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From the
Received for publication, February 11, 2002, and in revised form, April 14, 2002
The human poliovirus receptor/CD155 is a
transmembrane glycoprotein belonging to the immunoglobulin superfamily.
The ectodomain of CD155 mediates cell attachment to the extracellular
matrix molecule vitronectin, while its intracellular domain
interacts with the dynein light chain Tctex-1. CD155 is a
primate-restricted gene that is expressed during development in
mesenchymal tissues and ventrally derived structures within the
CNS. Its function in adults is as yet unknown, but
significantly, CD155 is aberrantly expressed in neuroectodermal tumors.
We show that the expression of CD155 mRNA is
up-regulated when human Ntera2 cells are treated with purified Sonic
hedgehog (Shh) protein. Reporter gene expression driven by the
CD155 core promoter is activated by Shh in transient co-transfection assays. Analysis of the CD155 core promoter
indicates that an intact GLI binding site is required for Shh
activation. In addition, overexpression of Gli1 or
Gli3 potently activates reporter gene expression driven by
the CD155 core promoter. These data identify the
CD155 gene as a transcriptional target of Shh, a finding
that has significance for the normal function of CD155 during
development and the expression of CD155 in neuroectodermal tumors.
The human poliovirus receptor/CD155 is a type I transmembrane
glycoprotein belonging to the immunoglobulin superfamily (Refs. 1 and
2; for review, see Ref. 3). The CD155 gene is the founding
member of the new CD155/nectin subclass of genes within the
immunoglobulin superfamily that share a common V-C2-C2 extracellular Ig
domain signature, which also includes nectin-1, -2, -3, -4, and Tage4
(4-8). CD155 mediates cell adhesion to the extracellular matrix
molecule vitronectin (9). Its intracellular C-terminal domain has
affinity to Tctex-1, a subunit of the dynein motor complex (10). The
nectins, on the other hand, possess homotypic and heterotypic cell
adhesion activities (8, 11-15). Intriguingly CD155, nectin-1, -2, and
Tage4 serve as receptors for human viruses. CD155 is the only known
receptor for poliovirus (1, 16), while the nectins are receptors for
We have examined the expression and transcriptional regulation of the
CD155 gene to elucidate the basic biology of its gene product (22-24). Our preliminary studies have revealed that CD155 is
expressed during embryonic development with peak levels that occur
during midgestation and then decline (25). Expression is
observed in mesenchymal structures like the notochord and ventrally derived structures of the developing central nervous system
(CNS)1 such as the floor
plate, motor neurons of the ventral neural tube, and retinal ganglion
layer of the retina. The related nectin-1 (PRR1) gene has
been mapped as a locus of inherited midline dysraphism syndromes in
humans (26). Analyses of transcriptional regulation of CD155
expression demonstrated activator protein-2 (AP-2) and nuclear
respiratory factor-1 (NRF-1) to be potent regulators of CD155 transcription (23, 24). During CNS development, these transcription factors are expressed in some of the locations of CD155 expression, such as neural tube and retina, suggesting
a role for these factors in directing developmental CD155
expression (27-29).
AP-2 and NRF-1 are not expressed in ventral midline structures during
embryogenesis (27-29), an observation suggesting that our
understanding of the factors contributing toward expression of
CD155 remains incomplete. The secreted morphogen Sonic
hedgehog (Shh) plays an essential role in patterning many structures
during development, including the notochord and ventral CNS, the
developing limb, lung, and foregut (30-33). The most well
characterized location for Shh action is the anterior neural tube,
associated with notochord, floor plate, and the motoneuronal system.
Secreted Shh from the notochord induces floor plate, which in turn
becomes a source of Shh that patterns many ventral neuron types along
the entire anterior-posterior axis of the developing CNS (31). Another location of Shh action is the developing optic system (34, 35). Shh is
expressed in the retinal ganglion layer and regulates patterning and
cell number in the developing retina (34, 35). Moreover Shh is a potent
mitogen for neuronal precursors (36, 37). Interestingly Shh signaling
has been implicated in the oncogenesis of neuroectodermal tumors
because mutations in the Shh receptor Patched are observed in
medulloblastoma and basal cell carcinomas (38-41). Indeed activation
of the Shh signaling cascade, either by mutation or overexpression of
activated signaling components, has been shown to cause
medulloblastomas and basal cell carcinomas in mice (42-44).
