (1:10,000 dilution; Sigma, St. Louis, MO) was performed overnight, followed by biotinylated goat anti-rabbit IgG (1:200 dilution; Vector Laboratories) and streptavidin-HRP (Renaissance TSA
Indirect; diluted 1:100; NEN) for 1 hr. This was followed by biotinyl
tyramide amplification for 2 min (1:100 dilution; amplification
diluent) and incubation for 1 hr in fluorescein-avidin D (1:200
dilution; Vector Laboratories). Detection of gal was essentially as
described above, except that the secondary fluorophore was substituted
with Alexa Fluor 594 goat anti-rabbit IgG (diluted 1:400; Molecular
Probes). Sections were mounted with Fluoromount-G (Southern
Biotechnology, Birmingham, AL).
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RESULTS |
Previous studies using stem cell chimeras have shown that
descendants of a single injected ES cell are capable of normal
participation in CNS development and provide good resolution on cell
migration pathways and cell fates (Tan et al., 1998; Hawkes et al.,
1999; Reese et al., 1999). Using this model, we introduced one to two wild-type ES cells into blastocysts from
Dab1+/ intercrosses. Under these
conditions, ES cells with normal Dab1 genes can populate
blastocyst hosts with Dab1/,
Dab1+/, or
Dab1+/+genotypes.
Chimeras (from Dab1/,
Dab1+/, or
Dab1+/+ hosts) were identifiable by their
patchy coat colors, and Dab1/ chimeras
(subsequently confirmed by genotyping) displayed ataxia, trembling,
dragging of hind limbs, and frequent flipping onto their backs. In all
Dab1/ chimeras, regardless of the
contribution of wild-type cells to their brains, this behavioral
phenotype was not rescued, and these mice did not survive beyond
17 d after birth. In all cases, chimeric cerebella were smaller
and poorly foliated. Genotyping results were used to distinguish
Dab1/ chimeras from littermates.
Nonchimeric mice did not provide a PCR product for lacZ
(Fig. 1B, lanes
2-4). The presence or absence of Dab1 or
Neo fragments allowed wild-type
(Dab1+/+) hosts (Fig.
1A, lane 4) to be distinguished
from heterozygous (Dab1+/) (lane
3) or null (Dab1/) (lane
2) mutants. Weak Dab1/ chimeras
(lane 5) tended to provide a weaker Dab1 band
(from the smaller contribution of ES cells) but a strong band for the Neo gene present in the targeting construct (Howell et al.,
1997b). Strong Dab1/ chimeras
(lanes 6-9) gave bands of approximately equal intensity for
Dab1 and Neo, reflecting a greater contribution
of Dab1+/+ ES cells. Lane 10 shows the presence of Dab1 in ES cells used for making the
chimeras.
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Figure 1.
Genotyping to distinguish chimeric
from nonchimeric animals and wild-type from mutant animals.
A, Top band represents the mutant allele
(Neo 170bp), and the bottom
band the endogenous allele (Dab1
81bp). B, Top band
represents lacZ from introduced ES cells (LacZ
154bp), the bottom band represents
Dab1 (81 bp). Lane 1,
pUCHpaII markers; lane 2, homozygous
mutant (Dab1/); lane
3, heterozygous mutant
(Dab1+/); lane 4,
wild type (Dab1+/+); lane
5, weak Dab1/ chimera;
lanes 6-9, strong
Dab1/ chimeras; lane
10, injected ES cells; lane 11, no DNA. As
expected, a weak Dab1/ chimera
gave a strong Neo band and a weak Dab1
band (lane 5); conversely, strong
Dab1/ chimeras (lanes
6-9) gave intense Dab1 signals from the ES cell
allele. Confirmation of the presence of the injected ES cells was
obtained by assaying for the presence of the lacZ gene.
As expected, this band was present in the ES cells (lane
10) and in chimeras (lanes 5-9).
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Wild-type cells in Dab1/
chimeras form a supercortex
Chimeric littermates with Dab1+/+ or
Dab1+/ genotypes were used as controls
for studying cortical cell dispersion. In these mice, gal-expressing
cells in the neocortex exhibited cell dispersion patterns seen in
normal chimeras (Tan et al., 1998). Radial columns of cells extending
across the full cortical depth were seen in Dab1+/ chimeras, suggesting that
wild-type neurons migrate normally, despite an environment of cells
heterozygous for Dab1 (Fig.
2A). In contrast, the
distribution of wild-type cells in
Dab/ chimeras was unexpected, with
ectopic segregation of gal-positive cells mainly in the superficial
area and occupying a cortical rind beneath the pial surface (Fig.
2B, arrows). Deeper into the cortex, a
minor but still substantial fraction of gal-positive cells was
diffusely intermingled with Dab1/
cells, making up the bulk of the cortical tissue underneath the densely
packed wild-type cells (Fig. 2B,D).
Despite the uneven distribution, the gal-positive cells in both deep
and superficial areas appeared to share a radial dispersion pattern
with parallel registration of lateral boundaries (Fig.
2B, inset). In strong chimeras, radial
columns were not visible, probably because of the merging of
neighboring columns (Fig. 2C,D). All
Dab1/ chimeras displayed the intense
packing of gal-positive Dab1+/+ cells
into a dense superficial band, resembling a supernumerary cortex that
we termed a supercortex (Fig. 2C,D).
