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The Journal of Neuroscience, October 15, 1999, 19(20):8954-8965
Sonic hedgehog Regulates Proliferation and Inhibits
Differentiation of CNS Precursor Cells
David H.
Rowitch1, 2,
Benoit
St.-Jacques1,
Scott
M. K.
Lee1,
Jonathon D.
Flax2,
Evan Y.
Snyder2, and
Andrew P.
McMahon1
1 Department of Molecular and Cellular Biology, Harvard
University, Cambridge, Massachusetts 02138, and 2 Division
of Newborn Medicine, Department of Pediatrics, Harvard Medical School,
Boston, Massachusetts 02115
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ABSTRACT |
Activation of the Sonic hedgehog (Shh) signal transduction pathway
is essential for normal pattern formation and cellular differentiation
in the developing CNS. However, it is also thought to be
etiological in primitive neuroectodermal tumors. We adapted GAL4/UAS methodology to ectopically express full-length
Shh in the dorsal neural tube of transgenic mouse
embryos commencing at 10 d postcoitum (dpc), beyond the period of
primary dorsal-ventral pattern formation and floorplate induction.
Expression of Shh was maintained until birth, permitting
us to investigate effects of ongoing exposure to Shh on CNS
precursors in vivo. Proliferative rates of spinal cord
precursors were twice that of wild-type littermates at 12.5 dpc. In
contrast, at late fetal stages (18.5 dpc), cells that were
Shh-responsive but postmitotic were present in persistent structures
reminiscent of the ventricular zone germinal matrix. This tissue
remained blocked in an undifferentiated state. These results indicate
that cellular competence restricts the proliferative response to Shh
in vivo and provide evidence that proliferation and
differentiation can be regulated separately in precursor cells of the
spinal cord. Thus, Hedgehog signaling may contribute to CNS
tumorigenesis by directly enhancing proliferation and preventing neural
differentiation in selected precursor cells.
Key words:
Sonic hedgehog; tumorigenesis; GAL4; central
nervous system; proliferation; differentiation; Wnt-1; medulloblastoma; transgenic mice
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INTRODUCTION |
Sonic hedgehog (Shh)
encodes a secreted glycoprotein that is initially expressed in
mesodermal tissues underlying the ventral midline of the murine CNS
(Echelard et al., 1993 ; Marti et al., 1995a). Shh is
essential for maintenance of notochord and prechordal mesoderm (Chiang
et al., 1996) as well as the induction of floorplate and ventral
neuronal populations that form at different positions along the
anterior-posterior (AP) axis of the neural tube (Echelard et al.,
1993; Roelink et al., 1994, 1995; Marti et al., 1995b; Chiang et al.,
1996; Ericson et al., 1997; Jessell and Lumsden, 1997). In addition,
there is evidence that Shh signaling may specify oligodendrocyte
precursors (Poncet et al., 1996; Pringle et al., 1996). Shh signal
transduction is complex (Tabin and McMahon, 1997). The active Shh
signal, which is produced by autoprocessing and cholesterol
modification (Porter et al., 1996), binds to a receptor complex
composed of at least two transmembrane proteins, Patched and Smoothened
(Marigo et al., 1996; Stone et al., 1996). Shh binding to Patched is
thought to relieve Patched-mediated inhibition of Smoothened activity,
resulting in the activation of transcriptional targets by members of
the Gli family (Ingham et al., 1991; for review, see Ingham,
1998). Although Patched and Gli-1 appear to be
general transcriptional targets in vertebrates, other factors are
specific to neural precursor cells, including HNF3 and
Nkx-2.2 (Dale et al., 1997; Ericson et al., 1997).
In contrast to its roles in neural patterning and differentiation,
recent studies have implicated the Hedgehog signaling pathway in
proliferation and tumorigenesis. Loss-of-function mutations in human
PATCHED are associated with activation of the Hedgehog signal transduction pathway and promotion of a neoplastic state characterized by proliferating, undifferentiated cell populations (Hahn
et al., 1996; Johnson et al., 1996). Of the children with Gorlin's
Syndrome, which is caused by inherited mutations of PATCHED, 3-5% develop medulloblastoma (Vorechovsky et al., 1997). Inactivating mutations of PATCHED have also been found in sporadically
occurring medulloblastoma (Raffel et al., 1997) and basal cell
carcinoma, and mice heterozygous for targeted mutations of
Patched, in which Shh targets are potentially upregulated,
develop cerebellar tumors (Goodrich et al., 1997). Recently,
Wechsler-Reya and Scott (1999) provided evidence that Shh is
required for granule cell precursor proliferation during cerebellar
development, raising the possibility that similar mechanisms are
involved during development and tumorigenesis.
Mitogenic effects of Shh have been observed in a number of tissues
during development (Fan and Tessier-Lavigne, 1994; Forbes et al., 1996;
Huang and Kunes, 1996; Bellusci et al., 1997; Jensen and Wallace, 1997;
Oro et al., 1997; Duprez et al., 1998), and misexpression of chicken
Shh (Echelard et al., 1993), Gli-1 (Hynes et al.,
1997), or a dominant-negative form of protein kinase A (dn-PKA), which activates Shh targets (Epstein et al.,
1996), all resulted in embryonic CNS hyperplasia. The mechanisms
underlying such proliferative effects, however, are poorly understood.
To gain insight into this process, we have focused on the mitogenic role of Shh in the developing CNS. Our results show that ectopic activation of Hedgehog signal transduction causes enhanced
proliferation, but only at embryonic stages. Thus, factors regulating
maturation and cellular competence of CNS precursor cells temporally
restrict the proliferative response to Shh in vivo.
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MATERIALS AND METHODS |
DNA constructs. The plasmid pGaTB and pUAST, encoding
full-length GAL4 and a pentamer array of its cognate DNA
binding sequence, the upstream activating sequence (UAS), were kindly
provided by Drs. A. Brand and N. Perrimon (Harvard Medical School). To
generate the transgene pWEXP-GAL4, plasmid pGaTB was
digested with HindIII and FspI to release a DNA
fragment encoding GAL4, which was cloned into
NruI-digested Wnt-1 expression vector pWEXP-2
(Echelard et al., 1993) (see Fig. 1A). The transgene
was purified from vector sequences by digestion with AatII.
To generate the reporter transgene pUAS-lacZ, the plasmid
XB3 (Echelard et al., 1994) was digested with NotI. The
pentamer array of UAS sequences from plasmid pUAST were amplified by
PCR primers that incorporated NotI and EagI recognition sequences. Once digested, the PCR products were cloned into
the XB3 vector to create pUAS-lacZ (see Fig.