The mechanism(s) of the morphogenic activity of Shh is currently under
investigation (45, 46). Available evidence suggests transmission of a
Shh signal to occur by the diffusible 19-kDa Shh N-terminal fragment
that is autoproteolytically cleaved from the full-length Shh protein by
the action of the Shh C terminus. The secreted Shh N-terminal fragment
binds to the Patched-Smoothened receptor complex that leads to
transduction of the Shh signal. Shh receptor activation induces GLI
proto-oncogene transcription factors, which then bind to and activate
the transcription of Shh-responsive genes (45, 46).
Since Shh is involved in the morphogenesis of embryonic structures
identified to harbor CD155 expression, we tested whether the
CD155 gene is a target of Shh signaling. Here we report the CD155 gene to be transcriptionally activated when human
Ntera-2 cells were treated with recombinant Shh protein. Transient
overexpression of Shh activated reporter gene expression driven by the
CD155 core promoter. Up-regulation of reporter expression
was dependent on an intact GLI binding site within the CD155
core promoter. According to their observed function as downstream
effectors of the Shh signal, GLI proto-oncogene transcription factors
(Gli1 and Gli3) strongly activated the
CD155 core promoter.
Cell Culture--
C3H10 T1/2 (mouse embryonic fibroblast, ATCC)
and Ntera-2 clone D1 (teratocarcinoma, ATCC) cell lines were
grown in Dulbecco's modified Eagle's medium, 10% fetal bovine serum.
Antibodies--
A rabbit polyclonal antiserum, NAEZ-8, was
raised against a recombinant protein encompassing the extracellular
domain of human CD155 fused to a hexahistidine tag. The protein was
expressed in HEK-293 cells and purified to homogeneity from culture
supernatants.2 Mouse
monoclonal antibody 5E1 against the N-terminal peptide of Shh was
obtained from the Developmental Studies Hybridoma Bank.
Shh Induction Assay and Detection of CD155, Gli1, or CD155 Reporter Assays--
Transient transfections were carried
out in the C3H10 T1/2 mouse fibroblast cell line using FuGENE 6 reagent
(Roche Molecular Biochemicals) according to the manufacturer's
instructions. Each transfection mixture contained 250 ng of the wild
type CD155 core promoter (BE, see Solecki et al.
Refs. 22-24) or Immunofluorescence--
CD155tg21 (47) E13.5 mouse
embryos were fixed for 2 h in 4% paraformaldehyde before
cryoprotection in OCT cryoprotectant (Tissue-TekTM).
Frozen sections were collected on poly-L-lysine-coated
slides, air dried, and postfixed in cold 1:1 methanol/acetone for
1 h at CD155 Promoter Activity during Embryogenesis in Transgenic
Mice--
We have recently constructed CD155 promoter-LacZ
transgenic mice using a 3.0-kb CD155 core promoter (Fig.
1A) to drive the reporter gene
(25). Histochemical examination of
To expand our studies of CD155 expression during embryogenesis we have
also examined CD155 protein expression in CD155 transgenic mice. These mice possess the entire CD155 gene, are
susceptible to poliovirus infection, and suffer a syndrome very similar
to human poliomyelitis suggesting that CD155 is expressed in the appropriate locations. Indeed CD155 protein in embryos of
CD155tg mice (ICR-PVRTg21, Ref. 47) is detectable in
a profile similar to that in the CD155 promoter-LacZ
transgenic mouse embryos. Expression was observed in the floor plate,
notochord, and sclerotome (Fig 2A) as well as the optic nerve
and chiasm (not shown). Particularly the expression pattern of CD155
within the floor plate matched that of Shh-N (Fig. 2, A-C).
We furthermore detected CD155 protein expression in the mesenchyme
surrounding the branching primordial tubules of the lung epithelium
(Fig. 3, B and C)
as well as the cartilage primordium of the developing ribs (Fig.
3D). Both tissues are known regulatory targets of the
hedgehog signaling cascade (32). It is particularly noteworthy that
CD155 was mostly concentrated in the mesenchyme surrounding the more
distal portions of the tubules precisely where Gli1 is found
and where the highest level of Shh in the adjacent lung epithelium has
been reported (32, 48).