Dab1/ cells appeared to fill the
remaining cortical thickness with a non-uniform infiltration of
Dab1+/+ cells, some of which coalesced
into cellular nodules in the middle layers (Fig. 2C,
white arrows). Interestingly, the supercortex did not extend
beyond the entorhinal areas (Fig. 2C,
arrowheads). The normally cell-poor MZ, situated above the
supercortex, was invaded by a large number of cell bodies, similar to
that reported for mice lacking Reelin, Dab1, or ApoER2/VLDLR. Cells of
both genotypes were found in the MZ (Fig.
2D-F), although staining of cell nuclei with
Hoescht 33342 (Fig. 3F)
revealed that the vast majority of the infiltrate were
Dab1/ cells. Thus, despite the
presence of adjacent wild-type cells, a large number of mutant cells
continued to invade the MZ as reported previously (Howell et al.,
1997b).
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Figure 2.
Dab1+/+
cells in chimeras form a supercortex
(SC) beneath the pial surface.
A, Radial columns are formed by
gal-positive cells (Dab1+/+
genotype), despite being in a heterozygous
Dab1+/ cortical environment.
B, In Dab1/
chimeras, gal-positive cells have formed a column in this weak
chimera, with the majority of the
Dab1+/+ cells segregating to the
superficial aspects of the column (arrows).
C, In this strong
Dab1/ chimera, the superficial
layers are occupied by densely packed
Dab1+/+ cells, which formed a
supercortex on top of the mutant cortex. The lateral reaches of the
supercortex appear to terminate at the entorhinal region
(arrowheads). Note a white band in the
supercortex that corresponds to the position of normal layer V neurons.
Deeper down in the mutant cortex, other
Dab1+/+ cells are found in smaller
clusters (white arrows). D, At higher
magnification, the supercortex is situated beneath the MZ. Other
gal-positive cells are also seen in mutant cortical tissue beneath
the supercortex. E, Higher magnification of strong
Dab1/ chimera shows invasion of
Dab1+/+ cells into the adjacent MZ.
F, Nuclear staining with Hoescht dye reveals a cell-rich
MZ, made up mainly by Dab1/ cell
bodies (light blue), with a smaller number of
Dab1+/+ cells (dark
blue). Scale bar: A, 145 µm; B,
455 µm; inset in B, 310 µm;
C, 510 µm; D, 110 µm;
E, F, 16 µm.
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Dab1+/+ cells in the supercortex
are Emx1-positive pyramidal neurons
To ascertain the identity of the cells making up the supercortex,
we performed double-immunofluorescent experiments using antibodies
against gal and NeuN, a marker for neurons.
The results indicate widespread immunoreactivity for NeuN
(Fig. 3A, red and double-labeled,
yellow, or orange), with only a few cells
expressing gal (green) without NeuN (Fig.
3A). Double-immunofluorescence was also performed using
antibodies against gal and Emx1, a homeoprotein transcription factor
homologous to the product of the Drosophila gene empty
spiracles (Cecchi and Boncinelli, 2000). Emx1 has been shown to
label cortical neurons (Gulisano et al., 1996) and, more specifically,
to be a marker for pyramidal neurons (Chan et al., 2001).
Widespread staining for Emx1 was confirmed across the entire cortex
(Fig. 3B, green and double-labeled,
yellow, or orange), but in the supercortex, most
of the cells were double-labeled with gal and Emx1 (Fig.
3B-D). At the bottom layer of the supercortex and parallel
to the pia (Fig. 3B,C, dotted
lines), a string of weakly positive Emx1 cells were found (Fig.
3D, arrows). The identity of these remain
unclear; however, their large cell somas and immunoreactivity for NeuN
suggests they are neurons. Within the supercortex, a small number of
Emx1-positive but gal-negative (i.e.,
Dab1/) cells were also found,
indicating contribution by host mutant cells. In the MZ overlying the
supercortex, wild-type gal-positive cells were also found, although
very few of these were weakly stained for Emx1 (Fig.
3B).
To confirm that Emx1 is a marker for radially migrating neurons, we
performed double-immunofluorescent labeling on radial columns of
wild-type chimeras. Staining with gal-antibody revealed the columnar
arrangement of lacZ-expressing cells (Fig. 3E,
red); however, staining with anti-Emx1 showed that, without
exception, all of the cells comprising the column also stained for Emx1
(Fig. 3F, yellow or orange). In light
of previous studies that have showed that radially migrating cells are
predominantly glutamatergic (Tan et al., 1998), coupled to electron
microscopic evidence that Emx1 only marks pyramidal neurons (Chan et
al., 2001), these results suggest that the Emx1-positive cells
in the supercortex are pyramidal. Additional supporting evidence was
obtained using antisera directed against GABA, a marker for
nonpyramidal interneurons. In the supercortex (Fig. 3G),
gal-positive cells (red) rarely stained for GABA
(green), but in the mutant cortex, double-positive
cells (green with yellow center) were
found (Fig. 3G, arrows). Although GABA-positive
neurons were seen in the supercortex (Fig. 3G,
arrowheads), they were invariably
Dab1/ (green). Thus,
it would appear that wild-type GABA interneurons, which normally
have a tangential mode of cell dispersion and the bulk of which originate from the underlying ganglionic eminence (Anderson et al., 1997, 2001), did not contribute to the formation of
the supercortex.
Supercortex is linked to mutant white matter by
myelinated fibers
The myelin-associated enzyme CNPase is normally found in the
plasma membrane of oligodendrocytes (Sprinkle, 1989; Thompson, 1992).
In the normal cortex, CNPase immunoreactivity is associated with
myelin-producing cells found in deeper layers and also in the
subcortical white matter (Vogel et al., 1988). This pattern of CNPase
staining was confirmed in wild-type and
Dab1/ cortices (Fig.
