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First published online 20 September 2006
doi: 10.1242/dev.02566
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1 RIKEN Center for Developmental Biology, 2-2-3 Minatojima Minamimachi, Chuoku,
Kobe 650-0047, Japan.
2 Department of Cell and Developmental Biology, Graduate School of Biostudies,
Kyoto University, Kitashirakawa, Sakyo-ku, Kyoto 606-8502, Japan.
3 Nakagawa Initiative Research Unit, RIKEN Frontier Research Program, 2-1
Hirosawa, Wako 351-0198, Japan.
4 Graduate School of Biological Sciences, Nara Institute of Science and
Technology, 8916-5, Takayama, Ikoma, NARA, 630-0192, Japan.
5 Division of Molecular and Developmental Biology, National Institute of
Genetics, Mishima, Shizuoka, Japan.
* Author for correspondence (e-mail: nakagawas{at}riken.jp)
Accepted 4 August 2006
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SUMMARY |
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 TOP SUMMARY INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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Key words: Horizontal cell, Retina, Cadherin, Dendrite, Transposon, Chicken
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INTRODUCTION |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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;
Jan and Jan, 2003;
Kim and Chiba, 2004;
Scott and Luo, 2001;
Whitford et al., 2002).
Studies investigating the mechanism of dendrite formation at the molecular
level have largely relied on technologies that enable the reproducible
visualization of dendritic morphology of particular neurons and the
simultaneous manipulation of gene functions in the same cells (reviewed by
Scott and Luo, 2001;
Jan and Jan, 2003). Hence,
most of the in vivo analyses have been carried out in invertebrates such as
Drosophila, an organism that allows advanced molecular and genetic
manipulations (reviewed by Scott and Luo,
2001; Jan and Jan,
2003). As for higher vertebrate species, our knowledge is largely
limited to that obtained from in vitro culture systems (reviewed by
Whitford et al., 2002).
Therefore, a model system that enables us to analyze the molecular mechanisms
of dendritic morphogenesis directly in vivo has been awaited. We accordingly
explored an alternative higher vertebrate model system that allows us to
induce the expression of exogenous genes in particular neurons and
simultaneously visualize the fine morphology of these cells.
Among the molecules known to control dendritic morphogenesis, we have been
focusing on the cadherin family of adhesion molecules. Cadherins mediate
Ca2+-dependent cell-cell adhesion, and endow cells with homophilic
adhesiveness in a subtype-specific manner
(Takeichi, 1995).
Immunoelectron microscopic studies have revealed that cadherins, as well as
their cytoplasmic regulator catenins, are localized at synaptic junctions
(Uchida et al., 1996;
Fannon and Colman, 1996). In
cultured hippocampal neurons, cadherins control the morphogenesis and
stability of dendritic spines (Abe et al.,
2004; Okamura et al.,
2004; Togashi et al.,
2002; Tanaka et al.,
2000). In hippocampal slice cultures, cadherins also regulate
synaptic plasticity during LTP (Tang et
al., 1998; Bozdagi et al.,
2000). All of these studies strongly support the view that
cadherins regulate synapse formation in the nervous system (reviewed by
Shapiro and Colman, 1999;
Takeichi and Abe, 2005;
Uemura, 1998).
Drosophila N-cadherin (DN-cadherin)-deficient mutants show a
variety of abnormalities, including aberrant fasciculation and misrouting of
axons in their larval central nervous system
(Iwai et al., 1997). In
DN-cadherin mutant allele-bearing flies that survive to the adult
stage, the synaptic architecture of their nerve terminals is disorganized
(Iwai et al., 2002). Mosaic
analysis of mutant cells also revealed that DN-cadherin is required
for correct target selection and synapse formation of photoreceptor cell axons
(Lee et al., 2001;
Nern et al., 2005;
Prakash et al., 2005;
Ting et al., 2005).