1B). The transgene was purified from vector sequences
by digestion with SalI before pronuclear injection. To
generate the mouse Sonic hedgehog misexpression transgene
pWEXP3C-Shh, the full-length cDNA was digested from plasmid
p8.1 (Echelard et al., 1993) and cloned into the Wnt-1 expression vector pWEXP-3C (Danielian and McMahon, 1996). The transgene
was purified from vector sequences by digestion with the restriction
endonuclease SalI before microinjection. To generate the
transgene pUAS-Shh, a shuttle vector, pUAS-Shuttle, was
constructed as follows. The KpnI and BglII
fragments of plasmid XB3 were replaced with an oligonucleotide
containing an XhoI site. This construct was digested with
NotI and KpnI, and an
NotI-KpnI upstream fragment of
pUAS-lacZ, comprising five copies of UAS, was added,
generating plasmid pUAS-Shuttle. Finally, pUAS-Shuttle was digested
with XhoI and BglII, and an
SalI-BglII fragment of pWEXP-3C was cloned into
the vector, creating plasmid pUAS-Shh (see Fig.
1C). The transgene was purified from vector sequences by
digestion with SalI and BglII before microinjection.
DNA sequencing of the constructs listed above was carried out using
both ABI dye terminator and dideoxy chain termination methodologies. The orientation and identity of GAL4 and
mShh in constructs pWEXP2-GAL4 and
pWEXP3C-Shh, respectively, were confirmed by DNA sequencing
using oligonucleotide 882 (5'-TAA GAG GCC TAT AAG AGG CGG-3'), which
primes ~60 bp upstream of the Wnt-1 translational initiation site.
Production and genotyping of transgenic mice.
Transgenic mice were generated by microinjection of linear DNA
fragments, separated from plasmid vector sequences, into pronuclei of
B6CBAF1/J (C57BL/6J × CBA/J) zygotes as described (Echelard et
al., 1994). The transgenic line Wnt-1/GAL4/cre-11
resulted from coinjection of the transgenes pWEXP2-GAL4 and
pWEXP3C-cre (construction and characterization of the
pWEXP3C-cre transgene are described elsewhere).
Founder (G0) transgenic mice were identified by
Southern blot of EcoRI-digested genomic DNA and probes for
GAL4 (line WEXP2-GAL4) or lacZ
(lines UAS-lacZ and UAS-Shh). Subsequent
genotyping of UAS-lacZ transgenic embryos or mice by
PCR was carried out as described in Echelard et al. (1994). Genotyping
of WEXP2-GAL4 and UAS-Shh transgenic embryos or
mice used an upstream primer from exon 1 untranslated sequence of
Wnt-1 (882-TAAGAGGCCATAAGAGGCGG) and a downstream primer
from within GAL4 (1061-ATCAGTCTCCACTGAAGC; product size
~600 bp) or mouse Shh (930-CTCATAGTGTAGAGACTCCTC; product
size ~600 bp) coding sequences, and the following PCR conditions: 30 sec, 93°C; 30 sec, 55°C, 1 min, 72°C for 40 cycles; then 5 min,
72°C.
Whole-mount histochemistry and skeletal preparation.
Analysis of embryos for -galactosidase activity was carried out as
described by Whiting et al. (1991). For analysis of skeletal
elements, 18.5 dpc bigenic fetuses were processed as described (Wallin
et al., 1994). Photography of processed embryos or fetuses was
performed in 80% glycerol/PBS on an Olympus SZH10 microscope using
Kodak 64T film. Live embryos or fetuses were photographed in PBS using a 35 mm Nikon camera and daylight film, respectively.
Histological analysis, proliferation studies, and in
situ hybridization. For histological analysis, embryos were
harvested between 9.5 and 18.5 dpc, dissected in PBS, fixed overnight
for 24 hr in Bouin's fixative, embedded in paraffin, and
sectioned (6-8 µm) at forelimb levels of the thoracic spine before
staining with hematoxylin-eosin. To analyze proliferation, 50 µg/g
of bromodeoxyuridine (BrDU) (Sigma, St. Louis, MO) was injected
intraperitoneally into pregnant mothers 3 hr before they were
killed at 12.5 and 18.5 dpc. Subsequently, four bigenic embryos
and wild-type littermates were fixed in paraformaldehyde and sectioned
as above. Dividing cells that had incorporated BrDU were identified
using monoclonal IgG (Becton Dickinson, San Jose, CA) and
immunoperoxidase staining (Vector Laboratories, Burlingame, CA) using
diaminobenzidine (Sigma) or FITC-tyramide (DuPont NEN, Wilmington,
DE). Terminal deoxynucleotidyl transferase-mediated biotinylated
UTP nick end labeling (TUNEL) procedure was performed as described
(Gavrieli et al., 1992). Both TdT and biotinylated-16-dUTP were from
Boehringer Mannheim (Indianapolis, IN).
In situ hybridization on paraffin sections with radiolabeled
antisense RNA probes was performed on either paraformaldehyde or
Bouin's fixed tissues according to lab protocols [after Wilkinson (1992); available on request]. Dark-field photomicrographs were collected on a Leitz Orthoplan or Nikon E600 compound microscope using a 35 mm camera and Fuji Velvia film or a SPOT I digital camera.
In situ hybridization on frozen sections of
paraformaldehyde-fixed tissues with digoxigenin-labeled antisense
probes was performed essentially as described in Ma et al. (1997), and
photomicrographs were collected on a Nikon E600 compound microscope
using a SPOT I digital camera (Diagnostic Imaging). We thank the
following investigators for kindly supplying the in situ
hybridization probes used: M. Scott (Ptc-1)
(Goodrich et al., 1996); A. Joyner (Gli-1) (Hui
et al., 1994); B. Hogan (HNF3) (Sasaki and
Hogan, 1993); P. Gruss (Pax-6)
(Walther and Gruss, 1991) (Pax-3)
(Goulding et al., 1993); J. Rubinstein (Nkx-2.2)
(Price et al., 1992); R. Johnson (Lmx-1b)
(Chen et al., 1998); D. Lachman (Brn-3a)
(Theil et al., 1994); L. Roberston (BMP-7)
(Lyons et al., 1995); R. Kageyama (HES-1)
(Sasai et al., 1992); Genetics Institute, Cambridge, MA (GDF-7) (Storm et al., 1994).
Immunohistochemistry. For immunohistochemistry,
embryos were either fresh frozen or fixed between 6 and 24 hr in fresh
4% paraformaldehyde before freezing and cryostat sectioning (15 µm). Antibody against a glutathione S-transferase-Hamster Lmx
fusion protein or Sonic hedgehog was generated in rabbits. Rabbit
antisera for Isl-1/2, Nkx-2.2, and Lim-3 were the generous gift of T. Jessell (Columbia University, New York). GalC, O4, and PDGF R
monoclonal antibodies were from Boehringer Mannheim. These and mouse
monoclonal antibodies against NeuN (Chemicon, Temecula, CA), TuJ1
(BAbCo, Berkley, CA), Pax-7 (Developmental Studies Hybridoma Bank), and O4 IgM were labeled with anti-rabbit Cy3 or anti-mouse IgG or IgM-conjugated Cy2 (Jackson ImmunoResearch Labs, West Grove, PA) before
visualization by fluorescence microscopy. Photomicrographs were
collected on a Nikon E600 compound microscope and SPOT I digital camera
(Diagnostic Instruments).