Shh Activates Transcription of the CD155 Gene--
The fact that
Shh acts as a global regulator of gene expression in structures
associated with CD155 expression led us to test whether Shh
could directly modulate the activation of the CD155 gene.
For these experiments, we treated undifferentiated human Ntera-2 clone
D1 cells with 5 nM Shh-Np protein. Undifferentiated Ntera-2
cells possess a primitive neuroepithelial cell phenotype and are
sensitive to many signaling pathways that modulate the differentiation
and proliferation of neuronal precursor cells (49, 50). Based on
expressed sequence tag data base searches and RT-PCR
experiments, Ntera-2 cells express the Shh receptors Patched and
Smoothened and the GLI zinc finger transcription factors required for transduction of a Shh signal (data not shown). Total RNA
was isolated from treated and untreated Ntera-2 cells,
reverse-transcribed with random hexamers, and then amplified with
primer sets specific for mRNAs of CD155, the
Gli1 transcription factor (a gene known to be activated
strongly by Shh), and The CD155 Core Promoter Is Activated by Shh Signaling--
The
results of our Shh induction assay provided qualitative evidence that
CD155 mRNA is increased by the addition of Shh protein to Ntera-2 cultures, suggesting that CD155 transcription may
be activated by Shh. We next sought to determine whether the
CD155 promoter could be activated by Shh signaling. Moreover
we designed experiments to map the region(s) of the promoter that would
convey responsiveness to Shh. Examination of the CD155
promoter revealed three regions with matching GLI consensus binding
(51) sites within the 3.0-kb fragment that was used to produce our
promoter transgenic mice lines (Fig. 1A). Interestingly one
of these sites was located within the CD155 core promoter,
known to harbor many of the elements required for cell type-specific
expression of CD155. The CD155 core promoter is 280 bp in
length, possesses multiple transcriptional initiation sites, and
harbors four known cis-acting elements (termed FPI-IV, see
Fig. 1B) as determined by DNase I footprinting and
functional linker scanning mutagenesis (22-24). A GLI binding motif is
located near the 5' border within FPIII, the largest footprinted region
of the CD155 core promoter (see Fig. 1B).
We next tested whether the CD155 core promoter could be
activated by Shh signaling using a transient transfection system. C3H10
T1/2 cells were used for these experiments because Ntera-2 cells proved
difficult to transfect on a consistent basis. C3H10 T1/2 cells were
previously reported to possess the necessary cellular machinery to
transduce a Shh signal in transient transfection assays (52-55). A
CD155 core promoter/fire fly luciferase reporter construct
was co-transfected into C3H10 T1/2 cells with a full-length Shh
expression vector. Co-transfection of 5 ng of the Shh
expression vector led to a 4-fold higher level of luciferase expression
compared with cells co-transfected with the control vector (see Fig.
5A, n = 4). We
next tested whether the GLI binding motif located within FPIII was
required for activation by using a mutant CD155 core promoter/reporter construct lacking this motif, termed The CD155 Core Promoter Is Potently Activated by Gli1 and
Gli3--
The results of our transient transfection experiments
suggested that GLI transcription factors may play an important role in
mediating Shh activation of the CD155 core promoter. We
therefore tested whether GLI factors could directly activate reporter
gene expression by co-transfecting the CD155 core promoter
construct with expression vectors encoding the human Gli1 or
Gli3 cDNAs. Peak levels of activation of luciferase
expression were observed when 5 ng of the Gli1 or
Gli3 expression vectors, respectively, were co-transfected
with the CD155 core promoter construct (see Fig.
5B, n = 4). Expression of Gli1
led to a 24-fold increase in reporter gene expression, while
co-expression of Gli3 produced 18-fold activation over basal
levels (Fig. 5B). As expected, co-transfection of the
Gli1 or Gli3 expression vectors with the Temporospatial expression patterns for many cell adhesion
molecules of the immunoglobulin superfamily are consistent with functions during embryonic development. We have described activity of
the CD155 promoter and expression of CD155 protein in
anterior midline structures of the developing human CNS (25).