DN-cadherin also controls refinement of the glomerulus-specific
dendrite projection of olfactory projecting neurons
(Zhu and Luo, 2004). As for
vertebrate studies, N-cadherin mutant mice or fish exhibit gross abnormalities
in their early neuroepithelial structures
(Erdmann et al., 2003;
Lele et al., 2002;
Malicki et al., 2003;
Masai et al., 2003;
Radice et al., 1997), which
subsequently cause a number of secondary effects on neuronal morphogenesis.
Therefore, it is essential to manipulate cadherin activity in a cell type- and
stage-specific manner to fully address its functions in the nervous
system.
In the present study, we investigated the role of cadherins in the dendritic morphogenesis of horizontal cells in the developing chicken retina. To do this, we introduced a novel, transposon-mediated gene transfer system that enables conditional expression of exogenous genes. We show that the perturbation of cadherin function decreased the dendritic field size of horizontal cells, while leaving axonal elongation unaffected. We also show that cadherin was necessary for the proper termination of dendritic processes onto photoreceptor cells, as well as for the accumulation of synaptic markers at their contact points. We thus provide compelling evidence showing that cadherin is required for dendrite morphogenesis and synapse formation in the developing vertebrate nervous system.
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MATERIALS AND METHODS |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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pT2K-CAGGS: the EF promoter of pT2KXIG
(Kawakami et al., 2004) was
replaced by the CAGGS promoter (Niwa et
al., 1991).
pT2K-rtTA-M2: cDNA fragment of M2, a modified tetracycline-responsive
activator, was excised from rtTA-M2
(Urlinger et al., 2000) and
subcloned into the pT2K-CAGGS.
pT2K-BI-mEGFP: the EF promoter of pT2KXIG was removed and replaced by the
expression cassette derived from pBI-EGFP (CLONTECH), which contains TRE, two
minimal promoters of CMV, and poly A signals; subsequently, the EGFP insert
was replaced with mEGFP (generated by Ichii Tetsuo, RIKEN CDB, Japan) that
contains a membrane localization signal of GAP43
(Okada et al., 1999) at
N' terminal.
pT2K-BI-mEGFP-myc: the myc-tagged cassette from pCS2+MT (a kind gift from
D. Turner) was excised and subcloned into pT2K-BI-mEGFP.
pT2K-BI-mEGFP-cNcad-myc and pT2K-BI-mEGFP-cN390
-myc: coding sequences
without stop codon of full-length N-cadherin (cNcad) and cN390
(Fujimori and Takeichi, 1993)
were amplified the by PCR and subcloned into pT2K-BI-mEGFP-myc.
For generating the cRNA probe of N-cadherin, we amplified the cDNA fragment corresponding to 1149-1991 of the coding sequence by PCR and subcloned it into pCRII (Invitrogen).
In ovo electroporation
In ovo electroporation was performed as previously described
(Kubo et al., 2005). For
co-electroporation experiments, plasmids at the same concentration were mixed
at the same ratio (1:1:1 or 1:1). For inducing the conditional expression, we
injected 400 µl of doxycycline (0.25 µg/ml in PBS) into the amnion of
each embryo every 24 hours from E12 to E16.