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RESULTS |
Gal4/UAS-targeted gene expression in the
Wnt-1 domain
The Wnt-1 enhancer is well suited for directing gene
expression in the roofplate of the spinal cord and was used to
overexpress mouse Shh in transgenic mice (D. Rowitch, B. St.-Jacques, and A. McMahon, unpublished observations). However, this
resulted in a lethal CNS malformation and precluded maintenance of
stable lines. Therefore, on the basis of the work of and Brand and
Perrimon (1993) in Drosophila and Ornitz et al. (1991) in
mice, we adapted the GAL4/UAS bigenic system for controlled
gene expression in the developing murine CNS. Six lines of transgenic
mice were generated in which GAL4 was expressed under
control of Wnt-1 regulatory sequences (Wnt-1/GAL4)
(Fig. 1A) (see Materials and
Methods), as judged by whole-mount in situ hybridization
(data not shown). These were subsequently crossed with a reporter line
in which expression of lacZ was governed by the
GAL4 cognate DNA-binding motif, "upstream activating
sequence" (Fig. 1B, UAS). When mated to
Wnt-1/GAL4 hemizygotes, 25% of progeny embryos from three
of five lines showed -galactosidase staining in the Wnt-1
pattern (Fig.
2A,B),
and one of these lines was selected for further study (designated
UAS-lacZ). All six Wnt-1/GAL4 founders were then
screened against the UAS-lacZ line and one of these was
selected for further study because of its relatively high levels of
activity (designated Wnt-1/GAL4). Expression of
lacZ in double-hemizygous (bigenic) embryos was studied from
8.5 to 18.5 dpc. -galactosidase staining was first detected at
~9.0 dpc in a region of the ventral midbrain. This represented a
delay of ~24 hr in the onset of expression compared with previous
observations of lacZ under direct control of
Wnt-1 regulatory sequences (Echelard et al., 1994).
Expression comprising the full Wnt-1 pattern was seen by
10.5 dpc (Fig. 2, compare A and B). Maintenance
of -galactosidase staining was observed at 12.5 dpc (Fig.
2C) and 18.5 dpc, at which point roofplate cells could be
clearly identified (Fig. 2D).
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Figure 1.
Schematic illustration of transgenes
WEXP-GAL4, UAS-lacZ, and
UAS-Shh used in bigenic system for misexpression in the
mouse embryonic CNS. A, Plasmid
pWEXP-GAL4 comprises full-length GAL4
(Brand and Perrimon, 1993) cloned into the WEXP2 expression vector
under control of Wnt-1 regulatory sequences (Echelard et
al., 1993). B, The reporter transgenic construct
pUAS-lacZ used the Wnt-1 minimal promoter
(Echelard et al., 1994) and five copies of the UAS (Brand and Perrimon,
1993). C, In plasmid pUAS-Shh,
full-length mouse Shh cDNA was cloned into expression
vector WEXP3C (Danielian and McMahon, 1996). Wnt-1
regulatory sequences were then replaced by five copies of the UAS.
Binding sites for oligonucleotide primers used in genotyping the
various transgenic lines are indicated (arrows).
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Figure 2.
The GAL4/UAS system for gene expression in the
developing CNS. A-D, Whole-mount
histochemical analysis of -galactosidase activity in transgenic
mouse embryos. A, Lateral view showing pattern of
lacZ expression under the control of
Wnt-1 regulatory sequences (Echelard et al., 1994).
B, C, Lateral views of 10.5 and 12.5 dpc
bigenic Wnt-1-Gal4 X UAS-lacZ embryos showing expression
pattern of lacZ (arrow indicates
roofplate expression in the spinal cord). D, Transverse
(top) and bisected (bottom) views of
lacZ expression in the rostral spinal cord of bigenic
fetus at 18.5 dpc. Note staining in roofplate oligodendrocytes that
project to the ventricular zone (arrows).
E-J, Morphological analysis of wild-type
(left) and Wnt-1-GAL4 X UAS-Shh bigenic
(right) littermates at 10.5 dpc (E,
arrow indicates anterior neural tube defect) and 12.5 dpc (F). G-J, Analysis at 18.5 dpc. Lateral views of wild-type (G) and bigenic
fetuses (H). Note tissue mass protruding
from midbrain that covers cerebral hemispheres (arrow).
I, Dorsal view of bigenic fetus showing hyperplastic
spinal cord that protrudes from the back covered by a thin epithelial
membrane. Note prominent vasculature and hemorrhage
(arrow). J, Dorsal view of skeletal prep
of wild-type (left) and bigenic (right)
fetuses at 18.5 dpc. Note absence of the membranous skull and dorsal
neural arches as well as the splayed open configuration of the
vertebral bodies (arrows).
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Conditional expression of Shh in the developing
spinal cord
To determine whether this bigenic system could also be used to
control expression of Shh, the transgenic line
UAS-Shh (Fig. 1C) was generated. Of eight founder
lines that carried the UAS-Shh transgene, six survived and
three transmitted the allele through the germline. One of these
promoted expression of Shh in response to GAL4 in the CNS.
The UAS-Shh line was viable; hemizygous progeny did not
express ectopic Shh. The phenotype of bigenic embryos (hereafter termed Shh-Tg), comprising ventralization of the
midbrain and neural hyperplasia, could first be distinguished at 9.5 dpc (data not shown) and was followed extensively from 10.5 to 18.5 dpc
(Fig. 2E-J). In contrast to
Wnt-1-Shh transgenic founder embryos, which display a
spectrum of phenotypic severity (Echelard et al., 1993; D. Rowitch, B. St.-Jacques, A. McMahon, unpublished observations), the phenotype of
the Shh-Tg embryos was highly reproducible. The Shh-Tg phenotype was judged as moderate compared with the
most severe Wnt-1-Shh founders, which failed to develop
craniofacial mesenchyme and died at 14-16 dpc. Gross morphological
analysis of Shh-Tg fetuses at 18.5 dpc revealed a tissue
mass that emanated from the midbrain (Fig. 2H,
arrow) and spinal cord tissues with a folded appearance
protruding from the back of the animals (Fig. 2I).
The membranous skull, the neural arches of the vertebrae, and epiaxial
muscle, which normally overlay the brain and spinal cord, were absent
(Figs. 2H-J). In addition, there
was pronounced blood supply to the dorsal spinal cord (Fig.
2I). Whether such effects on mesodermal derivatives
are caused by Shh itself or are a consequence of neural hyperplasia
remains to be determined.
Increased levels of proliferation in the spinal cord of
Shh-Tg mice at embryonic but not fetal stages of
development
Histological analysis of 12.5-18.5 dpc Shh-Tg bigenic
embryos demonstrated hyperplasia of the dorsal spinal cord and
expansion of the ventricular zone (VZ) (hydromyelia) (Fig.
