Department of Molecular Neurobiology, Institute of Development, Aging and
Cancer, and Graduate School of Life Sciences, Tohoku University, Seiryo-machi
4-1, Aoba-ku, Sendai 980-8575, Japan
* Present address: Laboratory for Neuronal Circuit Development, Brain Science
Institute, RIKEN, 351-0198 Japan
Author for correspondence (e-mail:
nakamura{at}idac.tohoku.ac.jp)
Accepted 22 October 2002
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SUMMARY |
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Key words: groucho, En, Cell fate, Lamination, Retinotectal projection, Remodeling
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INTRODUCTION |
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Although the chick optic tectum also displays laminar structure (La Vail
and Cowan, 1971a), the manner of postmitotic neuronal cell migration varies
slightly from that in the cerebral cortex
(La Vail and Cowan, 1971b;
Gray et al., 1988
;
Gray and Sanes, 1991
). La Vail
and Cowan (La Vail and Cowan,
1971b
) reported that the tectal laminae were formed as a result of
three distinct migration waves; the first wave forms the inner lamina, the
second one forms the outer lamina and the last one forms the middle lamina
(La Vail and Cowan, 1971b
). In
the central part of the tectum, the first and the second waves overlap
chronologically; the first was between E3 and E5 and the second was between E4
and E7. The third wave occurred between E6 and E8.
Grg4 belongs to the Gro/Grg/TLE family and functions as a
transcriptional repressor by binding to specific transcriptional factors
(Cavallo et al., 1998;
Roose et al., 1998
) (reviewed
by Fisher and Caudy, 1998
;
Chen and Courey, 2000
;
Courey and Jia, 2001
). In our
previous paper we showed that Grg4 is expressed in the prosencephalon
and the mesencephalon at E2, and suggested that Grg4 antagonizes
isthmus organizing activity to set the anterior limit of the tectum
(Sugiyama et al., 2000
).
Further study has revealed that Grg4 expression ceases during E3 and
E4, reappearing at E5. After E5, Grg4 expression is seen in the
ventricular layer. In the spinal cord, Grg is implicated in
determining the fate of neuronal progenitor cells along the ventrodorsal axis
(Muhr et al., 2001
). As
migration patterns change around E5 (La
Vail and Cowan, 1971b
), we proposed that Grg4 might be
involved in changing the fate of tectal postmitotic cells. To test this
hypothesis, we first examined the migration pattern of tectal postmitotic
cells by pulse-labeling the tectal neuroepithelium with lacZ. Our
results demonstrated that the migration pattern changed around E5, coinciding
with the re-expression of Grg4. Next, we used a retroviral vector and
the morpholino antisense oligonucleotide to perform gain- and loss-of-function
experiments. We concluded that Grg4 imbibes ventricular cells with a
late migratory fate. In addition, lamina g, which is normally unreceptive to
the invasion of retinal axons (Yamagata
and Sanes, 1995
), was disrupted by the misexpression of
Grg4, allowing retinal axons to invade the deeper laminae.
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MATERIALS AND METHODS |
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Introduction of plasmids and morpholino antisense
oligonucleotide
Pulse-labeling of the neuronal progenitor cells of the optic tectum was
achieved by transfecting at E3, E5 or E6 with the lacZ expression
vector, pMiwZ (Suemori et al.,
1990) using in ovo electroporation
(Funahashi et al., 1999
;
Momose et al., 1999
;
Nakamura et al., 2000
;
Summerton, 1999
).
Misexpression of Grg1 and Grg4 was achieved by
electroporation on E2 embryos (at stage 9-11) with retroviral plasmid vector.
Expression of the gene of interest may spread from the originally transfected
cells in virus-sensitive embryos by infection with the virus. In
virus-insensitive embryos, misexpression is limited to the descendents of the
originally transfected cells. The entire coding regions of Grg1 and
Grg4, as well as the 5'-region of Grg4
(Grg4-5') with an HA-tag sequence
(Sugiyama et al., 2000), were
inserted into Cla12 adapter plasmids. Each ClaI fragment of cDNA
(
2.4 kb) was then subcloned into the retroviral vector RCAS(BP)B
(Hughes et al., 1987
). The
RCAS(BP)B-AP vector, into which alkaline phosphatase (AP) had been subcloned,
served as a control (Cepko et al.,
2000
). To increase the survival rate of embryos, we used the
tungsten microelectrode as the cathode and the platinum electrode as the
anode. A square pulse of 7-8 V for 25 mseconds was delivered and the
electroporator was charged twice (Momose
et al., 1999
).
Retrovirus infection was also performed. The retroviral fluid for
RCAS(BP)B-En2, into which chick En2 had been subcloned
(Shigetani et al., 1997), was
injected into the lumen of the mesencephalon in virus-sensitive embryos at E2
(stage 8-9).