4A,B,
arrows), with occasional and faint fibrillar staining within
the lower cortical layers (arrowheads). In addition, oblique
fiber bundles were sporadically observed within the mutant cortex. The
superficial cortical layers clearly lacked significant immunoreactivity, with the exception of slight increased staining where
the MZ normally resides in the Dab1/
cortex (asterisk).
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Figure 4.
The supercortex is supported by extensive
myelination of its undersurface. A, In wild-type
(WT) neocortex, CNPase immunoreactivity is
confined to the white matter (WM, arrow),
with occasional staining of fibers (arrowheads) within
the gray matter. B, In
Dab1/ neocortex, CNPase staining
is present in the white matter (arrow) but is also
increased in the superficial region (asterisk) beneath
the pial surface. In addition, sporadic myelin staining is also found
within the gray matter (arrowheads). C,
In the neocortex of Dab1/
chimeras, CNPase staining is found underneath the supercortex
(arrow) and also marking myelinated fiber bundles
(arrowheads) connecting the supercortex with the mutant
white matter. Note increased packing of gal-positive
(green) cells in the supercortex.
D, In the supercortex (bracket), cells in
the upper layers only are immunoreactive for calbindin
(yellow, arrows), whereas lower
layer cells stained only for gal
(red). Mutant calbindin-positive neurons in the mutant
cortex (green) appear to possess branching
morphologies, suggestive of interneurons. Scale bar:
A-C, 75 µm; D, 40 µm.
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In contrast, the cortex of Dab1/
chimeras displayed a striking picture of CNPase immunoreactivity (Fig.
4C). Intense labeling, suggestive of widespread myelination,
was observed beneath the supercortex in a horizontal fiber tract
running parallel to the supercortex (Fig. 4C,
arrow). Many of the fibers had coalesced to form thick
bundles. Intense immunoreactivity was also observed in the white matter
and also in vertical fiber bundles traversing the
Dab1/ cortex. These vertical fiber
bundles appeared to link the subcortical fiber tracts beneath the
supercortex with mutant white matter (Fig. 4C,
arrowheads). The supercortex per se was remarkably free from
myelin staining, except for a thin margin of occasional
immunoreactivity in the superficial pial region and also in the deeper
layers of the supercortex. Because CNPase expression and activity is
dependent on the presence of nerve axons (Goto et al., 1990), it is
reasonable to assume that CNPase activity is associated with nerve
fiber tracts occupying a "white matter" region beneath the
supercortex. In this scenario, the vertical bundles of myelinated
tracts may represent nerve fibers attempting to connect the supercortex
with other subcortical structures. Indeed, the intensity of staining in
white matter of Dab1/ chimeras greatly
exceeds that of either wild-type or
Dab1/ mutants, suggesting an increased
number of myelinated fibers (Fig. 4C). However, it remains
unclear whether fiber tracts from the supercortex are functional as
corticofugal fibers emanating from supercortical neurons or
corticopetal pathways innervating the supercortex.
So far, neurons in the supercortex have been shown to be exclusively
pyramidal in composition by virtue of positive staining for Emx1 and
negative for GABA. Pyramidal neurons in the supragranular layers have
been shown to be differentially stained for calbindin, a calcium
binding protein (Demeulemeester et al., 1989; van Brederode et al.,
1991). Antibodies revealed calbindin immunoreactivity only among
neurons present in the upper half of the supercortex (Fig.
4D, yellow and arrows), whereas
the lower half supercortex neurons stained only for gal (Fig.
4D, red). Other calbindin-positive neurons
with extensive processes but belonging to the host
Dab1/ population were also seen
beneath the supercortex, and their morphology suggests them to be
mutant interneurons (Fig. 4D, green).
A subplate is formed beneath the supercortical plate
The calcium-binding protein calretinin labels the marginal zone
and subplate, derivatives of the preplate, at specific developmental stages (Vogt-Weisenhorn et al., 1994; Fonseca et al., 1995). Using an
antibody to calretinin, the cortices of E16.5 (wild-type,
Dab1/ mice, and
Dab1/ chimeras) were immunostained to
examine for the presence and localization of the subplate. In wild-type
cortices, both the MZ and the SP were labeled (Fig.
5A, arrows),
whereas in Dab1/ brains, the unsplit
preplate known as the SPP was labeled for calretinin (Fig.
5B, arrow).
Dab1/ chimeras displayed an
interesting pattern of staining: a strong band of calretinin staining
was seen in the presumptive MZ (Fig. 5D, arrow),
but in addition, there was clearly a string of calretinin-positive subplate cells underneath the "supercortical" plate (Fig.
5D, arrow). The location of the supercortical
plate in these sections was identified by examining neighboring
sections immunostained for gal (Fig. 5C,
asterisk). These results suggest that the supercortical plate has been positioned between the MZ and SP. The genotype of the SP
in Dab1/ chimeras revealed a mixture
of both mutant and wild-type cells (our unpublished
observations).
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Figure 5.
Immunocytochemistry for calretinin shows that the
preplate is split in wild-type (A) and
Dab1/ chimeras (C,
D) but not in Dab1/
(B). All tissues depicted were obtained from
E16.5 neocortices. A, Staining for calretinin, a marker
for preplate derivatives, shows normal splitting of E16.5 preplate into
MZ and SP. B, In mutant
Dab1/ embryos, the preplate fails
to split, as indicated by the calretinin-immunoreactive SPP.
C, D, In
Dab1/ chimeras, the
gal-positive supercortex (asterisk) is
bounded by calretinin-positive SP cells and the MZ. E,
F, In adjacent sections (separately stained for
gal and Dab1), gal-positive cells
in Dab1/ chimeras express Dab1 in
the supercortex (asterisk). Scale bar, 50 µm.