3, compare A and E
with I and M). In principle, this could
result from increased levels of proliferation and/or inhibition of
programmed cell death. To assess proliferation in wild-type and
Shh-Tg embryos, mitotically active cells were labeled with
BrDU at 12.5, 14.5, 16.5, and 18.5 dpc and identified in sections taken
at the forelimb level (Fig. 3B,F,J,N;
and data not shown). To quantify levels of proliferation at 12.5 dpc,
we derived a relative mitotic index (ratio of BrDU-labeled cells in the
alar vs basal ventricular zone) in Shh-Tg mice (mean = 9.3, SE = 1.45; n = 4) and wild-type
littermates (mean = 3.8, SE = 0.26; n = 4).
This indicated that levels of proliferation in 12.5 dpc
Shh-Tg embryos were approximately twice that of wild-type, reflecting significant (p < 0.001, Student's
t test) elevation in the dorsal compartment where
Shh was ectopically expressed. At 14.5 dpc, a small
population of BrDU-labeled cells were observed in the spinal cord of
one of three Shh-Tg embryos, but not in wild-type (data not
shown). However, by 18.5 dpc mitotic activity in Shh-Tg
neural tissue (n = 3) was not above background
wild-type levels (n = 3) (Fig. 3, compare J
and N).
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Figure 3.
Analysis of spinal cord morphology, rates of
precursor cell proliferation, and state of Shh signal transduction in
wild-type (A-D, I-L, Q) and Shh-Tg
(E-H, M-P, R-T) spinal cord at 12.5 and 18.5 dpc. A, E, I,
M, Histological analysis of transverse sections taken at
the forelimb level. E, M, Note
hyperplasia and expansion of dorsal regions of the spinal cord of
Shh-Tg embryos. M, At 18.5 dpc the
central canal of the spinal cord is grossly enlarged and distended
(hydromyelia). B, F, J,
N, BrDU incorporation in dividing cells at
(B, F) 12.5 dpc and
(J, N) 18.5 dpc. Note that
proliferative rates are low at 18.5 dpc in both wild-type and mutant
specimens. RNA in situ hybridization showing expression
of Ptc-1 at 12.5 dpc (C, G) and 18.5 dpc
(K, O). Note ectopic dorsal expression in
Shh-Tg tissues (G, O,
arrows). Expression of Gli-1 at 12.5 dpc
(D, H) and 18.5 dpc (L, P). Note
ectopic dorsal expression in Shh-Tg spinal cord
(H, P) and dorsal root ganglion (H,
left arrow). Q-T, Tissue from 18.5 dpc
fetuses. Q, R, Wild-type and
Shh-Tg cervical spinal cord tissues showing expression
of Shh. S, Distribution of Shh protein
demonstrated by immunostaining with anti-Shh serum (Marti et al.,
1995a). T, In situ hybridization showing
expression of HNF3. Note that expression is confined
to the floorplate region (arrow).
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During spinal cord development, there is evidence for programmed cell
death initially in neural crest precursors and the floorplate region at
early stages (Homma et al., 1994) and subsequently in ventral motor
neuronal populations (Lance-Jones, 1982). To examine programmed cell
death in the developing spinal cord, tissue from 12.5, 14.5, and 18.5 dpc wild-type and transgenic mice was analyzed by the TUNEL procedure.
No differences were observed between wild-type and Shh-Tg
samples even as late as 18.5 dpc (data not shown). We conclude from
these studies that hyperplasia of the dorsal spinal cord in
Shh-Tg mice is most likely a result of proliferation per
se, rather than inhibition of apoptotic cell death.
Interestingly, Shh was capable of promoting proliferation at 12.5 dpc,
when precursors are normally competent to divide, but not at 18.5 dpc,
when neurogenesis is complete. Thus a "clock" that normally
temporally restricts the period of neural precursor proliferation in
wild-type embryos also appeared to be operative in Shh-Tg mice.
Given these dramatic differences in cellular response, it was important
to establish that the Hedgehog signal transduction pathway was active
at both of these time points. Transcriptional targets of Shh include
the transmembrane receptor Patched-1 and the zinc finger
transcription factor Gli-1. Upregulation of Ptc-1 and Gli-1 was observed at both 12.5 and 18.5 dpc (Fig.
3G,H,O,P), confirming activation of Shh signal transduction. Additionally, high
levels of Shh expression (Fig. 3R) and protein production (Fig. 3S) were maintained at 18.5 dpc. Thus, activation of
Shh signal transduction was not able to promote proliferation in the spinal cord at late fetal stages.
Proliferative effects of Shh in the absence
of floorplate
Induction of floorplate has been observed when notochord was
ectopically grafted in the chick neural tube (Placzek et al., 1993) or
when naive neural plate tissues were treated with the N-terminal
fragment of Shh (N-Shh) (Marti et al., 1995b; Roelink et al., 1995),
but such effects were limited to early developmental stages (Placzek et
al., 1993; Ericson et al., 1996). In addition, proliferative effects of
notochord and floorplate have been observed previously (van Straaten et
al., 1989; Placzek et al., 1993). One possibility was that induction of
floorplate in Shh-Tg mice could lead to proliferation by
factors other than Shh. However, ectopic expression of
HNF3 in floorplate structures was not observed in the
spinal cord at either 10.5 or 18.5 dpc (Fig. 3T), in
keeping with previous observations (Echelard et al., 1993; Epstein et al., 1996). These data indicate that Shh expression in the
spinal cord of Shh-Tg mice occurs beyond the phase of
competence to induce floorplate (Ericson et al., 1996). At 10.5 dpc,
there was broad expression of HNF3 throughout the
midbrain, indicating ventralization (Echelard et al., 1993) (data not
shown). This may account in part for a failure in anterior neural tube
closure (Fig. 2E). Because neural tube defects can
have secondary effects on proliferation, patterning, and tissue
survival, we focused our studies at the forelimb and posterior cervical
spinal cord levels.
Ectopic Shh expression confers mixed dorsal-ventral
character to the embryonic spinal cord
Sonic hedgehog is normally expressed in organizing structures at
the ventral midline from early stages of neural development. Given that
Shh expression in Shh-Tg mice occurs beyond the
phase of competence to form floorplate, we investigated how
dorsal-ventral organization was subsequently affected in 12.5-14.5
dpc embryos. Secreted factors, such as bone morphogenetic proteins
(BMPs), from the non-neural ectoderm and roofplate, are thought to act on neural plate precursors to establish dorsal identity (Liem et al.,
1997; Lee et al., 1998). Dorsal neural precursors can be recognized by
expression of the molecular markers Pax-3 and Pax-7 at appropriate stages in wild-type mice at 12.5 dpc
(Fig. 4A) (Tanabe and
Jessell, 1996). In Shh-Tg embryos, Pax-3
expression was maintained in the alar plate, indicating that dorsal
cell types that were established before ectopic Shh
expression were maintained despite ectopic Shh activity (Fig.