Similarly, in CD155tg mouse embryos, CD155 can be detected
in the notochord, ventral neural tube, optic nerve/chiasm, and
cartilage primordia such as the rib and sclerotome as well as the
mesenchyme surrounding the branching primordial tubules of the
developing lung (see Figs. 2 and 3). Shh, an important morphogen, is
expressed in many of the same locations as CD155 during development
(Refs. 30-33 and 48, and See Fig. 2). We tested the possibility that
the CD155 gene may be a transcriptional target of the Shh
signaling cascade. The CD155 core promoter harbors a
potential GLI binding site, a finding that is consistent with the fact
that many of the promoters of transcriptional targets of Shh target
genes frequently harbor binding sites for the GLI family of
transcription factors. Treatment of the human Ntera-2 cell line with
purified Shh-Np protein led to an increase of both CD155 and
Gli1 mRNAs (Fig. 4). Although the results of this
assay are qualitative in nature since they are based upon RT-PCR, they
suggest that like Gli1, the CD155 gene is a
transcriptional target of Shh signaling. Importantly this hypothesis is
supported by data indicating that the CD155 core promoter is
activated by co-transfection of a Shh expression vector and that this
activity required an intact GLI binding motif (Fig. 5). Not
surprisingly GLI proto-oncogene transcription factors themselves
(Gli1 and Gli3) directly activated the
CD155 core promoter (Fig. 5).
The observed role of Shh and GLI transcription factors in the
regulation of expression of CD155 is consistent with their association with structures associated with the developing embryo (31). Our
previous studies have dissected the cis-acting elements
required for basal activity of the CD155 core promoter and
identified their interactions with AP-2 and NRF-1 transcription factors
(22-24). The GLI binding motif located within the boundaries of FPIII
differs from the NRF-1 and AP-2 consensus binding sites in that
mutation of this motif had little effect on basal promoter activity
(24). This suggests that this cis-element may act as a
Shh-dependent enhancer within the CD155 core
promoter. Shh-dependent activation of the CD155
promoter may contribute to the observed expression profile of CD155
within embryonic structures patterned by Shh.
Shh activation of CD155 expression may be highly relevant for the
overexpression of CD155 in cancers like medulloblastoma or
glioblastoma. A peak of CD155 expression was observed during midgestation of human and transgenic mouse embryos (Ref. 25, and
see Figs. 2 and 3). Interestingly up-regulation of CD155 expression is
observed in neuroectodermal malignancy (e.g. medulloblastoma or glioblastoma), an observation suggesting that gene regulatory pathways exist in these tumors that reactivate CD155 expression (20).
Recently both Shh and the GLI transcription factors have been
implicated in the oncogenesis of neuroectodermal and cutaneous cancers
(for review, see Ref. 56). Loss-of-function mutations of the Shh
receptor Patched are found in spontaneous and familial forms of
medulloblastoma (40, 41). Indeed loss of one Patched allele reportedly
led to medulloblastoma-like lesions in the cerebellum of mice (42).
Human Gli1 was first identified because of its association
with glioblastoma (57), and the Gli1 gene has subsequently been localized near a hotspot of gene duplication in these tumors (58).
Up-regulation of Gli1 expression is commonly observed in
human medulloblastomas (56, 59) and the medulloblastoma-like lesions of
germ line manipulated mice lacking one Patched allele (42).
Up-regulation of GLI genes may be an important determinant in
carcinogenesis as constitutive overexpression of Gli1 or
Gli2 in skin leads to spontaneous basal cell
carcinomas (43, 44). In this study, we show that CD155 expression is
activated by Shh signaling and that the CD155 core promoter
is strongly activated by Gli1 and Gli3. Based on
the data presented here, Shh and GLI signaling may be the critical gene
regulatory pathway activating CD155 expression in
medulloblastoma and glioblastoma. This hypothesis is currently being
tested in our laboratory.
CD155 has been reported to mediate cell adhesion to the extracellular
matrix by a specific interaction with vitronectin (9). The pattern of
vitronectin expression during embryonic development overlaps that of
CD155, including the notochord, floor plate, and ventral neural tube
(60, 61). It is interesting to note that the vitronectin gene also is a
Shh target and that its product binds directly to Shh thereby modifying
cellular responses to Shh (62). The physiological role of the
CD155/vitronectin/extracellular matrix interaction is unclear in this
context. Given the role of vitronectin in modulating Shh responses and
the fact that CD155 and vitronectin are both expressed in locations of
Shh action, it is tempting to speculate that CD155 may not
simply represent a Shh target gene. It may be a constituent of the
cellular machinery that modulates Shh action. Interestingly nectin-1,
one of the nectin molecules related to CD155, is specifically expressed
in the floor plate.3
Examination of the upstream sequence of the nectin-1 gene deposited in
the Human Genome Database has revealed the presence of multiple GLI
binding motifs suggesting that other nectin-related molecule besides
CD155 may be expressed in the floor plate and may be regulated by Shh signaling.