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Dab1 is expressed in gal-positive cells
In Dab1/ chimeras, wild-type
cells of ES cell origin are distinguished by expression of the
lacZ marker. To confirm that wild-type cells express Dab1,
we performed immunostaining using antibodies to Dab1 and
gal on adjacent sections of E16.5 neocortices. At this
stage, the "cortical plate" of the future supercortex can be
identified as a gal-positive structure underneath the
pial surface (Fig. 5E, asterisk). Staining of the
adjacent section revealed the presence of Dab1 protein in the
supercortex (Fig. 5F, asterisk), but as expected,
not in the underlying Dab1/ host.
Neurons of the supercortex are born in the correct
inside-out order
A key hallmark of defective Reelin signaling is the inversion of
cortical neurons born at different times of the neuronogenetic period
(Caviness, 1982). The thymidine analog BrdU was used to label neurons
undergoing the last round of mitotic cell division, before their
migration to the CP. Neuronal birth dating was performed for wild-type,
mutant Dab1/ (nonchimeric), and
Dab1/ chimeras to compare the
positions of neurons labeled with BrdU. In the nonchimeric
Dab1/ cortex, BrdU labeling at E12.5
and E13.5 confirmed aberrant displacement of early-born cohorts to
superficial layers (Howell et al., 1997b) (Fig.
6B, arrows).
As expected in the wild type, superficial layer labeling was observed
after BrdU injection at E17.5 (Fig. 6A). In
Dab1/ chimeras, BrdU injection at
E16.5 showed labeling of Dab1+/+ neurons
(yellow) in the upper layers of the supercortex (Fig. 6C, arrows), which is compatible with the
expected labeling position of later-born neurons. The host BrdU-labeled
Dab1/ neurons were mostly distributed
in the deeper half of the mutant cortex (data not shown), as reported
by others (Howell et al., 1997b), but in the supercortex, a very small
number of Dab1/ cells could also be
found close to the pial surface (Fig. 6C, red).
Additional confirmation that layers are inverted in the mutant cortex
is provided by the relative absence of E16.5 BrdU-labeled cells in the
area directly beneath the supercortex (Fig. 6C). Dab1/ chimeras were also injected with
BrdU at E12.5, and early born Dab1+/+
neurons (yellow) were found in the deeper layers of
the supercortex (Fig. 6D, arrows). In
these brains, the early-born mutant neurons (red) were
mostly found in the upper part of the mutant cortex, situated just
beneath the supercortex (Fig. 6D, red). A
low-power view showed that BrdU cells of
Dab1/ genotype (Fig.
6E, arrows), labeled at E12.5, had
migrated to the upper one-third of the mutant cortex, suggesting
persistent layer inversion of the mutant cells, despite the presence of
the Dab1+/+ supercortex above. Thus,
Dab1+/+ neurons born at different times in
the chimeric cortex appear to migrate to the appropriate deep and
superficial layer positions within the supercortex. Together with the
calbindin-staining data (Fig. 4D), neuronal
positioning of Dab1+/+ cells in the
supercortex appears to be independently driven and correlated with
their Dab1 genotype.
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Figure 6.
BrdU birth dating shows correct neuronal
positioning in wild-type neocortex (A) and
Dab1/ chimeric supercortex
(C, D) but incorrect positions in mutant
Dab1/ cortex
(B). A, BrdU labeling of wild-type
brains at E17.5 shows staining (arrows) in superficial
cortical layers. B, In contrast, the neocortex of mutant
Dab1/ mice shows staining in upper
layers (arrows), suggesting layer inversion of neurons
labeled with BrdU at E12.5 and E13.5. C, In
Dab1/ chimeras,
gal-positive neurons (green)
labeled with BrdU (red) at E16.5 are found to be
positioned in the upper half (yellow,
arrows) of the supercortex. This suggests appropriate
neuronal layer ordering of late-born neurons. D,
Dab1+/+ neurons labeled with BrdU at
E12.5 (yellow, arrows) are
distributed in deeper layers of the supercortex. Mutant
Dab1/ cells are also labeled with
BrdU (red) at E12.5, and they are mostly segregated in
an inverted manner in the upper parts of the mutant cortex, just
beneath the supercortex. E, Low-power view shows that
mutant Dab1/ cells labeled with
BrdU (red, arrows) at E12.5 are
inappropriately distributed to the upper one-third of the mutant cortex
(MC), despite the presence of the wild-type supercortex
above (SC). Scale bar: A,
B, 75 µm; C, D, 48 µm;
E, 24 µm.
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DISCUSSION |
Classically, the first step toward elucidation of gene function is
by targeted gene deletion. In the case of Dab1, the
spontaneous mutant scrambler and Dab1 knock-out
mice have been very useful in revealing the central role for Dab1 in
neuronal migration and cortical layering (Howell et al., 1997b; Sheldon
et al., 1997; Ware et al., 1997). Using chimeras, our results shed
additional light on Dab1 gene function in cortical
development. By considering the phenotype of
Dab1+/+ cells in the context of a
Dab1/ environment, another facet of
Dab1 gene function in the Reelin signaling pathway has been
exposed. We asked whether the function of Dab1 during cortical cell
migration and layering is cell autonomous or whether Dab1 activation
produces a non-cell-autonomous effect, for example, by regulating the
production of cell surface or extracellular molecules that may affect
the behavior of other cells. Answers to these questions will assist in
identifying the primary role of Dab1 gene function.
