- Email: [email protected]
03-P120 Fat4 and Dachsous1 regulate the apical membrane organization in the mouse cerebral cortex
S102
M E C H A N I S M S O F D E V E L O P M E N T 1 2 6 ( 2 0 0 9 ) S 6 7 –S 1 0 6
the actin cytoskeleton. Second, b-catenin is the intracellular
Pals1 complex in organizing the apical membrane architecture
signal transducer of canonical Wnt signaling and activates
of neural progenitor cells.
canonical Wnt target genes. b-catenin null mice die at E7.5. Since the conditional loss of b-catenin function in vivo does
doi:10.1016/j.mod.2009.06.172
not distinguish between adhesion and signaling, it is unclear whether the knock-out phenotype is due to defects in signaling, adhesion or both. Our aim is to generate conditional alleles for functionally mutant b-catenin isoforms. With the help of such signaling or adhesion impaired isoforms, we want to decipher the functional dualism of b-catenin in vivo. We will conditionally express the b-catenin from the ubiquitously active ROSA26 locus, and simultaneously delete endogenous b-catenin alleles.
03-P121 Expression pattern of proximodistal markers during avian lung development Takashi Miura Kyoto University Graduate School of Medicine, Kyoto, Japan
However, before analyzing mutant b-catenin isoforms, we have to test the suitability of our experimental approach. In a proof
The developing avian lung is formed mainly by branching
of principle experiment, we are studying whether the b-catenin
morphogenesis, but there is also a unique cystic structure, the
knock out phenotype can be rescued by expressing wild-type b-
air sac, in the ventral region. Using predictions from theoretical
catenin from the ROSA26 locus. In vitro, we can show that tar-
models, we have previously shown that the cystic structure
geted b-catenin null cells, derived from ES cells, express b-cate-
comes from fast FGF diffusion in the ventral mesenchyme tissue.
nin
cell
However, it is not still clear how the air sac tissue responds to the
morphology. Furthermore, we successfully generated mice car-
signal and whether the air sac structure comes from proximal or
rying the transgene. Currently, we are investigating the usabil-
distal structure.
on
the
membrane
and
display
wild-type
ES
ity of different Cre-mouse lines in order to generate b-catenin
In the present study, we examined several proximodistal mar-
null mice, which express wild-type b-catenin from the ROSA26
ker genes to elucidate the origin of air sac structure in avian lung.
locus. Ultimately, we want to substitute the wild-type gene with
We examined alpha smooth muscle actin and PCNA for general
our mutant isoforms and decipher the functions of b-catenin
proximo-distal markers, Shh, FGF, BMP4 and beta catenin for dis-
in vivo.
tal markers. We found that some proximal factors (alpha smooth actin) and distal factors (beta catenin, PCNA, Shh) are simulta-
doi:10.1016/j.mod.2009.06.171
neously expressed uniformly in air sac structure. This ambiguous result may reflect the fact that the air sac is evolutionally novel structure and not homologous to existing similar structure.