4B). To investigate whether precursor cells with
ventral character were induced, we tested expression of the marker
Nkx-2.2. Nxk-2.2 was detected exclusively in the ventral
neural tube of 12.5 dpc wild-type embryos (Fig. 4C) but was
ectopically induced in the dorsal region of Shh-Tg embryos
(Fig. 4D). Thus, populations of neural precursor cells with dorsal and ventral character occupied a similar domain in
the alar plate of the spinal cord in 12.5 dpc Shh-Tg
embryos. Pax-6 is expressed predominantly at 12.5 dpc in the
ventral ventricular zone of the neural tube as well as in postmitotic
ventral neurons (Fig. 4E). Expression of
Pax-6 can be repressed by Shh in neural plate explants in
culture (Ericson et al., 1997). However, we observed dramatic
upregulation of Pax-6 in the alar plate of Shh-Tg mice (Fig. 4F), consistent with the findings of
Monsoro-Burq et al. (1995). Pax-6 expression appeared to be
a sensitive indicator of immature ventricular zone precursors exposed
to ectopic Shh.
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Figure 4.
Analysis of dorsal-ventral organization in the
spinal cord of 12.5-14.5 dpc Shh-Tg embryos. In
situ hybridization was performed on 12.5 dpc (A-F, O,
P) and 14.5 dpc (G-N) spinal cord from
wild-type (A, C, E, G, I, K, M, O) and
Shh-Tg (B, D, F, H, J, L, N, P) embryos.
Expression of Pax-3 (A, B) is maintained
in Shh-Tg tissue (arrow).
C, D, Nkx-2.2 is expressed
in ventral ventricular zone (C, arrow)
and ectopically in Shh-Tg tissue (D,
arrow). E, F, Expression
of Pax-6 normally occurs in the roofplate
(rp) but is strongly upregulated in the
Shh-Tg tissue (F, arrow).
G, H, BMP-7 expression in
the meninges was unaffected in Shh-Tg mice
(arrows). I, J,
Maintenance and expansion of roofplate cells indicated by expression of
Wnt-3a in Shh-Tg tissue.
K, L, Expression of GDF-7
was weakly detected in wild-type mice and strongly maintained in dorsal
tissues of Shh-Tg mice. M,
N, Pattern of Lmx-1b expression. Note
large dorsal region in which Lmx-1b expression is
interrupted. fp, Floorplate. O,
P, Expression of the postmitotic neuronal marker
Brn-3a in dorsal spinal cord (arrows) and
dorsal root ganglion (drg).
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It was possible that hyperproliferating precursor cells in
Shh-Tg mice could be giving rise to cells with dorsal,
ventral, or mixed character. BMPs function as determinants of dorsal
character in the spinal cord and are expressed in the roofplate and
adjacent non-neural ectoderm of the embryonic neural tube (Liem et al., 1997; Lee et al., 1998) as well as the meninges. Our results indicated that BMP-7 expression in the meninges surrounding the spinal
cord was similar in wild-type and transgenic embryos (Fig.
4G,H). Analysis of Wnt-3a
expression confirmed that a roofplate population was maintained and
expanded in Shh-Tg mice (Fig.
4I,J). Moreover, dorsal
neural tissues continued to express GDF-7 (Fig.
4K,L) (Lee et al.,
1998). Thus, BMP and Wnt gene family members normally expressed in the
roofplate were maintained in Shh-Tg mice. To further
characterize development of dorsal populations, we tested expression of
Lmx-1b (Chen et al., 1998), which is expressed in cells
throughout a large region of the dorsal spinal cord and to a lesser
extent in the floorplate (Fig. 4M).
Interestingly, we observed that the Lmx-1b domain was
interrupted in Shh-Tg mice (Fig. 4N).
Taken together, these results suggested that although Shh did not
suppress the commitment to early dorsal fates, hyperplastic tissue that
was generated later lacked certain dorsal characteristics. Further
evidence for this sequence was provided by examination of
Brn-3a expression, a marker of postmitotic dorsal neurons
that can be suppressed when a source of ectopic Shh is grafted into the
early chick neural tube (Fedtsova and Turner, 1997). Maintenance of
Brn-3a expression was observed in Shh-Tg embryos
at 12.5 dpc, indicating that onset of Shh exposure likely followed that
of early specification of Brn-3a+ neurons (Fig. 4, compare
O and P). In summary, our results suggested
that early dorsal patterning of the neural tube was unaffected in
Shh-Tg mice, consistent with the delayed onset of Shh
activation. However, later populations of precursors exposed to the
ectopic Shh signal gave rise to cells expressing ventral markers.
Ultimately, the resulting structure comprised a hyperplastic and
disorganized dorsal extension superimposed on a spinal cord in which
the dorsal-ventral pattern was largely intact.
Cells of the expanded ventricular zone in Shh-Tg
mice are blocked in an undifferentiated state
We next investigated the ultimate cell fates acquired in the
hyperplastic dorsal spinal cord tissue of Shh-Tg mice.
Because Wnt-1-GAL4 expression persists throughout
the antenatal period, it is possible to characterize effects of
ongoing ectopic Shh pathway activation in tissue until late fetal
stages. A landmark structure in the wild-type spinal cord is the
ependymal cell-lined central canal (Fig.
5A,D).
A striking finding in Shh-Tg mice is that the central canal
is massively enlarged and often has a folded appearance in section
(Fig. 5B). Of particular interest was a cell-dense,
pseudostratified periventricular layer that was revealed by the nuclear
stain DAPI (Fig. 5C,E). This was
reminiscent of the periventricular neuroepithelial germinal zone, a
structure normally found only at earlier time points in spinal cord
development, which disappears as neural precursors differentiate and
emigrate from this region. Consistent with this interpretation, we
never observed labeling with mature (NeuN) or immature (TuJ1) neuronal markers within the persistent periventricular zones (Fig.
5E,G) or immunolabeling with the
astrocyte marker GFAP or the oligodendrocyte markers GalC or O4 (data
not shown). Antibodies against the N-terminal fragment of Shh (Marti et
al., 1995b) revealed that Shh proteins were produced exclusively within
the enlarged VZ (Figs. 3 R,S, 5F), a region of dramatic Ptc-1 and
Gli-1 upregulation in Shh-Tg mice (Fig.
3O,P). Further confirmation of the immature
character of the VZ cells was provided by analysis of HES-1
(Sasai et al., 1992) and Pax-6 expression. Overexpression of
HES-1 in the rodent neural tube causes delay or inhibition
of differentiation (Ishibashi et al., 1994), whereas HES-1
loss of function results in premature differentiation of neural plate
precursor cells (Ishibashi et al., 1995). We observed that
HES-1 expression was upregulated in the ventricular zone of
Shh-Tg mice (Fig. 5L). Our finding of
Pax-6 expression in the same region (Fig.