The sequence of fluorescein-labeled morpholino antisense oligonucleotide for Grg4 (Gene Tools) was 5'-GCGGATCATC-CACGCCGCTTCGGG-3'. The supplier's recommended control oligonucleotide, 5'-CCTCTTACCTCAGTTACAATTTATA-3', was used. A 1 mM solution of control or Grg4 morpholino was injected into the aqueductus mesencephali at stage 28, and electroporation was carried out as described above. As fluorescein-labeled morpholino is positively charged, it was introduced on the cathode side.
In situ hybridization, immunohistochemistry and histochemistry
In situ hybridization on sections was performed as described by Ishii
(Ishii et al., 1997).
Hybridization was carried out at 65°C. Digoxigenin (DIG)-labeled RNA
probes of Grg1 (corresponding to amino acids 2-255), Grg4
(Sugiyama et al., 2000
),
ER81 (kind gift from Dr Matsunaga), Lim1
(Matsunaga et al., 2000
),
Sox2, Sox14 (Uchikawa et al.,
1999
) and Cash1
(Jasoni et al., 1994
) were
used.
The following primary antibodies were used for immunohistochemistry; anti-ß-galactosidase (rabbit polyclonal, ICN), anti-Hu-C/D, 16A11 (monoclonal, Molecular probes), anti-HA, 3F10 (monoclonal, Roche), anti-HA (rabbit polyclonal, Upstate), anti-neurofilament, 3A10 (monoclonal, Developmental Studies Hybridoma Bank (DSHB)), anti-Parvalbumin, PARV-19 (monoclonal, Sigma), anti-Glutamate (rabbit polyclonal, Sigma), anti-NgCAM, 8D9 (monoclonal, DSHB), anti-En, 4D9 (monoclonal, DSHB) and anti-gag, AMV-3C2 (monoclonal, DSHB). Cy3- or Alexa 488-conjugated goat anti-mouse, anti-rabbit or anti-rat antibodies were used as secondary antibodies (Jackson, Molecular Probes, Rockland).
Sections of RCAS(BP)B-AP-infected embryos were processed for AP activity
(Halliday and Cepko, 1992), or
were immunostained with anti-gag antibody. For the AP reaction, endogenous AP
was inactivated by heating to 65°C for 30 minutes. Sections were then
placed in AP buffer containing 0.1 mg/ml X-phosphate
(5-Bromo-4Chloro-3-indolyl-phosphate, Roche), 1 mg/ml Nitro Blue Tetrazolium
(Roche) and 1 mM levamisole (Sigma), until the color was developed.
For nuclear staining, sections were incubated in 1-10 µg/ml DAPI (4' 6-Diamidino-2-phenylindole Dihydrochloride) in PBT and mounted in 2.3% DABCO (Sigma) in 80% glycerol.
BrdU incorporation
BrdU (Bromodeoxyuridine) solution (10 mM, Sigma) was injected into the
aqueductus of the retrovirus-infected mesencephalon at E8. Two hours after
BrdU injection, the embryos were fixed in 4% paraformaldehyde in PBS.
Incorporated BrdU was detected by the addition of monoclonal anti-BrdU
antibody (Roche), followed by incubation with Cy3-conjugated anti-mouse
secondary antibody.
Labeling of retinal axons
Retinal ganglion cells were labeled with 25% horseradish peroxidase (HRP,
Toyobo) in Hanks' buffer or with a tiny crystal of a tiny crystal of DiI
(1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine
perchlorate, Molecular Probes) at E15. The embryos were fixed in 4%
paraformaldehyde at E17. To reveal the retinal fibers targeting the deep
tectal lamina, the tecta after DiI labeling were cut into 100 µm sections
on the vibratome (Dosaka EM) and observed under a fluorescence microscope, or
the tecta after HRP labeling were cut into 100 µm section and were stained
immunohistochemically using a primary rabbit anti-HRP antibody (polyclonal,
Biogenesis) and a secondary Cy3-conjugated anti-rabbit antibody. The sections
were then immunostained with anti-gag antibody and Grg4 misexpression
was assessed.
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RESULTS |
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In the tectum at E8, most cells are postmitotic
(La Vail and Cowan, 1971b) and
five laminae are formed (Fig.
1A): two thin laminae (IV, III), a cell-filled thick lamina (II),
a fiber-rich lamina (I) and the ventricular layer. These laminae are
reorganized into 13 laminae by E12, by mechanisms that are not yet fully
understood. As it is difficult to pulse-label progenitor cells with
[3H]-thymidine or BrdU in the chick tectum, we took advantage of in
ovo electroporation techniques and transfected a lacZ expression
vector, pMiwZ. Expression from pMiwZ is transient, peak expression being
around 24 hours after electroporation
(Funahashi et al., 1999
;
Momose et al., 1999
). In
rapidly proliferating cells, plasmid and translation products are diluted
rapidly (Funahashi et al.,
1999
). In stable cells, high levels of the introduced gene product
are still maintained at 2 weeks after electroporation
(Aihara and Miyazaki, 1998
;
Kishimoto et al., 2002
). We
carried out electroporation with pMiwZ at E5 to check if this method could be
used to pulse-label neuroepithelial cells. By E5, many cells in the tectum are
postmitotic (LaVail and Cowan,
1971b
), but postmitotic cells pile up in the ventricular layer
until about E5 (stage 27) (Gray and Sanes,
1991
). Cells that express Hu-C/D, a marker for the early neuron,
accumulate just over the neuroepithelium as shown in the spinal cord
(Wakamatsu and Weston, 1997
).