Tissue preparation and immunohistochemistry
The retinas were dissected and fixed for 1 hour at room temperature in 4%
paraformaldehyde in saline buffered with HEPES (10 mM, pH=7.4). After the
retinas had been washed three times in TBS supplemented with 1 mM
CaCl2 (TBS-Ca), the associated pigment epithelium was carefully
removed, and retinal fragments of 0.5 cm2 were dissected from the
central region of the retina devoid of the optic nerve head. This region was
kept constant for all analyses. The explants were incubated for 1 hour in a
blocking solution containing 5% fetal calf serum (FCS) in TBS-Ca supplemented
with 0.5% Triton-X 100 and 0.04% sodium azide (TBST-Ca). They were
subsequently incubated for 3 days at 4°C with the primary antibodies
diluted in the blocking solution, and thereafter washed three times with
TBST-Ca (30 minutes each time). The samples were then incubated in the
blocking solution for 30 minutes followed by 1 day in a secondary antibody
solution, and then washed again three times for 20 minutes each time with
TBST-Ca. For section immunostaining, the fixed retinas were cryoprotected in
20% sucrose/TBS-Ca, embedded in OCT compound (Tissue-Tek), and sectioned at 16
µm using a cryostat. The sections were mounted on APS-coated glass slides
(Matsunami, Japan) and processed using a standard protocol. In situ
hybridization and double immunostaining was carried out according to the
protocol previously described (Tanabe, 2004). In brief, after washing in situ
probes, the sections were incubated in a mixture of anti-Prox1 antibody and
alkaline phosphatase-conjugated sheep anti-DIG antibody (Roche) for 1 hour,
washed three times for 20 minutes each time with TBST-Ca, and subsequently
incubated with Alexa488-conjugated anti-rabbit IgG. After washing the
secondary antibody, in situ hybridization signals were visualized with
HNPP-FastRed (Roche) according to the manufacturer's instructions and
immediately observed under the fluorescent microscope. The antibodies used
were the following: rat monoclonal anti-GFP (1:1000, clone GF090R,
Nakalaitesque, Japan), mouse monoclonal anti-myc (1 µg/ml, clone 9E10,
Developmental Studies Hybridoma Bank), rabbit anti-myc (1:500, Sigma C3956),
rabbit anti-N-cadherin (1:1000) (Matsunaga
et al., 1988), rabbit anti-Prox1 (1:500, AB5475, Chemicon), rabbit
anti-GluR4 (1 µg/ml, AB1508, Chemicon), mouse monoclonal anti-Pax6
(partially purified, 1:200, Developmental Studies Hybridoma Bank), Alexa
488-conjugated anti-rat IgG (0.5 µg/ml, Invitrogen), Cy3-conjugated
anti-mouse IgG (0.5 µg/ml, Chemicon), Alexa 647-conjugated anti rabbit IgG
(0.5 µg/ml, Invitrogen), biotinylated peanut agglutinin (1 µg/ml, B1075,
Vector Laboratory) and Alexa 594-conjugated streptavidin (0.5 µg/ml,
Invitrogen).
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RESULTS |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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).
However, the conventional method of in ovo electroporation, which is usually
carried out at embryonic day 1.5 (E1.5), fails to retain the transgene into
late developmental stages (reviewed by
Nakamura et al., 2004) (Y.T.,
unpublished). We therefore used an Ac-like transposon Tol2, which
originated from medaka fish Oryzias latipes
(Koga et al., 1996;
Kawakami, 2005)
(Fig. 1A). Co-introduction of a
plasmid vector expressing the Tol2 transposase (T2TP) and a plasmid
that encodes a gene cassette flanked by the Tol2-cis sequence (Tol2)
results in the incorporation of the latter gene cassette into the host genome,
thus enabling stable gene expression in fish
(Kawakami et al., 2000;
Kawakami et al., 2004), ES
cells (Kawakami and Noda,
2004) and chicken embryos (Y.T., unpublished). To induce exogenous
gene expression in a stage-specific manner, we employed the
tetracycline-mediated conditional gene expression system
(Gossen et al., 1995). We thus
co-electroporated the optic vesicles with three different plasmids
(Fig. 1A): the first plasmid
transiently expresses the Tol2 transposase; the second plasmid
carries a Tol2-flanked gene cassette that expresses the mutated tetracycline
repressor rtTA-M2 (Urlinger et al.,
2000) under the control of the CAG promoter
(Niwa et al., 1991); and the
third plasmid carries a Tol2-flanked gene cassette that expresses
membrane-targeted EGFP (mEGFP) under the control of the tetracycline
responsive element (TRE, Fig.