The assembly of multiple neuronal layers as a function of development
is a complex process, possibly requiring dynamic feedback of positional
information between early- and late-born neurons. Various models have
been proposed for the molecular control of this process, and they
invariably include the Reelin signaling pathway, but other cell surface
and cell matrix molecules may also be involved. Confirmation of
multiple pathway involvement is evidenced by layering abnormalities in
mutant mice for a number of genes, in addition to those described in
the Reelin pathway, e.g., p35, Cdk5, and 3 integrin (Gilmore et al.,
1998; Kwon and Tsai, 1998; Anton et al., 1999). To further understand
this complex process, an important step would be to demonstrate whether
or not the key players have interdependent relationships. Whereas the
activity of Reelin is clearly non-cell autonomous (Terashima et al.,
1986; Yoshiki and Kusakabe, 1998), the results presented here suggest
that Dab1 function in the neocortex is cell autonomous. This conclusion
is supported by several lines of evidence. First, the mutant
environment did not impose a mutant phenotype on the wild-type cells,
and, inversely, there was no rescue of the mutant phenotype by
wild-type cells. The capacity for radial cell dispersion by
Dab1+/+ cells in the mutant environment
appeared to be unaffected, but columns were abnormal, with the majority
of cells dispersing to the superficial part of the column. A minority
of Dab1+/+ neurons was found in the middle
and deeper layers of the composite cortex, but the vast majority of
wild-type neurons were segregated to the superficial region. Here, they
formed a supercortex beneath the pial surface. Second, there was
persistence of the mutant phenotype in the MZ, i.e., infiltration by a
large number of mutant cell bodies despite the close proximity of the
wild-type supercortex, again implying lack of rescue. Although the MZ
was densely populated by mutant cells, few wild-type cells bodies were
seen here, consistent with the notion that the wild-type preplate has
been properly split and most of the wild-type cells have withdrawn from
the MZ. This interpretation of cell-autonomous behavior is
substantiated by the presence of calretinin-positive subplate cells
underneath the chimeric supercortical plate. Evidently, despite the
presence of wild-type cells, the mutant preplate had failed to split,
otherwise a second calretinin-positive subplate would be observed below the mutant cortical plate. On the other hand, the observable subplate contains a mixture of both mutant and wild-type cells, suggesting that
some mutant cells may have responded to the subplate-splitting cues and
have assembled in the correct location with respect to the wild-type,
but not mutant, cortical plate. Most likely, mutant cell bodies seen in
the composite MZ (Fig. 2F) represent the bulk of the
ectopically displaced subplate cells from the unsplit mutant preplate
(Rice et al., 1998).
Within the supercortex, the dense packing of cells made it difficult to
distinguish between cortical layers on the basis of cellular morphology
or size, but birth-dating experiments using BrdU and staining with
calbindin, a marker of upper layer neurons (Demeulemeester et al.,
1989; van Brederode et al., 1991), indicate that they have formed in
the "correct" inside-out order. Furthermore, the presence of an
appropriately localized subplate in the embryo, and later in the adult,
the extensive myelination in the secondary "white matter," suggest
that restoration of Dab1 function has promoted assembly of a separate
cortex, despite it being sandwiched between mutant cortical tissue.
However, there were a number of unusual features in the supercortex
compared with the normal cortex. First, the supercortex was
overwhelmingly pyramidal in character as evidenced by double-staining
for Emx1. On the other hand, staining for GABA, a marker of inhibitory
neurons, revealed hardly any Dab1+/+
GABAergic cells inside the supercortex. The few GABAergic cells present
in the supercortex were invariably
Dab1/ in genotype (Fig. 3G,
arrowheads). Gauging from a similar density of mutant
GABAergic cells in the underlying mutant cortex, their presence in the
supercortex may simply reflect sharing of a common cortical space.
Although Dab1+/+ GABAergic neurons were
hardly seen in the supercortex, they were freely present beneath (Fig.
3G, arrows), mixed in with other cells of the
mutant cortex. This finding raises the possibility that the
supercortical environment, bounded between subplate and MZ, may be
especially conducive to the pyramidal phenotype (Gilmore et al., 1998).
However, this fails to account for the under-representation of
wild-type GABAergic cells in the supercortex. Perhaps interneuron migration, which is primarily tangential and mostly from
underlying striatum (Anderson et al., 1997, 2001; Tan et al., 1998),
may be unresponsive to Reelin signaling and their positions mediated by
other mechanisms that are non-cell autonomous with respect to Dab1. It
would be interesting for future studies to determine whether the
function of Dab1 extends equally to both pyramidal and nonpyramidal cells.
Another unusual feature of the supercortex was the extraordinary
compression of the layers at the expense of neuropil space. Furthermore, the supercortex was invariably positioned in the upper
part of the composite cortex with a minor but still substantial population of straggling gal-positive cells in the middle and deeper
layers. The superficial location of the supercortex may be attributable
to space constraints imposed by Dab1/
cells in an overpopulated cortex, resulting in upward pressure exerted
on the undersurface of the supercortex, preventing their downward
expansion into the deeper layers. Therefore, straggling cells, many of
which are pyramidal neurons, may also represent incomplete attempts to
fill the depth of cortical space.
Alternatively, the asymmetric placement of the supercortex may simply
reflect increased affinity of wild-type neurons for a source of Reelin
near the pial surface. This observation invites speculation for a
mechanistic role of Dab1 in neuronal positioning. One model suggests
temporary increases in cell-cell adhesion at the Reelin-cortical
plate interface as incoming neurons expressing high levels of Dab1 are
activated by Reelin (Fig. 7A).