03-P120 Fat4 and Dachsous1 regulate the apical membrane organization
doi:10.1016/j.mod.2009.06.173
in the mouse cerebral cortex Takashi
Ishiuchi1,2, Kazuyo Misaki1, Shigenobu Yonemura1,
Masatoshi Takeichi1, Takuji Tanoue1,3
03-P122
1
RIKEN Center for Developmental Biology, Kobe, Japan
Molecular interactions and cellular events involved in palatal
2
Graduate School of Biostudies, Kyoto University, Kyoto, Japan
3
Graduate School of Medicine, Kobe University, Kobe, Japan Polarization of the plasma membrane in a cell is fundamen-
rugae development Wern-Joo Sohn1, Hye-In Jung2, Min-A. Choi3, Hitoshi Yamamoto4, Hong-In Shin3, Sang Gyu Lee1, Han-Sung Jung5, Jae-Young Kim2 1
School of Life Science and Biotechnology, Kyungpook National Univer-
tal for its proper functions. Fat and Dachsous cadherins are
sity, Daegu, Republic of Korea
known to regulate cell polarity in Drosophila, but their functions
2
in the vertebrates are poorly understood. Here we present evi-
National University, Daegu, Republic of Korea
dence that mammalian Fat4 and Dachsous1 regulate the apical
3
plasma membrane organization in the mouse embryonic cere-
Dentistry, IHBR, Kyungpook National University, Daegu, Republic of
bral cortex. In neural progenitor cells of the cortex, Fat4 and
Korea
Dachsous1 were concentrated together in a cell–cell contact area
4
positioned more apically than the adherens junction (AJ). These
University School of Dentistry, Chiba, Japan
molecules interacted in a heterophilic fashion, affecting their
5
respective protein levels. We further found that Fat4 associated
Biology, Research Center for Orofacial Hard Tissue Regeneration, Brain
and colocalized with the Pals1 complex whose ortholog in Dro-
Korea 21 Project, Oral Science Research Center, College of Dentistry, Yo,
sophila is well known to regulate the apical-basal polarity or api-
Seoul, Republic of Korea
Department of Biochemistry, School of Dentistry, IHBR, Kyungpook Department of Oral Pathology and Regenerative Medicine, School of
Department of Histology, Cytology and Developmental Anatomy, Nihon Division in Anatomy and Developmental Biology, Department of Oral
cal membrane size. Ultrastructurally, the apical junctions of the progenitor cells comprised the AJ and a stretch of plasma
Palatal rugae, epithelial ridges on secondary palatal shelves,
membrane apposition extending apically from the AJ, which
development showed the specific pattern formation with epithe-
positionally corresponded to the Fat4/Dachsous1-positive zone.
lial differentiation in mice embryonic development. Histological
Depletion of Fat4 or Pals1 abolished this membrane apposition.
and scanning electronic microscopic studies revealed the precise
These findings suggest the importance of the Fat-Dachsous1-
morphological changes of palatal rugae from E12 to E16. Cellular
M E C H A N I S M S O F D E V E L O P M E N T 1 2 6 ( 2 0 0 9 ) S 6 7 –S 1 0 6
the actin cytoskeleton. Second, b-catenin is the intracellular
Pals1 complex in organizing the apical membrane architecture
signal transducer of canonical Wnt signaling and activates
of neural progenitor cells.
canonical Wnt target genes. b-catenin null mice die at E7.5. Since the conditional loss of b-catenin function in vivo does
doi:10.1016/j.mod.2009.06.172
not distinguish between adhesion and signaling, it is unclear whether the knock-out phenotype is due to defects in signaling, adhesion or both. Our aim is to generate conditional alleles for functionally mutant b-catenin isoforms. With the help of such signaling or adhesion impaired isoforms, we want to decipher the functional dualism of b-catenin in vivo. We will conditionally express the b-catenin from the ubiquitously active ROSA26 locus, and simultaneously delete endogenous b-catenin alleles.
03-P121 Expression pattern of proximodistal markers during avian lung development Takashi Miura Kyoto University Graduate School of Medicine, Kyoto, Japan
However, before analyzing mutant b-catenin isoforms, we have to test the suitability of our experimental approach. In a proof
The developing avian lung is formed mainly by branching
of principle experiment, we are studying whether the b-catenin
morphogenesis, but there is also a unique cystic structure, the
knock out phenotype can be rescued by expressing wild-type b-
air sac, in the ventral region. Using predictions from theoretical
catenin from the ROSA26 locus. In vitro, we can show that tar-
models, we have previously shown that the cystic structure
geted b-catenin null cells, derived from ES cells, express b-cate-
comes from fast FGF diffusion in the ventral mesenchyme tissue.
nin
cell
However, it is not still clear how the air sac tissue responds to the
morphology. Furthermore, we successfully generated mice car-
signal and whether the air sac structure comes from proximal or
rying the transgene. Currently, we are investigating the usabil-
distal structure.