We thank Dr. P. Beachy (Johns Hopkins
University) for critical discussion and providing purified Shh-Np
protein, Dr. Ken Kinzler (Johns Hopkins University) for providing the
Gli1 and Gli3 cDNAs, and Dr. Andrew McMahon
for providing the full-length Shh cDNA. The 5E1 monoclonal antibody
developed by Dr. T. Jessell was obtained from the Developmental Studies
Hybridoma Bank developed under the auspices of the NICHD, National
Institutes of Health and maintained by the University of Iowa,
Department of Biological Sciences, Iowa City, IA 52242.
*
This work was supported in part by National Institutes of
Health Grant AI39485 (to E. W.).The costs of publication of this article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
§
A member of the graduate program in Molecular and Cellular Biology,
State University of New York at Stony Brook and recipient of a grant
from the Deutscher Akademischer Austauschdienst (DAAD). To whom
inquiries should be addressed: Laboratory of Developmental Neurobiology, The Rockefeller University, 1230 York Ave., New York, NY
10021. E-mail: soleckd@mail.rockefeller.edu.
¶
Recipient of a Burroughs Wellcome Career Award. Current
address: Dept. of Molecular Genetics and Microbiology, Duke University Medical Center, Durham, NC 27710.
Published, JBC Papers in Press, April 30, 2002, DOI 10.1074/jbc.M201378200
2
R. Welker and E. Wimmer, unpublished results.
3
S. Mueller, J. Zhan, and E. Wimmer, unpublished observations.
The abbreviations used are:
CNS, central nervous
system;
Shh, Sonic hedgehog;
AP-2, activator protein-2;
NRF-1, nuclear
respiratory factor-1;
RT, reverse transcription;
E13.5, embryonic day
13.5;
FP, footprinted region.
Expression of the Human Poliovirus
Receptor/CD155 Gene Is Activated by Sonic Hedgehog*
§,¶,
,
, and
Department of Molecular Genetics and
Microbiology, School of Medicine, State University of New York at Stony
Brook, Stony Brook, New York 11794 and
** Max-Delbrück-Centrum für Molekulare Medizin,
Robert-Rössle-Strasse 10, 13092 Berlin, Germany
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
-herpesviruses (17-19). More recently CD155 has been revealed as a
tumor antigen and a potential target for therapeutic intervention as
its expression is up-regulated in neuroectodermal cancers, including
glioblastoma multiforme, medulloblastoma, and colorectal carcinoma (20,
21).
MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
-Actin
mRNA--
1 × 107 Ntera-2 clone D1 cells were
seeded into 10-cm dishes. 18 h after passage, the serum-containing
medium that was used to seed the cells was exchanged for serum-free
medium. After 12 h, purified Shh-Np protein (palmitoylated Shh-N,
a kind gift of Phil Beachy, Johns Hopkins University, Baltimore, MD)
was then added to the medium to a final concentration of 5 nM (~150 ng/ml) and incubated for 18 h. Total
mRNA was then isolated from the treated and untreated cultures.
RT-PCR was then used to analyze the levels of CD155, Gli1,
and -actin RNA within these samples. 10 µg of total RNA was used
as template for reverse transcription using Superscript II (Invitrogen)
primed with random hexamers, and the resulting first strand cDNA
was amplified in parallel using the following primers: cd155
5', 5'-cgagccatggccgccgcgtggccg-3'; cd155 3',
5'-ggtctgagtgccaggtgatttgggct-3'; Gli1 5',
5'-attggcaccatgagcccatctctggg-3'; Gli1 3',
5'-ccttcaaacgtgcacttgtgtggc-3'. The cycling parameters for
amplification were 95 °C for 30 s, 55 °C for 30 s, and 72 °C for 1 min for 30 cycles. The PCR products were then run
on a 1% agarose gel and transferred to nitrocellulose membranes, and
southern hybridization with radiolabeled probes was used to detect the
CD155-, Gli1-, or -actin-specific RT-PCR products.