Under normal circumstances, a momentary increase in cell adhesion would
draw the most recent arrivals past preexisting neurons (displacing them
in the process) to the MZ (Fig. 7B). After arrival near the MZ, Reelin binds to other surface molecules (e.g., 31 integrin) to initiate neuronal de-adhesion and detachment from radial glia (Dulabon et al., 2000). Reiteration of this process, involving successive waves of Dab1-expressing cells, may explain how incoming cohorts of neurons can leapfrog over older and less adhesive neurons whose Dab1 may be downregulated or degraded (D'Arcangelo et al., 1999)
(Fig. 7C). What may be the mechanism for increased cell adhesion after Dab1 activation? One lead is available from recent work
with p35-activating proteins. The p35 protein is a regulator of Cdk5
kinase, and mutations in both proteins result in abnormalities of
cortical layering. It has been demonstrated that increased kinase
activity leads to decreased cell adhesion because of disruption of
N-cadherin--catenin complexes (Kwon et al., 2000). Although a
direct link between Dab1 and p35-Cdk5 kinase remains elusive, it has
been suggested that one effect of Reelin signaling is to inhibit
p35-Cdk5 kinase activity in newly arriving neurons, leading to
increased N-cadherin-mediated adhesion (Homayouni and Curran, 2000).
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Figure 7.
A, Proposed model to account for
supercortex (SC) formation from increased cell adhesion
among Dab1 cells in a Dab1/
environment. In this model, an SP is formed beneath the supercortex
from cell-autonomous function of Dab1 cells. C-R cells,
Cajal-Retzius cells. B, C, Model
to suggest how dynamic changes in Dab1 activity and degradation may
account for correct neuronal positioning among successive waves of
migrating neurons. In this example, layer VI neurons generated at E12
are attracted to a Reelin source, leading to increasing cell adhesion
mediated by Dab1 as neurons approach the marginal zone. Dab1 activation
in layer VI cells is followed by Dab1 degradation, leading to decreased
cell-cell adhesion among layer VI neurons. At the same time, arriving
layer V neurons (generated at E14) show increasing Dab1 activity as
they respond to Reelin in the marginal zone, causing increased
cell-cell adhesion and enabling them to migrate past layer VI
cells.
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Finally, the distribution of the straggling gal-positive cells at
midcortical levels deserves additional comment. These
Dab1+/+ cells may have failed to make it
to the supercortex, suggesting that there are defects in the
Dab1/ environment that may not be
fully overcome by a Dab1+/+ genotype. This
is suggestive of non-cell-autonomous behavior mediated by structures
that normally facilitate neuronal migration. One possibility is that
radial glia in the mutant cortex may be defective, as has been reported
in reeler mice (Pinto-Lord et al., 1982; Hunter-Schaedle,
1997), causing obstruction of neuronal migration affecting both mutant
and wild-type neurons. The other possibility is that failure of
Dab1/ neurons to detach from radial
glia may have caused a structural blockade imposed by malpositioned
Dab1/ neurons (Dulabon et al., 2000).
However, the fact that the bulk of wild-type neurons have somehow been
able to migrate past mutant neurons would argue against a log-jam
hypothesis. Nonetheless, straggling wild-type neurons may have behaved
like mutant neurons and been blocked in their migratory journey,
perhaps because of sharing of glial fibers with mutant neurons that
failed to detach. Thus, although the main conclusion of the present
study points to a cell-autonomous role for Dab1, it needs to be
tempered by the possibility of non-cell-autonomous behavior for neurons
that do not insert into the supercortex.
| |
FOOTNOTES |
Received Nov. 29, 2000; revised Aug. 9, 2001; accepted Aug. 16, 2001.
This work was supported by an Institute block grant from the National
Health and Medical Research Council. We thank Frank Weissenborn
for expert technical assistance, Rachael Parkinson and Renee Mason for
making the chimeras, and Chris Job for stimulating discussions.
Correspondence should be addressed to Seong-Seng Tan, Developmental
Neurobiology Laboratory, Howard Florey Institute, The University of
Melbourne, Parkville 3010, Victoria, Australia. E-mail:
stan{at}hfi.unimelb.edu.au.
| |
REFERENCES |
-
Anderson SA,
Eisenstat DD,
Shi L,
Rubenstein JLR
(1997)
Interneuron migration from basal forebrain to neocortex: dependence on Dlx genes.
Science
278:474-476[Abstract/Free Full Text].
-
Anderson SA,
Marin O,
Horn C,
Jennings K,
Rubenstein JL
(2001)
Distinct cortical migrations from the medial and lateral ganglionic eminences.
Development
128:353-363[Abstract].
-
Angevine JB,
Sidman RL
(1961)
Autoradiographic study of cell migration during histogenesis of the cerebral cortex in the mouse.
Nature
192:766-768[Medline].
-
Anton ES,
Kreidberg JA,
Rakic P
(1999)
Distinct functions of 3 and V integrin receptors in neuronal migration and laminar organization of the cerebral cortex.
Neuron
22:277-289[Web of Science][Medline].
-
Caviness Jr VS
(1982)
Neocortical histogenesis in normal and reeler mice: a developmental study based upon [3H]thymidine autoradiography.
Brain Res
256:293-302[Medline].
-
Caviness Jr VS,
Sidman RL
(1973)
Time of origin or corresponding cell classes in the cerebral cortex of normal and reeler mutant mice: an autoradiographic analysis.
J Comp Neurol
148:141-151[Web of Science][Medline].
-
Cecchi C,
Boncinelli E
(2000)
Emx homeogenes and mouse brain development.