on
the
membrane
and
display
wild-type
ES
ity of different Cre-mouse lines in order to generate b-catenin
In the present study, we examined several proximodistal mar-
null mice, which express wild-type b-catenin from the ROSA26
ker genes to elucidate the origin of air sac structure in avian lung.
locus. Ultimately, we want to substitute the wild-type gene with
We examined alpha smooth muscle actin and PCNA for general
our mutant isoforms and decipher the functions of b-catenin
proximo-distal markers, Shh, FGF, BMP4 and beta catenin for dis-
in vivo.
tal markers. We found that some proximal factors (alpha smooth actin) and distal factors (beta catenin, PCNA, Shh) are simulta-
doi:10.1016/j.mod.2009.06.171
neously expressed uniformly in air sac structure. This ambiguous result may reflect the fact that the air sac is evolutionally novel structure and not homologous to existing similar structure.
03-P120 Fat4 and Dachsous1 regulate the apical membrane organization
doi:10.1016/j.mod.2009.06.173
in the mouse cerebral cortex Takashi
Ishiuchi1,2, Kazuyo Misaki1, Shigenobu Yonemura1,
Masatoshi Takeichi1, Takuji Tanoue1,3
03-P122
1
RIKEN Center for Developmental Biology, Kobe, Japan
Molecular interactions and cellular events involved in palatal
2
Graduate School of Biostudies, Kyoto University, Kyoto, Japan
3
Graduate School of Medicine, Kobe University, Kobe, Japan Polarization of the plasma membrane in a cell is fundamen-
rugae development Wern-Joo Sohn1, Hye-In Jung2, Min-A. Choi3, Hitoshi Yamamoto4, Hong-In Shin3, Sang Gyu Lee1, Han-Sung Jung5, Jae-Young Kim2 1
School of Life Science and Biotechnology, Kyungpook National Univer-
tal for its proper functions. Fat and Dachsous cadherins are
sity, Daegu, Republic of Korea
known to regulate cell polarity in Drosophila, but their functions
2
in the vertebrates are poorly understood. Here we present evi-
National University, Daegu, Republic of Korea
dence that mammalian Fat4 and Dachsous1 regulate the apical
3
plasma membrane organization in the mouse embryonic cere-
Dentistry, IHBR, Kyungpook National University, Daegu, Republic of
bral cortex. In neural progenitor cells of the cortex, Fat4 and
Korea
Dachsous1 were concentrated together in a cell–cell contact area
4
positioned more apically than the adherens junction (AJ). These
University School of Dentistry, Chiba, Japan
molecules interacted in a heterophilic fashion, affecting their
5
respective protein levels. We further found that Fat4 associated
Biology, Research Center for Orofacial Hard Tissue Regeneration, Brain
and colocalized with the Pals1 complex whose ortholog in Dro-
Korea 21 Project, Oral Science Research Center, College of Dentistry, Yo,
sophila is well known to regulate the apical-basal polarity or api-
Seoul, Republic of Korea
Department of Biochemistry, School of Dentistry, IHBR, Kyungpook Department of Oral Pathology and Regenerative Medicine, School of
Department of Histology, Cytology and Developmental Anatomy, Nihon Division in Anatomy and Developmental Biology, Department of Oral
cal membrane size. Ultrastructurally, the apical junctions of the progenitor cells comprised the AJ and a stretch of plasma
Palatal rugae, epithelial ridges on secondary palatal shelves,
membrane apposition extending apically from the AJ, which
development showed the specific pattern formation with epithe-
positionally corresponded to the Fat4/Dachsous1-positive zone.
lial differentiation in mice embryonic development. Histological
Depletion of Fat4 or Pals1 abolished this membrane apposition.
and scanning electronic microscopic studies revealed the precise
These findings suggest the importance of the Fat-Dachsous1-
morphological changes of palatal rugae from E12 to E16. Cellular