1A) (Y.S. and Y.T., unpublished). The rtTA-M2 is a transactivator
that binds the TRE sequence in the presence of the tetracycline analogue
doxycycline (DOX) (Urlinger et al.,
2000). No background expression was observed at any time point we
observed (from E2 to E16) in the absence of DOX (data not shown). At E16, 14
days after the electroporation with these three plasmids and 24 hours after
the addition of DOX, we observed that mEGFP signals are predominantly
localized to a subset of cells in the retina: horizontal cells, Müller
cells and a subpopulation of amacrine and retinal ganglion cells
(Fig. 1B). With the method
described above, only the cells that have integrated both of the Tol2-flanked
gene cassettes into the genome express mEGFP upon the addition of DOX. This
stochastically infrequent event leads to the advantage of a small population
of cells being labeled. In addition, the horizontal cells, which we
specifically focused on in this study, were positioned away from the
Müller cell columns (Fig.
1B, see Fig. S1 in the supplementary material), facilitating
observations of entire cell morphology at the single-cell level. The identity
of the horizontal cell was confirmed by its position and morphology, as well
as by the expression of molecular markers including Prox1 and Pax6
(Belecky-Adams et al., 1997;
Edqvist and Hallbook, 2004;
Tanabe et al., 2004)
(Fig. 1B,C).
Embryonic chicken retinas have 3 morphologically distinct subtypes of horizontal cells
We next decided to use our novel method to investigate the roles of
cadherins in dendritic morphogenesis. Before performing the functional
analysis of cadherin, we examined the normal morphology of horizontal cells in
the retina. We visualized the horizontal cells by overexpressing mEGFP, and
then observed whole-mounted retina from the scleral (outer) side using
confocal microscopy. As the retinal pigment epithelium (RPE) becomes tightly
associated with the neural retina and hampers fluorescence observations in
post-hatched chicks, we carried out our analysis at E16 and earlier, the
stages during which we could still separate the RPE from the associating
neural retinas. Although E16 is still an embryonic stage, synaptic ribbons and
vesicles are already present in the outer plexiform layer
(Hughes and LaVelle, 1974),
suggesting that basic neural connecting patterns are already established.
|
).
We were able to identify all of these subtypes by mEGFP expression. Type I
cells possessed axons and bushy dendrites that covered a small dendritic field
of 230 µm2 on average (n=9, s.d.=60 µm2)
(Fig. 2A). The mean length of
their axons was 82 µm (n=7, s.d.=9.2 µm). Type II cells were
axonless, flattened cells with large, wavy dendrites covering a dendritic
field of 700 µm2 on average (n=7, s.d.=74
µm2) (Fig. 2B).
Type III cells were also axonless, and showed a `candelabrum-shaped'
morphology with vertically traversing dendritic branches that were usually
single up to their termination zone (Fig.
2C). The terminals of these dendrites were enlarged, forming
bulge-like structures (Fig.
2C); the average dendritic area was 200 µm2
(n=7, s.d.=32 µm2). To examine the ratio of each
horizontal cell subtype, we examined 270 horizontal cells from 12 independent
retinal regions. Among them, 93 cells (34%) belonged to the type I horizontal
cells, and 68 (25%) and 109 (40%) cells were classified into type II and III
horizontal cells, respectively. Our results are consistent with the
aforementioned previous observations on the adult chicken retina
(Genis-Galvez et al.,
1979).
We then confirmed the expression pattern of N-cadherin, a major cadherin
subtype expressed in the nervous system
(Redies and Takeichi, 1993;
Redies et al., 1993;
Hatta and Takeichi, 1986), in
the horizontal cells. At E16, N-cadherin mRNA was ubiquitously expressed in
all the cells in the neural retina (magenta in
Fig. 2E) except in the
presumptive Müller cells in the inner nuclear layer
(Fig. 2E). To confirm that all
the horizontal cells expressed N-cadherin, we performed double labeling for
Prox1 protein and N-cadherin mRNA. As expected, N-cadherin mRNA signals were
observed in the cytoplasm of all the horizontal cells expressing Prox1
(Fig. 2E).