5M) further suggests that VZ cells at 18.5 dpc
share similar properties with ventricular zone precursor cells during
the period of neurogenesis (Tanabe and Jessell, 1996). Thus, markers
normally associated with precursor populations and dividing cells
present during embryogenesis revealed ectopic induction and striking
persistence into late fetal stages in the CNS of Shh-Tg
mice.
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Figure 5.
Absence of differentiation in cells lining the
enlarged ventricular zone in 18.5 dpc Shh -Tg mice.
A, B, Histological analysis of wild-type
(A) and Shh-Tg
(B) spinal cord at the forelimb level with
hematoxylin-eosin. Note that the ventricular zone (VZ)
is massively enlarged in Shh-Tg mice
(arrows). In addition, the tissue surrounding the VZ is
hyperplastic. C, Cells lining the VZ have a
pseudostratified columnar appearance as revealed by the nuclear stain
DAPI. D-G, Immunocytochemistry of VZ
region in wild-type (D) and Shh-Tg
(E-G) tissue. D,
E, The mature neuronal marker NeuN
(green) counterstained with DAPI
(blue). Compare the sizes of ventricular zone
(arrows) and the absence of NeuN labeling.
F, Shh expression (red) was confined to
VZ cells and did not overlap NeuN+ cells (green)
in the surrounding hyperplastic tissue (arrows).
G, Labeling with -tubulin III (TuJ1,
green) is excluded from the VZ (arrows).
H-M, In situ hybridization of wild-type
(H-J) and Shh-Tg
(K-M) fetuses. H, K,
Bright-field images are shown for orientation. I, L,
Expression of HES-1 was upregulated in
Shh-Tg (arrow) in cells lining the VZ.
J, M, Pax-6 was maintained in a similar
pattern of expression (arrow).
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Induction of neuronal and oligodendroglial lineages in hyperplastic
tissue adjacent to Shh-producing ventricular zone
cells
The preceding results demonstrated that regions of highest
Hedgehog pathway activation formed large ventricular zone structures comprising cells maintained in an undifferentiated state. In contrast, neuronal differentiation clearly occurred in the hyperplastic tissue
adjacent to the persistent VZ structures in Shh-Tg mice, as
demonstrated by immunolabeling with the mature neuronal marker Neu-N
(Fig. 5E). Several lines of evidence indicate that Shh is necessary and sufficient for ventral neuron (in particular motor neuron) and oligodendrocyte induction (Marti et al., 1995b; Roelink et
al., 1995; Chiang et al., 1996; Ericson et al., 1996; Poncet et al.,
1996; Pringle et al., 1996; Orentas et al., 1999). Thus, we determined
whether ventral motor neurons or oligodendrocytes were induced in
Shh-Tg mice.
We initially tested expression of molecular markers associated with
postmitotic ventral neuronal populations including c-ret, Isl-1, and En-1. Although ventrally located motor
and interneuronal populations were clearly identified, ectopic
expression of these markers was not observed (data not shown). Some
dorsally located neurons normally express Isl-1 (Liem et al., 1997).
However, additional numbers of Isl-1/2 neurons were only observed in 1 out of 5 Shh-Tg animals analyzed (Fig.
6A). One possibility
was that the dose of Shh may have been either too low or too high for
efficient Isl-1 motor neuron induction, because concentration
dependence of motor neuron induction has been demonstrated in chick
neural explant culture (Roelink et al., 1995; Ericson et al., 1997). We
therefore analyzed tissue for the presence of Lim-3 and Nxk-2.2 neurons. These markers indicate cell populations lying immediately dorsal and ventral to the region normally giving rise to motor neurons
in the ventricular zone (Tanabe et al., 1998; Briscoe et al., 1999),
and they can be induced with lower and higher concentrations of N-Shh,
respectively (Ericson et al., 1997). As shown (Fig. 6B-D), we readily detected ectopic
induction of Nkx-2.2+ and Lim-3+ cells in regions adjacent to the
enlarged ventricular zone. Thus, it is unlikely that the failure to
form Isl-1+ neurons is related to the dosage of Shh in
Shh-Tg mice. A second possibility was that Shh actually
inhibited the differentiation of Isl-1 motor neurons, as suggested from
in vitro studies (Kalyani et al., 1998). We therefore
analyzed Shh-Tg dorsal spinal cord cells in dispersed explant cultures for generation of Isl-1 neurons. Although numerous Lim-3+ and Nkx-2.2+ neurons were detected, we failed to detect Isl-1+
neurons after 5-7 d in culture (data not shown). Thus, the most likely
explanation for the lack of Isl-1 motor neuron induction is that
temporal restrictions on competence are exceeded by the time of Shh
production in Shh-Tg mice.
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Figure 6.
Analysis of neuronal and oligodendroglial cell
fate in the dorsal spinal cord of Shh-Tg mice.
Immunocytochemistry of wild-type (E, F) and
Shh-Tg (A-D, G-I) 18.5 dpc
fetuses. A, Isl-1/2 (red) labeled cells
of the dorsal root ganglion (drg, white
arrow) and a few cells in the dorsal spinal cord in one of five
specimens analyzed (hollow arrow). Note absence of
counterstain with the mature neuronal marker NeuN
(green) in dorsal cells. B,
Numerous Nkx-2.2+ cells were detected in regions surrounding the VZ
(diagonal arrow) but not the drg. C, The
area boxed in B at higher power. Not all
Nkx-2.2+ cells (e.g., solid arrow) counterstained with
NeuN (hollow arrow), which suggests relative immaturity.
D, Region adjacent to VZ analyzed with Lim-3
demonstrating numerous positive cells (red,
arrows). E, F, Analysis of Lmx-1b
populations (red) in the substantia gelatinosa region
(boxed in E, and F)
and roofplate (F, hollow arrow)
counterstained with NeuN (green). Contrast the
organization of Lmx-1b+ cells in the wild-type
(G) with those of Shh-Tg spinal
cord tissue. H, Labeling of cells with the dorsal marker
Pax-7 (green, hollow arrows)
compared with the ventral neuronal marker Nkx-2.2 (red,
solid arrows). Cells expressing both markers were not
detected. I, Oligodendrocyte precursors are induced in
regions adjacent to the Shh-expressing VZ, as indicated by the marker
PDGFR (green). Counterstain with DAPI is
blue.
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We next investigated the dorsal nature of tissue in Shh-Tg
mice at 18.5 dpc with the marker Lmx-1b. Although Lmx-1b is
expressed in the floorplate and dorsal spinal cord at embryonic stages
(Fig. 4J), Lmx-1b antisera only labels dorsal cells
at both embryonic and fetal stages (data not shown). In the wild-type
fetus, Lmx-1b is detected broadly in neurons of the substantia
gelatinosa (orange/yellow) and the roofplate (red) (Fig.