We designated this layer as early neuronal
(Fig. 1A,B). Two hours after
electroporation at E5, the lacZ-positive cells were restricted to the
neuroepithelium and were not seen in the Hu-C/D-positive early neuronal layer
(Fig. 1B), indicating that in
ovo electroporation with pMiwZ could be used for pulse-labeling of
neuroepithelial cells.
First, we carried out electroporation at E3 (stage 16-18). At E6 (stage 29), labeled cells were found in laminae II and I (Fig. 1C). In lamina I, the labeled cells extended their fibers to migrate to their destination. At E8, the cells that had been labeled at E3 were found in lamina I (37%), upper lamina II (24%), lamina III (12%) and lamina IV (10%). Deeper within lamina II, labeled cells were hardly found (7%, Fig. 1D,E), suggesting that lamina II should be divided into two subregions: upper lamina II and deeper lamina II.
The cells labeled at E6 (stage 29-30) were found in the deeper lamina II (32%) and lamina I (16%) by E8 (Fig. 1F), but were hardly found (4-5%) in the upper laminae (i.e. laminae IV-IIu). Many labeled cells stayed in the ventricular layer (40%). The fact that cells labeled at E6 had colonized into the deeper region of lamina II, but not into the upper region, supports the proposition that lamina II is composed of two sublaminae.
As the migration behavior was different between the cells that were labeled around E3 and those that were labeled around E6, we focused on the behavior of cells that were labeled in between. We carried out electroporation at E5 with pMiwZ and looked at localization of labeled cells at E8. As expected, labeled cells studded entire laminae (Fig. 1G). The results indicate that the migration pattern of postmitotic cells in the tectum changes around E5. We designated those that migrate before E5 as early migratory cells, while those that migrate after E5 were referred to as late migratory cells. At E5, the tectal neuroepithelium may be in a transitory state and be composed of a mixture of early and late migratory cells.
At E12, we could distinguish 13 laminae: SO, SGFS (a/b, c, d, g, h, i, j), SGC, SAC, SGP, SFP and the ventricular layer. Most cells that were labeled at E3 were found in two distinct zones: some were in the deeper laminae such as the SGC (30%) and SAC (11%), while others were in the upper laminae such as laminae a-d (25%) and g (17%) of the SGFS (Fig. 1H,I). Comparison of the pattern of distribution of the labeled cells at E8 and E12 after electroporation at E3 indicates that lamina I at E8 may be reorganized into deeper laminae (SGC and SAC), and that laminae IV-IIu at E8 may be reorganized into the upper laminae (a-d and g of SGFS) at E12.
The majority of cells labeled at E6 were found in laminae i/j (45%), and h (11%) of the SGFS at E12 (Fig. 1J). This result, together with that seen at E8 indicates that lamina IId at E8 is reorganized into laminae i/j and h of the SGFS at E12. Labeled cells were also found in the SGC (9%) and SAC (8%). These cells may be those that are still migrating toward the destination, as they extend radial processes. Thus, the SAC and SGC may be composed of early migratory cells.
Expression of Grg4 and Grg1 during tectal
lamination
Previously, we have reported that Grg4 is expressed in the
mesencephalon and prosencephalon at E2, where it plays an important role in
the boundary formation and rostrocaudal polarity formation of the tectum by
repressing En2 (Sugiyama et al.,
2000; Ye et al.,
2001
). The expression of Grg4 ceases during E3-E4 and
then reappears at E5. We examined the precise expression pattern of
Grg4 to determine whether it plays a role in regulating the migration
pattern of postmitotic cells.
At E4 (stage 22), Grg4 expression transiently disappeared from the tectal anlage (Fig. 2B). Grg4 was re-expressed at late E5 (stage 28) in the ventricular layer in a gradient rostrocaudally: rostral high and caudal low (Fig. 2C,D). Because of this gradient, the level of Grg4 expression at the rostral part of the tectum at late E5 is similar to that at the caudal part at E6 (stage 29, Fig. 2D,E). Although Grg4 expression was seen throughout the ventricular layer, cells that strongly expressed Grg4 gathered at the outermost zone, as the early neuronal layer. Double-staining for Grg4, using in situ hybridization, and for Hu-C/D, using immunohistochemistry, shows that cells that are strongly positive for Grg4 also express Hu-C/D (Fig. 2E). This result indicates that these cells are postmitotic early neurons that are waiting to migrate. At the central part of the tectum at E6 (stage 29), Grg4-expressing cells were detected in the ventricular layer and in laminae II and I (Fig. 2F). The intensity and the number of Grg4-expressing cells were increased at E6.5 (stage 30, Fig. 2G). Expression in the ventricular layer continued to E14 (stage 40, Fig. 2H,I). Expression in laminae II and I was weakened after E7 (stage 31). At E8 (stage 34), Grg4 expression was only slightly observed in the upper laminae (Fig. 2H), while at E14 (stage 40), Grg4 expression was observed in lamina d of the SGFS (Fig. 2I, I').