Horizontal cell dendrites undergo morphological changes during embryonic development
To determine whether the dendrites of horizontal cells undergo changes in
their morphology during development, we fixed retinas at three different time
points, E9, E12 and E14, and observed the morphology of the mEGFP-expressing
cells (Fig. 3). At E9,
EGFP-expressing horizontal cells could be found in the scleral side of the
inner nuclear layer; their identity was confirmed by an intense expression of
the horizontal cell marker Prox1 (Fig.
3A). At this stage, a number of filopodia-like processes were
observed projecting from the cell body
(Fig. 3B), some of which
projected vertically (Fig. 3B,
arrowheads). All of the cells we observed possessed similar morphology,
preventing us from discriminating the three subtypes of the horizontal cells.
At E12, two types of horizontal cells became distinguishable. The first cell
type possessed a long process reminiscent of an axon
(Fig. 3C, arrow), suggesting
that these cells were precursors of type I horizontal cells. Their dendrites
were less branched compared with those of mature cells
(Fig. 3C,
Fig. 2A). Cells of the second
type elongated their horizontal dendrites bidirectionally, which were randomly
oriented in relation to the centroperipheral axis of the eye
(Fig. 3D). These cells lacked
axon-like processes, suggesting that they were precursors of type II or type
III cells. The vertically protruding processes were also prominent at this
stage (arrowheads in Fig.
3C,D). By E14, the vertical processes with strong mEGFP expression
had disappeared, and dendritic processes had further elongated horizontally to
form branching patterns characteristic of the three types of horizontal cells
(Fig. 3E-G). However, the
bulges of dendritic terminals of type III cells had not yet been generated;
instead, growth cone-like structures were occasionally observed at the tips of
the dendrites (arrows in Fig.
3G).
|
). Although PNAL was expressed in all of the cone cells at the
outer segment level (Fig. 4A,
right), the signals were observed in only a subset of cone cells at the
pedicle level: the synaptic site of cone photoreceptor cells
(Fig. 4A, left). These
PNAL-positive pedicles were located at the scleral side of the outer plexiform
layer, which was assumed to correspond to those of the `double-cone' cells
according to a previous EM study (Morris
and Shorey, 1967). To confirm this interpretation, we carefully
examined serial confocal sections. At the level of the outer segment, double
cones were easily identified by their `8' shape morphology revealed by
N-cadherin immunostaining (Fig.
4A). The outlines of the double-cone cells could be traced through
adjacent confocal sections, which eventually met a pair of adjacent weak and
strong PNAL signals at the pedicle level
(Fig. 4A, left). In all cases,
the strong PNAL signals (small arrows in
Fig. 4A) were surrounded by
hoof-like weak PNAL signals (arrowheads in
Fig. 4A). Double cones consist
of two types of cone cells: principal and accessory cone cells
(Morris and Shorey, 1967).
Considering that the principal-cone pedicles are larger than the
accessory-cone pedicles (Morris and
Shorey, 1967), the weak and strong PNAL signals presumably
corresponded to the pedicles of the principal and accessory cones,
respectively (Fig. 4K).
|
). The punctate signals of GluR4 were found
along the dendritic terminals of type I horizontal cells, overlapping with
their mEGFP signals (Fig. 4D),
suggesting that these dendritic terminals formed synapses with the double-cone
cells. On the other hand, the dendritic terminals of type III horizontal cells
specifically projected to the portion of the double-cone pedicles with strong
PNAL signals (Fig. 4I,K), which
corresponded to the accessory-cone pedicles. They did not arborize but formed
bulge-like structures that overlapped with the strong PNAL signals
(Fig. 4I). GluR4 was
co-localized with the mEGFP signals on the terminals of the type III
horizontal cell dendrites (Fig.
4J), suggesting that they also formed synapses with accessory-cone
pedicles. The dendrite terminals of type II horizontal cells did not project
to the PNAL-positive sublamina in the outer plexiform layer
(Fig. 4E-G); instead, they
terminated in the vitreal (inner) side of the outer plexiform layer, where rod
spherules and single cone pedicles are predominantly distributed
(Morris and Shorey, 1967).