6F). In contrast, the distribution of Lmx-1b cells is
disorganized in Shh-Tg mice (Fig. 6G). We
conclude from this that Lmx-1b cells persist in the dorsal spinal cord and are interspersed with cells of ventral character (e.g., Nkx-2.2+ neurons). These results do not rule out the possibility that cells with
mixed dorsal-ventral character were elaborated in Shh-Tg mice. To assess this, we immunolabeled dorsal spinal cord tissue with
antibodies against the ventral neuronal marker Nkx-2.2 and the dorsally
restricted marker Pax-7 (Tanabe and Jessell, 1996). As shown (Fig.
6H), we did not detect cells that expressed both markers.
Oligodendrocyte precursors arise from a similar region of the neural
tube that gives rise to motor neurons (Sun et al., 1998) and can be
induced at an identical concentration of N-Shh in neural explant
culture (Pringle et al., 1996). To determine whether oligodendrocyte precursors were induced in Shh-Tg mice, we performed
immunolabeling with PDGFR (Pringle and Richardson, 1993). As shown
in Figure 6I, we observed numerous PDGFR+ cells in
regions adjacent to the VZ, the source of ectopic Shh. Induction of O4+
cells was observed in a similar distribution; however, GalC+
oligodendrocytes were only detected in the axons of the
dorsal funiculus (data not shown). These results confirmed that the
oligodendrocyte lineage was induced in the hyperplastic tissue
surrounding the VZ in Shh-Tg mice.
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DISCUSSION |
Ectopic Hedgehog signaling has been implicated in the etiology of
CNS tumors (Hahn et al., 1996; Johnson et al., 1996); however, mechanisms underlying Hedgehog-mediated tumorigenesis are poorly understood. We have used a GAL4/UAS bigenic system (Ornitz
et al., 1991; Brand and Perrimon, 1993; Wang et al., 1997), which allows for the production of stable transgenic lines to produce large
numbers of embryos that express a lethal transgene, to explore the
effects of maintaining ectopic Shh activity in the dorsal neural tube
as a model of deregulated Hedgehog signaling in the developing CNS.
Analysis of bigenic embryos revealed dramatic neural hyperplasia and
enhanced proliferative levels at 12.5 dpc. However, at 18.5 dpc, neural
tissue was postmitotic, despite the fact that cells were exposed to Shh
and still responsive, as demonstrated by upregulation of two general
transcriptional targets, Ptc-1 and Gli-1.
Shh proliferative effects in the developing
spinal cord
Several studies using primary CNS precursor cell cultures have
demonstrated proliferative effects of the biologically active N-Shh
protein after treatment for 36-48 hr (Jensen and Wallace, 1997;
Kalyani et al., 1998). Whether Shh functions as a direct mitogen
in vitro, however, has not been established (Jensen and Wallace, 1997). In a transgenic gain-of-function model, resolving whether proliferative effects of Shh are direct is difficult, because
Shh could lead to induction of other mitogens (e.g., Wnts/BMPs) (Dickinson et al., 1994). Unfortunately, it is not feasible to remove
all Wnt/BMP function from this model to determine whether the phenotype
also depends on these activities. However, the expansion and patterning
abnormalities clearly require Shh, and the induction of ventral cell
types (e.g., Nkx-2.2) is most consistent with direct Shh signaling.
Moreover, our observations are entirely consistent with a number of
in vitro studies of Shh proliferative effects on CNS
precursors (Jensen and Wallace, 1997; Kalyani et al., 1998;
Wechsler-Reya and Scott, 1999) and the finding that Patched
mutations in mice result in highly proliferative cerebellar tumors
(Goodrich et al., 1997). An obvious question remains whether Shh has a
role in regulating proliferation during normal spinal cord development,
as has been reported recently for cerebellar granule cells
(Wechsler-Reya and Scott, 1999).
Our findings from analysis of proliferation in vivo indicate
that CNS precursors are competent to proliferate in response to
activation of the Shh signal transduction pathway only at selected periods during embryogenesis. Overexpression of the Hedgehog
transcriptional target Gli-1 resulted in increased levels of
proliferation in the developing mouse brain (Hynes et al., 1997) and
Xenopus ectoderm (Dahmane et al., 1997); moreover,
GLI upregulation has been associated with brain tumors and
basal cell carcinoma in humans (Dahmane et al., 1997). We have used
Gli-1 and Patched-1 to confirm activation of Shh
signal transduction at both 12.5 and 18.5 dpc in the CNS of
Shh-Tg mice. However, given that levels of proliferation
were significantly elevated only at embryonic stages, it is clear that Gli-1 overexpression is itself insufficient for
proliferation in neural tissues at 18.5 dpc. Rather, it is possible
that Gli-1 acts in concert with other determinants of cell cycle
regulation to effect a proliferative state, as has been suggested
previously (Ruppert et al., 1991). In preliminary analysis, we have
observed that explant cultures of dorsal spinal cord tissue from 17.5 dpc Shh-Tg fetuses resume proliferation after 3 d in
serum-free media. Further work will be required to determine whether
dispersal of such tissue liberates environmental (i.e., secreted or
matrix-associated) signals that antagonize Shh proliferative effects.
Shh signaling prevents differentiation of
neural precursors
Although our results are consistent with a mitogenic role for Shh
in the neural tube, a second possibility is that proliferative effects
are an indirect consequence of preventing or delaying differentiation
of neural precursors. A ventricular zone germinal matrix-like structure
comprising primitive undifferentiated yet nondividing cells persisted
in the dorsal spinal cord of Shh-Tg mice. At 18.5 dpc, cells
in these regions expressed markers indicative of mitotically active
neural precursors such as Pax-6, HES-1, and
Dbx-1. Whether these cells represent true multipotential
precursors or are restricted in their potential to form neural cell
types is under study.
Our results suggest possible mechanisms downstream of Shh signaling
that could function to inhibit neuronal differentiation. In
Shh-Tg mice, superimposition of endogenous dorsalizing
signals (e.g., GDF-7, BMP-7) with Shh resulted in a broad overlap of
the ventral marker Nkx-2.2 with dorsally expressed
Pax-3 at 12.5 dpc. We evaluated whether the mixed signals in
the dorsal compartment might have prevented differentiation of cells
along a coherent pathway. However, we did not detect any cells
coexpressing the ventral and dorsal markers Nkx-2.2 and Pax-7, making
such a mechanism unlikely. Another possibility is that persistent
expression of Pax-6 or other factors associated with neural
precursors could institute a block to terminal differentiation.
Upregulation of HES-1, in particular, suggests that such a
mechanism may be functioning in Shh-Tg mice. Interestingly,
Kalyani et al. (1998) and Wechsler-Reya and Scott (1999) recently
reported that Shh can directly inhibit differentiation of neuronally
restricted precursor cells in vitro.