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We also examined the expression pattern of Grg1. Grg1 was continuously expressed in the ventricular layer from E2 to E14 (Fig. 2J-M). Expression was visible throughout the whole mantle layer before late E6 (stage 30, Fig. 2K), but was restricted to the deeper lamina II by E8 (stage 34, Fig. 2L). Its expression was again visible within entire laminae by E14 (stage 40, Fig. 2M).
En2 expression was detected at late E5 (stage 28) in an opposite gradient to that of Grg4: rostral low and caudal high (Fig. 2N,O). En2 expression then disappeared from the rostral side, being completely absent by E7 (stage 31).
Effect of Grg4 misexpression on tectal lamination
As the reappearance of Grg4 expression and the change in migration
pattern of postmitotic cells occur at late E5 (stage 28), we suspected that
Grg4 might be responsible for the fate change of the postmitotic
cells. We carried out misexpression of Grg4 by in ovo
electroporation, in which proviral plasmid vector that contained RCAS-Grg4
(Hughes et al., 1987) was
electroporated into virus-sensitive embryos at E2 (stage 9-11). As a control,
proviral plasmid that contained RCAS-AP was also electroporated. Misexpression
in the neuroepithelium expands by secondary infection with the retrovirus in
virus-sensitive embryos (Fig.
3A,B). At E12, in the RCAS-AP-infected tecta, 13 laminae [SO, SGFS
(a-d, g-j), SGC, SAC and the ventricular layer] were clearly distinguished by
staining with DAPI (Fig. 3A,C) and with anti-neurofilament antibody (Fig.
3F), as is seen in tecta without any treatment. In
RCAS-Grg4-infected tecta, the tectal wall was thinner at the
Grg4-misexpressing region (n=4/4,
Fig. 3B). DAPI staining showed
that lamina g of the SGFS became inconspicuous, suggesting that the cells that
normally form this structure were halted in their migration
(Fig. 3D). However, lamina i/j
of the SGFS increased in thickness, indicating that more cells migrated into
lamina i/j than in the control (Fig.
3D). Immunohistochemistry with anti-neurofilament antibody showed
that the SAC and SGC were thinner than those in the controls, and that radial
neuronal fibers in lamina i/j invaded the deeper lamina that corresponds to
the SGC (Fig. 3G,G').
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Next, we looked at the effects on genes that are specifically expressed in
the laminae at E14. Parvalbumin (PV) is a Ca2+-binding protein in
GABAergic neurons and is normally expressed in cell somata and fibers of
laminae a-c, g, h and i/j of the SGFS (Fig.
3H). Within the Grg4-misexpressing region, PV-positive
cells were detected in lamina a-c, h and i/j, but were not detected in lamina
g (Fig. 3I). In the control
region, glutamate was detected in the large cells of the SGC
(Fig. 3K), and Ng-CAM was
detected immunohistochemically in axonal bundles of the SAC
(Fig. 3N), as reported
previously (Kröger and Schwarz,
1990; Yamagata et al.,
1995
). The number of glutamate-positive cells was reduced in the
Grg4-misexpressing region (right hand side of
Fig. 3L), and the region of
Ng-CAM-positive bundles in the SAC was diminished
(Fig. 3O).
In the control, transcription factors ER81 and Lim1 are expressed mainly in the laminae that are composed of late migratory cells; ER81 in laminae h and i/j of the SGFS and Lim1 in laminae i/j of the SGFS (Fig. 3Q,S). Weak expression of Lim1 was also seen in laminae a-d of SGFS (Fig. 3S). When Grg4 is misexpressed, ER81 and Lim1 expression is also seen in the laminae that correspond to the SGC and SAC (Fig. 3R,T), where cells that express ER81 or Lim1 always misexpressed Grg4 (Fig. 3R',T'). These ER81- and Lim1-positive cells in the deep laminae may have acquired the property of one of the laminae h-j. In other words, laminae h-j may have been enlarged, even admitting that some of the ER81- and Lim1-positive cells in deep laminae are still en route to their destination. In total, nine embryos were sacrificed at E14, and above mentioned effects were found in seven embryos.
The results suggest that Grg4 instructs postmitotic neuronal cells to behave as late migratory cells. Consequently, lamina g, which is formed by early migratory cells, disappears, while laminae h-j, that are formed by late migratory cells, become enlarged.