However, we could not determine the targets of the type II horizontal cells,
because of a lack of molecular markers that clearly distinguish between rod
spherules and single-cone pedicles at this optical resolution. Similarly, we
could not clarify whether type I and type III horizontal cell dendrites also
projected to other synaptic sites than the double-cone pedicles in the
PNAL-negative inner region of the outer plexiform layer.
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,
Fig. 5B)
(Fujimori and Takeichi, 1993).
It has been established that cN390 inhibits a wide range of classic
cadherin subtypes that possess a catenin-binding region (CBR)
(Togashi et al., 2002;
Fujimori and Takeichi, 1993).
As a control, we used myc-tagged full-length N-cadherin as well as another
form of the mutant molecule that lacks both the extracellular domain and the
catenin-binding region (CBR), leaving the juxtamembrane domain (JM) intact
[cN390 CBP(-), Fig. 5B].
We induced exogenous expression at E12 after the formation of the initial
dendritic processes, and examined the cellular morphology after 4 days at E16.
The simultaneous expression of mEGFP and the myc-tagged molecules was
confirmed by double-immunostaining for mEGFP and the myc-tag on sections
(Fig. 5C-E). To confirm the
overexpression of cN390 did not cause non-specific toxic effects on
cell survival, we made transverse sections that crossed the center of randomly
selected mEGFP-expressing clones. The average number of labeled horizontal
cells within 200 µm width retina on the sections did not change
significantly by the overexpression of cN390 [3.6 in the control retina
(n=12, s.d.=0.9) and 3.7 in the retina expressing cN390
(n=10, s.d.=0.8), P>0.75]. The differentiation of the
three subtypes of horizontal cells occurred more or less normally, as we could
distinguish the cell types by their characteristic morphology
(Fig. 6E-J; see Fig. S2E-H in
the supplementary material). However, the dendritic processes covered much
smaller areas in the cells expressing cN390 than did the control ones
expressing the full-length N-cadherin (Fig.
6E-J). These effects were not observed in the cells expressing
cN390 CBP(-) (see Fig. S2E-H in the supplementary material;
Fig. 6K). Statistical analysis
showed that expression of cN390 significantly reduced the dendritic
field size of all three types of horizontal cells (P<0.000008 for
type I, P<0.000027 for type II and P<0.000058 for type
III cells; n is shown in Fig.
6I). However, the length of axons of type I horizontal cells was
not affected (Fig. 6A,E,
P>0.94; n is shown in
Fig. 6L). These results suggest
that cadherin controls the global dendritic growth or stabilization, but not
axon elongation, of horizontal cells.
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inhibited early phases of dendritic
growth or de-stabilized pre-formed dendritic branches, we examined the
morphology at an earlier stage, E14, 48 hours after the induction of the
dominant-negative molecule (Fig.
7). At this time point, it was difficult to discriminate type II
cells from type III cells by their morphology when they expressed cN390
(Fig. 7E-G). Therefore we
compared the dendritic field size of the horizontal cells with axon (type I)
or without axon (type II or type III cells). The expression of cN390
significantly reduced the size in both cell population (P<0.00004
for type I, P<0.001 for type II or type III cells; n is
shown in Fig. 7H), suggesting
that cadherin function was required during the initial phase of dendrite
morphogenesis to increase the field size.
Perturbation of cadherins did not affect local target selections but impaired synapse formation
We then studied the projection patterns of dendritic terminals of the
horizontal cells expressing cN390. Interestingly, a substantial number
of dendrite terminals of type I and type III horizontal cells projected to the
PNAL-positive sublamina in the outer plexiform layer (arrows in
Fig. 8A,C). In addition, the
local target selections occurred more or less normally; i.e. the terminals of
type I horizontal cells converged into double-cone pedicles
(Fig. 8A,H) and those of type
III cells projected to accessory-cone pedicles with strong PNAL signals
(Fig. 8C,J). The number of
dendrite terminals projecting to the correct cone pedicles from a single
neuron, however, decreased upon overexpression of cN390
(P<0.000065 for type I cells and P<0.0000034 for type
III cells; n is shown in Fig.