Absence of ectopic floorplate in Shh-Tg mice
We determined that Shh effects on proliferation and
differentiation were not mediated by ectopic floorplate. Conversion of the entire spinal cord to floorplate has been observed in
Patched-deficient mice (Goodrich et al., 1997), establishing
the competence of the lateral (future dorsal) neural plate to respond
to Shh signaling at early stages. The kinetics of Wnt-1/GAL4-X
UAS-Shh expression initiates Shh expression at
~9.5-10 dpc in the spinal cord, when dorsalizing signals (e.g., from
roofplate and non-neural ectoderm) (Liem et al., 1997; Lee et al.,
1998) have already commenced. In the face of non-naive tissues, Shh is
inadequate to convert the dorsal spinal cord to floorplate (Placzek et
al., 1993; Ericson et al., 1996). Indeed, maintenance of
Wnt-3a and GDF-7 expression in Shh-Tg
mice indicates that important dorsal organizing properties of the
roofplate cannot be suppressed by Shh beyond an early naive phase.
Developmental neuropathology of CNS tumors
Given that CNS tumors can arise in tissues well after primary
patterning events have taken place, it is relevant to consider the
temporal role of the Hedgehog signaling pathway. Our results indicate
that activation of Hedgehog signaling at 10.5 dpc in neural tissue that
has already acquired dorsal character can result in mixed and complex
morphology. The persistent and massively enlarged ventricular zone in
Shh-Tg mice was surrounded by hyperplastic and largely
nestin-positive tissues comprising both dorsal and ventral neuronal
cell types. For example, we observed patches of cells expressing the
dorsal marker Lmx-1b adjacent to tissue containing ectopic Lim-3+ and
Nkx-2.2+ neurons. Although Shh is capable of ventral motor neuron
induction at early developmental stages, we did not detect induction of
Isl-1+ motor neurons, most likely because Shh is produced at 10.5 dpc
in Shh-Tg mice, beyond the period when neural tube is
capable of forming ectopic floorplate or motor neurons. In addition,
foci of both astrocytes and oligodendrocyte were also observed.
Whether these findings are relevant as an indication of effects of
active Hedgehog signal transduction contributing to a tumorigenic state
in humans requires further analysis. Although inactivating mutations of
PATCHED can result in medulloblastoma, a tumor of cerebellar
granule cells, the spinal cord is not affected in such patients.
Nevertheless, Shh causes proliferation in spinal cord precursor cells
in vitro (Kalyani et al., 1998) and in vivo
(present study). Our results suggest that severe temporal restrictions on cellular competence could limit a putative "tumorigenic window" to only a few days of embryogenesis in the spinal cord. In this regard
it is interesting to note that cerebellar granule cells are the latest
population of CNS precursors to undergo terminal differentiation. Thus
it is possible that the relatively long period of granule cell
competence may facilitate stochastic events required for tumorigenic
transformation in response to Hedgehog pathway activation in humans and mice.
| |
FOOTNOTES |
Received June 29, 1999; revised Aug. 5, 1999; accepted Aug. 6, 1999.
We thank Drs. Makoto Ishibashi, Ryoichiro Kageyama, Qiufu Ma, Chuck
Stiles, David Fischer, Yann Echelard, Rob Wechsler-Reya, and Matt Scott
for comments and stimulating discussions; Yann Echelard for preparation
of the Wnt-1-GAL4 transgene; and Dong-In Yuk, Bianca Klumpar, and Wendy Liu for technical assistance. D.H.R. was
supported by a Physician Postdoctoral Fellowship from the Howard Hughes
Medical Institute and Grant HD01182 from National Institutes of Health.
B.S.J. was supported by a postdoctoral fellowship of the Medical
Research Council of Canada. These studies were funded by National
Institutes of Health Grants NS32691 and HD30249 (A.P.M.) and the
Charles H. Hood Foundation and Brain Tumor Society (D.H.R.). D.H.R. is
a recipient of a Basil O'Conor Starter Scholar Award from the March of
Dimes Foundation.
Correspondence should be addressed to Dr. David H. Rowitch at his
present address: Department of Pediatric Oncology, Dana-Farber Cancer
Institute, Boston, MA 02115, or to Dr. Andy McMahon, Department of
Molecular and Cellular Biology, Harvard University, The Biolabs, 16 Divinity Avenue, Cambridge, MA 02138.
Dr. St.-Jacques's present address: Ontogeny, Inc., Cambridge, MA 02138.
| |
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N. Byrd, S. Becker, P. Maye, R. Narasimhaiah, B. St-Jacques, X. Zhang, J. McMahon, A. McMahon, and L. Grabel
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[Abstract]
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T. Reya
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[Abstract]
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A. M. Kenney, M. D. Cole, and D. H. Rowitch
Nmyc upregulation by sonic hedgehog signaling promotes proliferation in developing cerebellar granule neuron precursors
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[Abstract]
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R. A. McCarthy, J. L. Barth, M. R. Chintalapudi, C. Knaak, and W. S. Argraves
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[Abstract]
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D. J. Solecki, M. Gromeier, S. Mueller, G. Bernhardt, and E. Wimmer
Expression of the Human Poliovirus Receptor/CD155 Gene Is Activated by Sonic Hedgehog
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[Abstract]
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K. O. Hartley, S. L. Nutt, and E. Amaya
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[Abstract]
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M. Rallu, R. Machold, N. Gaiano, J. G. Corbin, A. P. McMahon, and G. Fishell
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Development,
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[Abstract]
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[PDF]
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F. Long, X. M. Zhang, S. Karp, Y. Yang, and A. P. McMahon
Genetic manipulation of hedgehog signaling in the endochondral skeleton reveals a direct role in the regulation of chondrocyte proliferation
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[Abstract]
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C. B. Bai and A. L. Joyner
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[Abstract]
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N. Dahmane, P. Sanchez, Y. Gitton, V. Palma, T. Sun, M. Beyna, H. Weiner, and A. Ruiz i Altaba
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L.-A. D. Miller, S. E. Wert, and J. A. Whitsett
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J.-B. Charrier, F. Lapointe, N. M. L. Douarin, and M.-A. Teillet
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R. A. Schneider, D. Hu, J. L. R. Rubenstein, M. Maden, and J. A. Helms
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S Pons, J. Trejo, J. Martinez-Morales, and E Marti
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N Scheer, A Groth, S Hans, and J. Campos-Ortega
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M Treier, S O'Connell, A Gleiberman, J Price, D. Szeto, R Burgess, P. Chuang, A. McMahon, and M. Rosenfeld
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S Nery, H Wichterle, and G Fishell
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A. M. Kenney and D. H. Rowitch
Sonic hedgehog Promotes G1 Cyclin Expression and Sustained Cell Cycle Progression in Mammalian Neuronal Precursors
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D. Maric, I. Maric, Y. H. Chang, and J. L. Barker
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[Abstract]
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C. Wetmore, D. E. Eberhart, and T. Curran
The Normal patched Allele Is Expressed in Medulloblastomas from Mice with Heterozygous Germ-Line Mutation of patched
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[Abstract]
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K. O. Hartley, S. L. Nutt, and E. Amaya
Targeted gene expression in transgenic Xenopus using the binary Gal4-UAS system
PNAS,
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[Abstract]
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TOP
ABSTRACT
INTRODUCTION