Grg4 changes the fate of early migratory cells to late
migratory cells
Our results indicated that Grg4 switched the fate of the early
migratory cells to that of late migratory cells. We confirmed this by
electroporation of retroviral vector into virus-resistant embryos at E2 (stage
9-10), where misexpression is limited to the descendents of originally
transfected cells. By E8 (stage 34), after electroporation with the RCAS-AP
vector, a lineage of transfected cells was distributed radially throughout the
tectal wall (Fig. 4A).
Quantitative examination was carried out on 17 clones from six embryos, and
showed that the cells were almost equally distributed in each lamina
(Fig. 4A). However, after
electroporation with RCAS-Grg4 (20 clones from eight embryos), the
Grg4-expressing cells were concentrated in the deeper lamina II that
is composed of late migratory cells (Fig.
4B). The labeled cells in lamina I may be those en route to their
final destination. This result indicates that Grg4 directly governs
the neural precursor cells to take the late migratory fate.
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The notion that Grg4 instructs the neuroepithelial cells to take late migratory fate was further confirmed by looking at the effects on other marker molecules. We have shown that laminae IV-III, upper lamina II and lamina I of E8 tecta are mainly composed of early migratory cells, and that deeper lamina II is mainly composed of late migratory cells. In the control tecta, Sox2 was expressed in upper lamina II and the ventricular layer (Fig. 5A, part b) and Sox14 was expressed in lamina IV and deeper lamina II (Fig. 5A, part c). ER81 was expressed in deeper lamina II. (Fig. 5A, part d). Parvalbumin (PV) was intensely expressed in upper lamina II and weakly expressed in lamina III and deeper lamina II (Fig. 5A, part e).
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In the Grg4-misexpressing region, the laminae composed of early migratory cells were specifically reduced (n=13/13, Fig. 5B, parts a-f). The number of cells in lamina I was reduced (Fig. 5Ba), and Sox2-positive and PV-positive cells in the upper lamina II almost disappeared (Fig. 5B, parts b,e). In terms of Sox-14 expression, lamina IV was nearly absent, in contrast to the control tectum (Fig. 5B, part c). However, Sox14-positive and ER81-positive cells in deeper lamina II, which is composed of late migratory cells, were rather increased compared to the control (Fig. 5B, parts c,d). The effects of Grg4 on molecular markers within each lamina indicate that Grg4 had changed the fate of early migratory cells to that of late migratory cells.
Inhibition of Grg4 function
To further investigate the ability of Grg4 to direct the fate of
neuronal precursor cells we carried out experiments using morpholino antisense
oligonucleotide (Heasman et al.,
2000). The antisense oligonucleotide was applied by
electroporation at E5 (stage 28), the stage that coincides with Grg4
re-expression (Fig. 5C, parts
a-e). Control morpholino oligonucleotide did not affect laminar formation when
observed at E8 (data not shown). Grg4 antisense morpholino
oligonucleotide increased the number of Sox2-positive cells in upper
lamina II by E8, which is mainly composed of early migratory cells
(Fig. 5C, part b). However, the
number of Sox14-positive and ER81-positive cells in deeper
lamina II was decreased (Fig.
5C, parts c,d). Expansion of upper lamina II and reduction of
deeper lamina II (n=5/7) is the opposite result to that obtained with
Grg4 misexpression. As deeper lamina II is mainly composed of late
migratory cells, we postulate that the Grg4 morpholino antisense
oligonucleotide may have prevented the neuronal precursor cells from acquiring
a late migratory fate.
In our previous study (Sugiyama et al.,
2000), it was shown that Grg4 repressed En2 expression,
and that the 5' region of Grg4 (Grg4-5') induced En2
expression in the tectum. In other words, Grg4-5' acts as a
dominant-negative form of Grg4 in tectum development. When we
misexpressed Grg4-5' by electroporation with
RCAS-Grg4-5', the results were similar to those obtained after
Grg4 morpholino antisense oligonucleotide application
(n=3/4, Fig. 5D, parts
a-d). Sox2-positive cells in upper lamina II was increased
(Fig. 5Db), and the expression
of Sox14 and ER81 in deeper lamina II was weakened
(Fig. 5D, parts c,d). Laminae
IV-III and the ventricular layer were not affected by Grg4-5'.
A remarkable feature was that deeper lamina II was reduced and lamina I
extended to lamina II (Fig. 5D,
parts a-e).
En2 is expressed in a gradient along the rostrocaudal axis from E2
(Gardner et al., 1988). The
gradient of En2 was opposite to that of Grg4 at E5 (stage 28,
Fig. 2N,O). Grg4 could
repress the expression of En2 (Sugiyama et
al., 2000
), and continued misexpression of En2 resulted
in retardation of laminar formation (Logan
et al., 1996
). We misexpressed En2 by infection with
RCAS-En2 viral fluid at E2 (stage 8-9). En2 misexpression exerted
similar effects as treatment with Grg4 morpholino antisense
oligonucleotide or misexpression of Grg4-5' (n=2/2).