Trends Neurosci
23:347-352[Web of Science][Medline].
-
Chan C-H, Godinho LN, Thomaidou D, Tan S-S, Gulisano M, Parnavelas
JG (2001) Emx1 is a marker for pyramidal neurons
of the cerebral cortex. Cereb Cortex, in press.
-
D'Arcangelo G,
Miao GG,
Chen SC,
Soares HD,
Morgan JI,
Curran T
(1995)
A protein related to extracellular matrix proteins deleted in the mouse mutant reeler.
Nature
374:719-723[Medline].
-
D'Arcangelo G,
Nakajima K,
Miyata T,
Ogawa M,
Mikoshiba K,
Curran T
(1997)
Reelin is a secreted glycoprotein recognized by the CR-50 monoclonal antibody.
J Neurosci
17:23-31[Abstract/Free Full Text].
-
D'Arcangelo G,
Homayouni R,
Keshvara L,
Rice DS,
Sheldon M,
Curran T
(1999)
Reelin is a ligand for lipoprotein receptors.
Neuron
24:471-479[Web of Science][Medline].
-
Demeulemeester H,
Vandesande F,
Orban GA,
Heizmann CW,
Pochet R
(1989)
Calbindin D-28K and parvalbumin immunoreactivity is confined to two separate neuronal subpopulations in the cat visual cortex, whereas partial coexistence is shown in the dorsal lateral geniculate nucleus.
Neurosci Lett
99:6-11[Web of Science][Medline].
-
Dulabon L,
Olson EC,
Taglienti MG,
Eisenhuth S,
McGrath B,
Walsh CA,
Kreidberg JA,
Anton ES
(2000)
Reelin binds 31 integrin and inhibits neuronal migration.
Neuron
27:33-44[Web of Science][Medline].
-
Fonseca M,
del Rio JA,
Martinez A,
Gomez S,
Soriano E
(1995)
Development of calretinin immunoreactivity in the neocortex of the rat.
J Comp Neurol
361:177-192[Web of Science][Medline].
-
Gilmore EC,
Ohshima T,
Goffinet AM,
Kulkarni AB,
Herrup K
(1998)
Cyclin-dependent kinase 5-deficient mice demonstrate novel developmental arrest in cerebral cortex.
J Neurosci
18:6370-6377[Abstract/Free Full Text].
-
Goldowitz D,
Cushing RC,
Laywell E,
D'Arcangelo G,
Sheldon M,
Sweet HO,
Davisson M,
Steindler D,
Curran T
(1997)
Cerebellar disorganization characteristic of reeler in scrambler mutant mice despite presence of reelin.
J Neurosci
17:8767-8777[Abstract/Free Full Text].
-
Goto K,
Kurihara T,
Takahashi Y,
Kondo H
(1990)
Expression of genes for the myelin-specific proteins in oligodendrocytes in vivo demands the presence of axons.
Neurosci Lett
117:269-274[Medline].
-
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 in the mouse.
Eur J Neurosci
8:1037-1050[Web of Science][Medline].
-
Hawkes R,
Beierbach E,
Tan S-S
(1999)
Granule cell dispersion is restricted across transverse boundaries in mouse chimeras.
Eur J Neurosci
11:3800-3808[Medline].
-
Hiesberger T,
Trommsdorff M,
Howell BW,
Goffinet A,
Mumby MC,
Cooper JA,
Herz J
(1999)
Direct binding of Reelin to VLDL receptor and ApoE receptor 2 induces tyrosine phosphorylation of disabled-1 and modulates tau phosphorylation.
Neuron
24:481-489[Web of Science][Medline].
-
Homayouni R,
Curran T
(2000)
Cortical development: Cdk5 gets into sticky situations.
Curr Biol
10:R331-R334[Web of Science][Medline].
-
Howell BW,
Gertler FB,
Cooper JA
(1997a)
Mouse disabled (mDab1): a Src binding protein implicated in neuronal development.
EMBO J
16:121-132[Web of Science][Medline].
-
Howell BW,
Hawkes R,
Soriano P,
Cooper JA
(1997b)
Neuronal position in the developing brain is regulated by mouse disabled-1.
Nature
389:733-737[Medline].
-
Howell BW,
Herrick TM,
Cooper JA
(1999)
Reelin-induced tryosine phosphorylation of disabled 1 during neuronal positioning.
Genes Dev
13:643-648[Abstract/Free Full Text].
-
Howell BW,
Herrick TM,
Hildebrand JD,
Zhang Y,
Cooper JA
(2000)
Dab1 tyrosine phosphorylation sites relay positional signals during mouse brain development.
Curr Biol
10:877-885[Web of Science][Medline].
-
Hunter-Schaedle KE
(1997)
Radial glial cell development and transformation are disturbed in reeler forebrain.
J Neurobiol
33:459-472[Web of Science][Medline].
-
Kwon YT,
Tsai LH
(1998)
A novel disruption of cortical development in p35(
 /) mice distinct from reeler.
J Comp Neurol
395:510-522[Web of Science][Medline]. -
Kwon YT,
Gupta A,
Zhou Y,
Nikolic M,
Tsai LH
(2000)
Regulation of N-cadherin-mediated adhesion by the p35/Cdk5 kinase.
Curr Biol
10:363-372[Web of Science][Medline].
-
Ogawa M,
Miyata T,
Nakajima K,
Yagyu K,
Seike M,
Ikenaka K,
Yamamoto H,
Mikoshiba K
(1995)
The reeler gene-associated antigen on Cajal-Retzius neurons is a crucial molecule for laminar organization of cortical neurons.