9A); however, the relative number of dendrite terminals per
dendritic field area did not change significantly (P>0.08 for type
I and P>0.80 for type III cells,
Fig. 9B). These observations
suggest that, despite the decreased size of the dendritic field, their
terminals could find their correct targets within the local area they resided.
The stratification of type II horizontal cells was also fairly normal, and
their dendrite terminals projected to the vitreal side of the outer plexiform
layer, avoiding the PNAL-positive sublamina
(Fig. 8B). However, the
morphologies of the dendrite terminals were severely affected; many of them
covered only small areas of the double-cone pedicles, exhibiting irregular
terminal shapes (arrows in Fig.
8H,J; compare their terminal areas and morphologies with those in
Fig. 8D,F), as confirmed by
quantification (Fig. 9C).
Furthermore, accumulation of the synaptic marker GluR4 faded in the cone
pedicles receiving dendrite terminals expressing cN390
(Fig. 8I,K); in extreme cases,
GluR4 signals disappeared almost completely from the pedicles (arrows in
Fig. 8I,K;
Fig. 9D). In the cases when
dendrite terminals occupied only part of the double-cone pedicles, GluR4
signals decreased there locally (arrowheads in
Fig. 8I,K;
Fig. 9D). We could not observe
any of these phenotypes in the cells expressing cN390 CBP(-) (see Fig.
S3 in the supplementary material).
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DISCUSSION |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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on the development of horizontal cell
dendrites. We found that cadherin controlled distinct steps of dendrite
morphogenesis as well as synapse formation, as discussed below.
The overexpression of cN390 decreased the dendritic field area of
the horizontal cells. During normal development, filopodia-like processes were
commonly observed at earlier stages when the dendrites were actively growing
(E9-14), which disappeared at later stages such as E16. We can assume that the
outgrowth of dendritic processes requires their anchoring to other cells or
substrates. Considering that cadherin activity is essential for the firm
attachment of filopodial processes to other neurites, as found in the case of
axon- to-dendritic spine interactions
(Togashi et al., 2002;
Abe et al., 2004), cadherin
probably sustains the extension of horizontal cell dendrites by providing them
with the ability to anchor to other cells. In fact, cells expressing the
dominant-negative cadherin retained a hairy morphology with a number of
filopodia-like processes, which might have failed to stabilize the attachment
to other cells or substrates. It remains unclear whether cadherin activity is
required for the maintenance of horizontal cell dendrites. As the confocal
observation of dendrite morphology was available during only a limited period
of time (E16 and earlier), before the formation of tight association between
the pigment epithelium and the photoreceptor cells, it was technically
demanding to investigate the effect of the dominant-negative cadherin at later
stages. Time lapse observation using cultured retinal explants may provide an
alternative way to clarify if cadherin function is necessary for the extension
of the dendritic processes or for the stabilization of the established
branches. The anchorage of the dendritic processes may be mediated by the
homophilic interactions of cadherins expressed by the horizontal cells with
those expressed by other cells; however, we are currently ignorant of the
precise cell types to which developing horizontal cell dendrites attach. As
all three types of neurons comprising the outer plexiform layer express
N-cadherin, the dendrites of horizontal cells potentially interact with
photoreceptor cells and bipolar cells, as well as with those of the same cell
type via the N-cadherin homophilic bindings. Further studies that specifically
block cadherin functions in each cell type will clarify with which cells
horizontal cells interact during the extension of their dendrites.
|
,
suggesting that horizontal cell axons navigate independently of cadherin
activity. Interestingly, a previous study showed that overexpression of a
dominant-negative cadherin inhibits outgrowth of axons and dendrites of
retinal ganglion cells in the Xenopus retina
(Riehl et al., 1996). This
discrepancy might be explained by the different timing of exogenous gene
expression. In Xenopus, the first expression of exogenous genes
introduced by lipofection is observed in undifferentiated retinal progenitor
cells (Riehl et al., 1996;
Holt et al., 1990), whereas we
induced the expression in postmitotic neurons that had finished their vertical
migration across the retinal layers. Cadherin might thus be necessary for an
early step of the outgrowth of axons, but dispensable for their elongation.