In the En2-misexpressing region of the E8 tectum, the number of
Sox2-positive cells in upper lamina II was increased
(Fig. 5E, parts a,b) and the
number of Sox14-positive and ER81-positive cells in deeper
lamina II was decreased (Fig.
5E, parts c,d). The results indicate that misexpression of En2 may
restrict neuronal precursor cells to an early migratory fate.
Quantification of Sox2- and Sox14-positive
cells
It was indicated that Grg4 forced the cells to follow late migratory
pathway. We confirmed the notion by quantification on E8 embryos. At E8,
deeper lamina II consists of late migratory cells, and upper lamina II
consists of early migratory cells. Sox2 and Sox14 are good
markers for deeper lamina II and upper lamina II, respectively
(Fig. 5A, parts a,c). For
quantification, a rectangle that covers whole the wall of the tectum (one side
of the rectangle is 100 µm and parallel to the ventricular surface) was
made on the Photoshop image. The number of Sox2- or
Sox14-positive cells around lamina II and the number of total cells
in the mantle layer were counted on four samples from two embryos each.
Percentage of Sox2- or Sox14-positive cells was calculated. According to our
expectation, percentage of Sox2-positive cells, which are early
migratory cells, was reduced after Grg4 misexpression
(19.17±7.2% s.e.m. in controls, and 12.15±1.52% in Grg4
misexpressing tecta, n=4 for each,
Fig. 5F). However, treatment
with morpholino antisense oligonucleotide for Grg4 increased the
percentage of Sox2-positive cells (29.42±2.46%, n=4,
Fig. 5F).
Percentage of Sox 14-positive cells, which are late migratory cells, was increased in the Grg4 misexpressing tecta (31.33±1.26% in controls, and 46.24±2.14% in Grg4 misexpressing tecta, n=4 for each, Fig. 5F). The percentage of Sox14-positive cells was reduced after treatment of morpholino antisense oligonucleotide for Grg4 (24.49±0.88%, n=4, Fig. 5F).
Quantitative analyses clearly show that Grg4 forces neuronal precursor cells to follow late migratory pathway.
Effect of the Grg family on tectal neuronal precursors
Another groucho-related gene, Grg1, is continuously
expressed in ventricular cells from E2 and we wondered if this gene could
influence laminar formation of the tectum. Electroporation with the RCAS-Grg1
expression vector was carried out at E2. In Grg1-misexpressing
regions, the number of Sox2-, Sox14- and ER81-expressing
cells was decreased throughout laminae IV-I (n=5/5,
Fig. 6A, parts a-d).
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Drosophila Groucho and human TLE1/Grg1, were shown to
inhibit transcription of the genes for neuronal differentiation
(Paroush et al., 1994;
Fisher et al., 1996
). We
looked at effects of Grg1 and Grg4 misexpression on the
expression of the proneuronal marker gene, Cash1. Cash1 is a chick
achaete-scute homolog, and is one of the targets for Gro/Grg
(reviewed by Kageyama and Nakanishi, 1991). In the control E8 tecta,
Cash1 expression was detected in the upper ventricular layer
(Fig. 6B). In the
Grg1-misexpressing region, Cash1 expression was repressed in
the ventricular layer (Fig.
6C), indicating that Grg1 prevents ventricular cells from
expressing neuronal genes, in accordance with previous studies (reviewed by
Fisher and Caudy, 1998
;
Yao et al., 2000
). In the
Grg4-misexpressing region, however, Cash1 expression was
expanded in the ventricular layer, compared with the control
(Fig. 6D). Double-staining for
Hu-C/D and Grg4-HA showed that many Grg4-misexpressing cells
gathered at the boundary between lamina I and the ventricular layer
(Fig. 6E), where these cells
did not incorporate BrdU (Fig.
6F,G). These results indicate that Grg4 does not inhibit
ventricular cells from neuronal differentiation, but forces postmitotic cells
to acquire a late migratory fate.
Disruption of retinotectal projection by Grg4
Retinotectal projection is organized in a precise retinotopic manner.
Retinal axons run tangentially on the tectal surface to form the SO and make a
right turn to arborize in laminae a/b, d and e/f of the SGFS (LaVail and
Cowan, 1971a; Crossland et al.,
1974; Rager and von Oeyhausen, 1979;
McLoon, 1985
;
Thanos and Bonhoeffer, 1987
;
Yamagata and Sanes, 1995
).
They do not normally invade lamina g. We showed that lamina g was mainly
composed of early migratory cells and that it was disrupted by Grg4
misexpression. Thus, we were interested in the behavior of retinal axons in
the absence of lamina g. All axons emanating from a retina were labeled by
injecting the eye with a solution of HRP at E15, or a small group of axons was
labeled by placing a crystal of DiI on the retina at E15. The embryos were
fixed at E17, when remodeling of the retinal axons was complete
(Nakamura and O'Leary, 1989
).