Gli reporter plasmids and 5 ng of the
pcDNA3-Shh, pcDNA3-Gli1, or
pcDNA3-Gli3 expression vectors. Co-transfections were
filled in with empty pcDNA3 so that a total of 250 ng of pcDNA3
backbone plasmid would be constant for each transfection. Basal
reporter activity was determined by co-transfecting empty pcDNA3
vector alone. 18 h post-transfection cells were harvested, and
luciferase activity in the lysates of transfected cells was measured
using Luciferase Assay Reagent (Promega).
20 °C. For CD155/Shh-N double labeling sections were
blocked with M.O.M. blocking reagent (Vector Laboratories) followed by overnight incubation at 4 °C with a 1:500 dilution of CD155 antibody NAEZ-8 and 1:2 dilution of hybridoma supernatant 5E1 in M.O.M. diluent (Vector Laboratories). After 1 h of washing with
phosphate-buffered saline the sections were incubated with a 1:200
dilution of Alexa488-conjugated anti-rabbit (Molecular Probes) and a
1:500 dilution of Cy3-conjugated anti-mouse (Jackson Immuno Research)
secondary antibodies for 1 h at 37 °C. The sections were washed
extensively with phosphate-buffered saline and mounted with Immu-Mount
(Shandon, Pittsburgh, PA). CD155 single labeling was essentially done
as above except that blocking and antibody dilutions were done in
phosphate-buffered saline containing 2% normal goat serum instead of
M.O.M. blocking reagent. Images were acquired on a Zeiss Axioplan II
fluorescence microscope equipped with a model SP401 camera (Diagnostic
Instruments Inc.) and processed with Adobe Photoshop software.
RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
-galactosidase activity in
embryos harboring the CD155 promoter-LacZ transgene has
revealed that the CD155 promoter possesses elements that
direct reporter gene expression in a profile similar to the endogenous expression of CD155. -Galactosidase activity was observed
in midline structures, i.e. notochord, floor plate, and
presumptive motor neurons of the anterior horn along the
anterior-posterior axis of the transgenic embryos. In addition,
expression was seen in the developing retina, optic chiasm, and optic
nerve.
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Fig. 1.
Schematic of 5' flanking sequences of the
CD155 gene. A, schematic of 3.0-kb
CD155 promoter. A 3.0-kb fragment of genomic DNA containing
the promoter of the CD155 gene has been previously isolated
and characterized in transgenic mice (see Ref. 25 for details). This
3.0-kb genomic DNA harbors three potential GLI binding motifs, two of
which are located within a repetitive element and one that is located
within the CD155 core promoter. B, schematic of
the CD155 core promoter. Bent arrows indicate the
region of transcriptional initiation. Open box, transcribed
region; gray box, coding region of exon 1; black
ovals, locations of the DNase I footprints observed in previous
studies. The region of FPIII that harbors the GLI binding motif is
highlighted, and the GLI motif is boxed. In the
Gli construct the sequence TGGGTGGCC is replaced by a
SpeI restriction site.
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Fig. 2.
CD155 and Shh-N colocalize to the floor plate
of CD155tg mouse embryos. Transverse thoracic
sections of E13.5 embryos were double labeled for CD155 and Shh-N.
A, CD155 is expressed in floor plate, notochord, and
sclerotome. B, Shh localization to the floor plate.
C, overlay of A and B reveals
extensive overlap of CD155 and Shh-N expression patterns in the floor
plate. D, control section incubated with preimmune serum and
an unrelated mouse IgG hybridoma supernatant. Bars, 100 µm.
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Fig. 3.
CD155 expression in mouse embryonic lung
mesenchyme and developing ribs. A, phase contrast image
of a transverse section through E13.5 lung. B, the same
section stained with CD155-specific antiserum. CD155 is concentrated in
the mesenchyme surrounding the distal portion of branching primordial
tubules of the developing lung epithelium. C, a higher
magnification view of a lung tubule depicted in B. D, CD155 is highly expressed in the cartilage primordia of
developing ribs. E, an adjacent control section incubated
with preimmune serum shows no nonspecific staining in primordial rib.