Neuron
14:899-912[Web of Science][Medline].
-
Pinto-Lord MC,
Evrard P,
Caviness VS
(1982)
Obstructed neuronal migration along radial glial fibers in the neocortex of the reeler mouse: a Golgi-EM analysis.
Dev Brain Res
4:379-393.
-
Rakic P
(1974)
Neurons in rhesus monkey visual cortex: systematic relation between time of origin and eventual disposition.
Science
183:425-427[Abstract/Free Full Text].
-
Reese BE,
Necessary BD,
Tam PPL,
Faulkner-Jones B,
Tan S-S
(1999)
Clonal expansion and cell dispersion in the developing mouse retina.
Eur J Neurosci
11:2965-2978[Web of Science][Medline].
-
Rice DS,
Curran T
(1999)
Mutant mice with scrambled brains: understanding the signaling pathways that control cell positioning in the CNS.
Genes Dev
13:2758-2773[Free Full Text].
-
Rice DS,
Sheldon M,
D'Arcangelo G,
Nakajima K,
Goldowitz D,
Curran T
(1998)
Disabled-1 acts downstream of Reelin in a signaling pathway that controls laminar organization in the mammalian brain.
Development
125:3719-3729[Abstract].
-
Rossant J,
Spence A
(1998)
Chimeras and mosaics in mouse mutant analysis.
Trends Genet
14:358-363[Web of Science][Medline].
-
Shindler KS,
Roth KA
(1996)
Double immunofluorescent staining using two unconjugated primary antisera raised in the same species.
J Histochem Cytochem
44:1331-1335[Abstract].
-
Senzaki K,
Ogawa M,
Yagi T
(1999)
Proteins of the CNR family are multiple receptors for Reelin.
Cell
99:635-647[Web of Science][Medline].
-
Sheldon M,
Rice DS,
D'Arcangelo G,
Yoneshima H,
Nakajima K,
Mikoshiba K,
Howell BW,
Cooper JA,
Goldowitz D,
Curran T
(1997)
Scrambler and yotari disrupt the disabled gene and produce a reeler-like phenotype in mice.
Nature
389:730-733[Medline].
-
Sprinkle TJ
(1989)
2'3'-cyclic nucleotide 3'-phosphodiesterase, an oligodendrocyte-Schwann cell and myelin-associated enzyme of the nervous system.
Crit Rev Neurobiol
4:235-301[Web of Science][Medline].
-
Sturm KS,
Berger CN,
Zhou SX,
Dunwoodie SL,
Tan S-S,
Tam PPL
(1997)
Unrestricted lineage differentiation of parthenogenetic ES-cells.
Dev Gene Evol
206:377-388.
-
Tan S-S,
Williams EA,
Tam PPL
(1993)
X-chromosome inactivation occurs at different times in different tissues of the post-implantation mouse embryo.
Nat Genet
3:170-174[Web of Science][Medline].
-
Tan S-S,
Kalloniatis M,
Sturm K,
Tam PPL,
Reese BE,
Faulkner-Jones BE
(1998)
Separate progenitors for radial and tangential cell dispersion during development of the cerebral neocortex.
Neuron
21:295-304[Web of Science][Medline].
-
Terashima T,
Inoue K,
Inoue Y,
Yokoyama M,
Mikoshiba K
(1986)
Observations on the cerebellum of normal-reeler mutant mouse chimera.
J Comp Neurol
252:264-278[Web of Science][Medline].
-
Thompson RJ
(1992)
2'3'-cyclic nucleotide-3'-phosphohydrolase and signal transduction in central nervous system myelin.
Biochem Soc Trans
20:621-626[Web of Science][Medline].
-
Trommsdorff M,
Gotthardt M,
Hiesberger T,
Shelton J,
Stockinger W,
Nimpf J,
Hammer RE,
Richardson JA,
Herz J
(1999)
Reeler/Disabled-like disruption of neuronal migration in knockout mice lacking the VLDL receptor and ApoE receptor 2.
Cell
97:689-701[Web of Science][Medline].
-
van Brederode JF,
Helliesen MK,
Hendrickson AE
(1991)
Distribution of the calcium-binding proteins parvalbumin and calbindin-D28k in the sensorimotor cortex of the rat.
Neuroscience
44:157-171[Web of Science][Medline].
-
Vogel US,
Reynolds R,
Thompson RJ,
Wilkin GP
(1988)
Expression of the 2',3'-cyclic nucleotide 3'-phosphohydrolase gene and immunoreactive protein in oligodendrocytes as revealed by in situ hybridization and immunofluorescence.
Glia
1:184-190[Medline].
-
Vogt-Weisenhorn DM,
Weruaga-Preito E,
Celio MR
(1994)
Localization of calretinin in cells of layer I (Cajal-Retzius cells) of the developing cortex of the rat.
Dev Brain Res
82:293-297[Medline].
-
Ware ML,
Fox JW,
Gonzalez JL,
Davis NM,
Lambert de Rouvroit C,
Russo CJ,
Chua Jr SC,
Goffinet AM,
Walsh CA
(1997)
Aberrant splicing of a mouse disabled homolog, mdab1, in the scrambler mouse.
Neuron
19:239-249[Web of Science][Medline].
-
Yoshiki A,
Kusakabe M
(1998)
Cerebellar histogenesis as seen in identified cells of normal-reeler mouse chimeras.
Int J Dev Biol
42:695-700[Medline].
Copyright © 2001 Society for Neuroscience 0270-6474/01/21228798-11$05.00/0
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ABSTRACT
INTRODUCTION