At E17, when remodeling of retinal fibers is complete
(Nakamura and O'Leary, 1989
),
retinal axons in normal tecta were restricted to the retinorecipient laminae
superficial to the border between lamina f and g
(Fig. 7A). In eight out of 11
RCAS-Grg4-infected tecta, terminal arbors invaded deeper, beyond the disrupted
lamina g (Fig. 7B). The regions
of the tecta in which retinal axons penetrated deep to lamina g were positive
for the viral gag protein, indicating the presence of virus carrying the Grg4
gene (Fig. 7C).
|
We were then interested in the behavior of arbors in their initiation phase, and cryosections of E12 tecta were stained immunohistochemically with anti-neurofilament antibody. The SO, which consists of retinal axons, was stained heavily in both the control and Grg4-misexpressing region (Fig. 7D,E). Some fibers were branching directed inside the tectum. These fibers may be terminal arbors in their initial phase. In the control region, terminal arbors do not invade lamina g, in contrast to the Grg4-misexpressing region in which terminal arbors were able to reach lamina h.
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DISCUSSION |
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Migration of the postmitotic cells in the tectum
The migration of postmitotic cells from the ventricular layer to their
destination, is dependent on their time of birth
(LaVail and Cowan, 1971b;
Gray et al., 1988
;
Gray and Sanes, 1991
). We have
shown here that two migratory groups, designated as early and late migratory
cells, contribute to tectal architecture: the first group leaves before E5 and
the second group leaves after E5. Early migratory cells form laminae a-g of
the SGFS, SGC, SAC, SGP and SFP, while late migratory cells form laminae h-j
of the SGFS. LaVail and Cowan (LaVail and
Cowan, 1971b
) reported that there are three migration waves of
postmitotic cells that contribute to tectal laminar formation. The first-born
neurons form the SGC, SAC, SGP and SFP; and the second-born neurons formed
laminae a-g of the SGFS. These first and second waves mostly occur before E5
in a chronologically overlapping manner. The third wave occurs between E6 and
E8, and forms laminae h-j of the SGFS. Thus, these first and second waves may
correspond to the early migration in our study, and the third wave may
correspond to the late migration.
Many young neurons of the early migratory group first accumulate over the
neuroepithelium, later migrating to establish laminae II and I by E6 (see
Fig. 1)
(Gray and Sanes, 1991). Late
migratory cells remain in the ventricular layer up until E6, subsequently
migrating to intervene between laminae II and I by E8. As a result, in E8
tecta, the upper laminae (lamina IV to upper lamina II) and the deeper lamina
(lamina I) consist of early migratory cells, and the intervening lamina
(deeper lamina II) consists of late migratory cells. Thus, we propose that
lamina II actually consists of two divisions: upper lamina II and deeper
lamina II. As most neuronal precursors that form tectal laminae are
postmitotic by E8 (LaVail and Cowan,
1971b
), the five laminae of E8 become reorganized into 13 laminae
by E12. Early migratory cells stay in upper laminae (laminae a-g of the SGFS)
and deeper laminae (SGC, SAC, SGP and SFP). It must be emphasized that lamina
g was mostly composed of early migratory cells (see
Fig. 3H). The contribution of
late migratory cells to lamina g is minimal (see
Fig. 3J). Late migratory cells
were mainly found in laminae h-j of the SGFS. Comparison of late migratory
cells at E8 and E12 indicates that deeper lamina II at E8 may become
reorganized into laminae h-j of the SGFS by E12.
Role of Grg4 in directing the fate of tectal postmitotic
cells
As discussed above, the fate of postmitotic cells changes after E5. As
Grg4 is re-expressed at E5 and continues thereafter in the tectal
ventricular layer, we suspected that Grg4 might be responsible for
the fate change of the tectal postmitotic cells. As expected, Grg4
misexpression resulted in a reduction in thickness and cell number of upper
and deeper laminae of E8 tecta that are composed of early migratory cells.
Conversely, the intervening middle lamina (deeper lamina II), which is
composed of late migratory cells, was rather increased by E8. Quantitative
analysis clearly showed that the percent of cell number in deeper lamina II
was increased, but that in upper lamina II was decreased (see
Fig. 5F). At E14, the middle
laminae (laminae h-j of the SGFS), which are composed of late migratory cells,
expanded, whereas upper (lamina g of SGFS) and deeper (SGC-SFP) laminae were
reduced. Disruption of lamina g was distinct. This result is explained by the
fact that lamina g is mostly composed of early migratory cells (see
Fig. 1I,J), and supports the
idea that Grg4 confers a late migratory fate to tectal postmitotic
cells. This was further confirmed by clonal misexpression of Grg4. We
could limit the misexpression to the descendents of the originally transfected
cells by carrying out electroporation with proviral plasmid vectors on
virus-resistant embryos. Clonal misexpression of AP showed that the
AP-positive cells radially spanned between the ventricular and pial surfaces
(Gray et al., 1988;
Gray and Sanes, 1991
), whereas
clonal misexpression of Grg4 showed that the
Grg4-misexpressing cells were mainly restricted to the intervening
middle lamina (deeper lamina II). Grg4-misexpressing cells were also
found in the deeper laminae (lamina I and the early neuronal layer), where
they may still be en route to their ultimate destination.