B, C, and D, CD155 expression was
analyzed by indirect immunofluorescence using CD155-specific antiserum
NAEZ-8 (1:500) in combination with an Alexa488-conjugated anti-rabbit
secondary antibody (1:200). Fluorescence was visualized under
epifluorescence on a Zeiss Axioplan II microscope equipped with a
fluorescein isothiocyanate filter set. Bars, 100 µm.
-actin (an internal control for RNA loading).
Whereas RT-PCR products corresponding to CD155 and
Gli1 message could barely be demonstrated in control
cultures, abundant -actin message was readily detected (see Fig.
4). In contrast, treatment of Ntera-2
cells with 5 nM Shh-Np produced an increase in both of the
CD155- and Gli1-specific transcript RNAs, whereas
the -actin levels remained stable. Gli1 has been demonstrated to be a primary target of the Shh signaling cascade. Our
observations of an increase of the CD155 RT-PCR product in the presence of Shh suggested that the CD155 gene, like
Gli1, is a transcriptional target of the Shh signaling
cascade.
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Fig. 4.
Expression of CD155 core is
activated by Shh. Ntera-2 cells were treated with 5 nM
Shh-Np protein. After a 24-h incubation total RNA was isolated, and
CD155, Gli1, and -actin messages were analyzed by RT-PCR.
Both the CD155 and Gli1 mRNAs are activated by Shh,
while the -actin internal control remains unaffected.
Gli (see Fig.
1B for the location of the GLI binding motif and location of
the linker scanning mutant). Remarkably no activation of the Gli
construct was observed when it was transfected with the Shh expression
vector (see Fig. 5A). These results indicated that the
CD155 core promoter was responsive to Shh, a result that is consistent with the activation of CD155 core in Ntera-2
cells treated with Shh protein. The GLI binding motif located within FPIII is required for Shh activation of the CD155 core
promoter, a result in accordance with known signaling mechanisms
induced by Shh.
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Fig. 5.
The CD155 core promoter is
activated by Shh and GLI factors through the GLI binding motif in
FPIII. A, effect of co-transfection of a full-length
Shh expression vector on the promoter activity of the wild type and a
Gli mutant BE promoter construct in the C3H10 T1/2 cell line. Cells
were seeded in six-well tissue culture plates and were transfected with
FuGENE 6 with the BE or Gli promoter construct and pcDNA3-Shh.
Transfections were filled in with pcDNA3 to keep the amount of
expression vector backbone in each reaction at a constant level for all
experiments. Transfected cells were harvested 18 h
post-transfection, and the luciferase activity contained within the
cytoplasmic extract of transfected cells was determined using the
Luciferase Reporter System (Promega). The activity of the promoter
construct co-transfected with only pcDNA3 was set to 100% (control
promoter activity), and the level of activation caused by
co-transfected of pcDNA3-Shh is expressed relative to that 100%.
Results are the mean ± S.D. of triplicate transfections. The
average Renilla luciferase corrected relative light
unit values of these transfections were 1200 (BE) and 1300 (Gli).
B, effect of co-transfection of GLI transcription
factor expression vectors on the promoter activity of the wild type and
a Gli mutant BE promoter construct in the C3H10 T1/2 cell line.
Cells were seeded in six-well tissue culture plates and were
transfected with FuGENE 6 with the BE or Gli promoter construct and
pcDNA3-Gli1 or -Gli3. Transfections, harvest,
and the luciferase assay were carried out as described in
A. The activity of the promoter construct co-transfected
with only pcDNA3 was set to 100% (control promoter activity), and
the level of activation caused by co-transfected of
pcDNA3-Gli1 or -Gli3 is expressed relative to
that 100%. Results are the mean ± S.D. of triplicate
transfections. The average Renilla luciferase corrected
relative light unit values of these transfections were 1200 (BE) and
1300 (Gli).
Gli
mutant CD155 core promoter construct failed to elicit a
similar response (Fig. 5B). Taken together our results
suggest that Gli1 and Gli3 are potent activators
of the CD155 core promoter and that activation is mediated
by a consensus GLI binding motif located in FPIII.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
ACKNOWLEDGEMENTS
FOOTNOTES
Supported by a doctoral fellowship of BoehringerIngelheim
Fonds, Heidesheim, Germany.
Supported by Grant BE1886/1-2 from the Deutsche Forschungsgemeinschaft.
ABBREVIATIONS
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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