Alternatively, the axon growth may be regulated in a cell type-specific
manner, and a cadherin-dependent cell-adhesion system is differentially
operating at the tips of the growth cone depending on the cell type. In fact,
horizontal cell axons are unique in the sense that they do not generate
neuronal impulses (Nelson et al.,
1975) and hence may use different molecular machineries for
elongation.
Although cN390 decreased the dendritic field size, local target
selection of the dendrite terminals took place to some extent. For example,
dendrites of type II horizontal cells correctly terminated in the vitreal side
of the outer plexiform layer and never invaded the PNAL-positive sublamina
located scleraly. In addition, a substantial number of dendrite terminals of
type I and type III horizontal cells correctly found their targets in the
double-cone pedicles, although the number of terminals decreased almost
proportionally to the reduction in the dendritic field of each cell. We, thus,
speculate that cadherins, at least the subtypes that can be inhibited by the
dominant-negative construct used here, are not required for the local target
selection of dendrite terminals in horizontal cells but that they control
global extension or stabilization of the dendrites as discussed above.
Postsynaptic marker accumulation was largely impaired in the cells
expressing cN390. This observation is consistent with a series of
preceding in vitro studies suggesting the essential role of cadherins in
synapse formation (reviewed by Shapiro and
Colman, 1999; Uemura,
1998; Takeichi and Abe,
2005). The defective synaptic contacts may partially be
responsible for the suppressed extension of dendrites. For example, a
reduction in the mechanical forces required to maintain the synaptic contacts
may allow a contraction of dendrites, leading to smaller dendritic fields.
Furthermore, normal synaptic activities might be essential for maintaining the
normal morphology of dendrites, as found in the case of other neurons
(reviewed by Wong and Ghosh,
2002). Taken together, we can propose that dendrite morphogenesis
of horizontal cells are regulated by at least two cadherin-dependent
processes, one during the early dendrite extension stages and the other after
synaptic contact formation.
A number of experimental methods have been established to introduce
exogenous genes into the retina, such as retroviruses
(Turner and Cepko, 1987;
Price et al., 1987),
adenoviruses (Jomary et al.,
1994; Bennett et al.,
1994), in vivo lipofection
(Holt et al., 1990) and in
vivo electroporation (reviewed by Nakamura
et al., 2004). All of them, except for retroviruses, allow only
transient expression, restricting the analysis to early developmental periods.
In addition, the episomal, transient expression often hampers the
specificities of various promoters (Sive
et al., 2000), making it difficult to perform cell type-specific
expression, let alone stage-specific conditional expression. As for
retroviruses, making high-titer virus is time-consuming and even impossible,
especially when the insert length exceeds the capacity of the virus vector.
The transposon-mediated gene transfer system we have used in this study
provides a cell type-specific, inducible overexpression system with
conventional plasmid expression vectors. The use of different tissue-specific
promoters enabled the induction of exogenous genes in distinct cell types
(K.T. and S.N., unpublished), providing further opportunity to examine the
function of specific genes in the nervous system. We believe the experimental
method used in this study offers a conventional and alternative experimental
approach to the genetic method (Zong et
al., 2005) for analyzing gene function at the single-cell level in
the vertebrate nervous system.
Supplementary material
Supplementary material for this article is available at
http://dev.biologists.org/cgi/content/full/133/20/4085/DC1
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ACKNOWLEDGMENTS |
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