If Grg4 does indeed instruct tectal postmitotic cells to follow
the late migratory pathway, blockade of Grg4 should exert reverse
effects. Accordingly, application of Grg4 morpholino antisense
oligonucleotide at E5 (stage 28) resulted in a decrease the number of late
migratory cells and in the thickness of the corresponding laminae. On the
contrary, the number of early migratory cells increased. The expression of
Grg4-5' has been shown to exert dominant-negative type effects
(Sugiyama et al., 2000). In
our hands, misexpression of Grg4-5' exerted similar effects as
that of the Grg4 morpholino antisense oligonucleotide. These results
support the idea that Grg4 instructs tectal postmitotic cells to
follow a late migratory pattern.
Grg1 is continuously expressed from E2 to E14. Drosophila
Groucho and human TLE1/Grg1 can inhibit transcription of neuronal genes
(Paroush et al., 1994;
Fisher et al., 1996
) and Grg1
can keep neuroepithelial cells in an undifferentiated proliferative state
(Yao et al., 2000
). This study
also showed that Grg1 could repress the generation of neuronal
precursor cells, resulting in poor differentiation of the tectal laminae. We
concluded that the effects of Grg4 do not result from suppression of
neuronal differentiation but from the conversion of early migratory cells into
late migratory cells.
The molecular events involved in deciding the fate of progenitor cells in
the ventricular layer of the spinal cord have been studied in detail (reviewed
by Jessell, 2000). Recent
studies indicate that the interactions of certain homeodomain (HD) and bHLH
proteins defined the neuronal subtype identity
(Pierani et al., 2001
;
Vallstedt et al., 2001
;
Mizuguchi et al., 2001
;
Novitch et al., 2001
).
Gro/Grg-mediated transcriptional repression probably plays a role in
regulation of the spatiotemporal expression of the homeodomain proteins in
progenitor cells (Muhr et al.,
2001
). In laminar formation of the cerebral cortex, cell fate is
decided in the ventricular layer before the progenitor cells reach their
destination (McConnell, 1988
),
although candidate molecules have not yet been identified. Our results showed
that Grg4-expressing postmitotic cells followed the late migratory
pathway, and we propose that Grg4 directs the fate of these cells to
follow the late migratory fate in tectal laminar formation.
In normal development, En2 expression (caudal high and rostral low) is in an opposite gradient to Grg4. The second phase of Grg4 expression (after E5) commences at the rostral side of the tectum, and proceeds to the caudal side. Thus, postmitotic cells at the rostral part of the tectum may acquire a late migratory fate earlier than those at the caudal part. This is reflected in the cytoarchitectural development of the tectum, with the rostral part proceeding faster than the caudal. En2 expression may force the ventricular cells to take an early migratory fate.
Lamina g of the SGFS functions as a barrier for the terminal retinal
arbors
The projection of retinal axons in retinorecipient tectal laminae has been
described in previous studies (Crossland, 1974; Rager and von Oeyhausen, 1979;
McLoon, 1985;
Thanos and Bonhoeffer, 1987
).
Retinal axons enter the tectum from the rostral part and run caudally at the
most superficial layer to form the SO. Axons make a right turn to make
terminal arborizations in lamina a-f of the SGFS at their target zone.
Temporal retinal fibers make terminal arborizations at the rostral part of the
tectum, but not before first extending beyond the target to the central part
of the tectum, where they can even make arborizations even outside of the
target area. Arborizations outside of the target zone are pruned and become
confined to the definitive target zone by E16
(Nakamura and O'Leary, 1989
).
Within the target zone, retinal arbors reach lamina f of the SGFS (La Vail and
Cowan, 1971a), but never pass through lamina g. In the
Grg4-misexpressing regions, where lamina g of the SGFS was disrupted,
retinal axons were seen to extend beyond lamina g, which may express a
nonpermissive signal (Yamagata and Sanes,
1995
). Our preliminary results indicated that refinement of
retinal projections was also disturbed in the Grg4-misexpressing
region. It has been proposed that synchronized firing of the neighboring
fibers plays an important role in refining the retinal projection
(O'Leary et al., 1986
;
Stryker and Harris, 1986
;
Cline et al., 1987
;
Kobayashi et al., 1990
;
Meister et al., 1991
;
Mooney et al., 1996
), and that
maturation of GABAergic inhibitory neurons is important for activity-dependent
refinement in the visual cortex (Fagiolini
and Hensch, 2000
). In the tectum, parvalbumin, which is expressed
in GABAergic neurons, is expressed in lamina g. Thus, there is a possibility
that lamina g is involved in refinement of the retinotectal projection. In
conclusion, lamina g of the SGFS may play important roles in the formation of
the topographic retinotectal projection; for localization of retinal axons to
the retinorecipient laminae and for refinement of the retinotectal
projection.
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ACKNOWLEDGMENTS |
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