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The Journal of Neuroscience, June 15, 1998, 18(12):4684-4696
Expression of GDNF Family Receptor Components during Development:
Implications in the Mechanisms of Interaction
Tian
Yu1,
Sheila
Scully2,
Yanbin
Yu,
Gary M.
Fox2,
Shuqian
Jing2, and
Renping
Zhou1
1 Laboratory for Cancer Research, Department of
Chemical Biology, College of Pharmacy, Rutgers University, Piscataway,
New Jersey 08855, and 2 Amgen Incorporated, Amgen Center,
Thousand Oaks, California 91320-1789
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ABSTRACT |
Glial cell line-derived neurotrophic factor (GDNF) and a related
factor, neurturin, promote survival of diverse groups of neurons. Both
GDNF and neurturin signal via a two-component receptor complex that
consists of a ligand-binding GDNF family receptor (GFR -1 or
GFR-2) and the receptor protein tyrosine kinase Ret. Recently, a
third receptor related to GFR-1 and GFR-2 has also been isolated
and designated GFR-3. Although much is known about the interaction
among GDNF family factors, Ret, and the -receptors in
vitro, it remains unclear about their interactions in
vivo. We show here by in situ hybridization that
Ret and the -receptors may be colocalized in the same tissues or
expressed separately in projecting and target tissues, respectively,
indicating that two distinct modes of interaction between Ret and the
-receptors exist in vivo. First, Ret may interact
with the -receptors expressed in the same cells (termed interaction
"in cis") in many tissues and cell populations that respond to GDNF
and/or neurturin, such as the substantia nigra, dorsal root ganglia,
spinal cord motoneurons, kidney, and intestine. Second, Ret may
interact with the -receptors localized in the target neurons (termed
interaction "in trans"). In addition, we present evidence in
vitro that GFR-1 mediates Ret activation by GDNF in trans.
These observations suggest that there are multiple mechanisms
regulating the interaction between Ret and the -receptors that
mediates the effects of GDNF family trophic factors on the survival and
differentiation of cells and on neuron-target interactions in the
nervous system.
Key words:
neurotrophic factors; Ret tyrosine kinase; GDNF family
receptors; neurturin; neuron-target interaction; in situ
hybridization
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INTRODUCTION |
Glial cell line-derived neurotrophic
factor (GDNF) is a potent survival factor for many central and
peripheral neurons, including midbrain dopaminergic neurons (Lin et
al., 1993 ; Beck et al., 1995; Tomac et al., 1995), spinal cord
motoneurons (Henderson et al., 1994; Li et al., 1995), cerebellar
Purkinje cells (Mount et al., 1995), and sensory and autonomic neurons
(Buj-Bello et al., 1995). In addition, GDNF is essential for the
development of the kidney and enteric nervous system (Moore et al.,
1996; Pichel et al., 1996; Sanchez et al., 1996). Recently, a novel GDNF-related neurotrophic factor, neurturin, has been isolated (Kotzbauer et al., 1996) and shown to have similar activities to GDNF.
For example, both molecules promote the survival of sympathetic neurons
of the superior cervical ganglia and sensory neurons of the nodose and
dorsal root ganglia (Henderson et al., 1994; Buj-Bello et al., 1995;
Ebendal et al., 1995; Oppenheim et al., 1995; Trupp et al., 1995; Yan
et al., 1995; Kotzbauer et al., 1996).
The biological action of GDNF is mediated by a two-component
receptor complex consisting of a glycosylphosphatidylinositol-linked cell surface molecule, the GDNF family receptor GFR-1 (originally named GDNFR-), and the receptor protein tyrosine kinase Ret (Durbec et al., 1996b; Jing et al., 1996; Treanor et al., 1996; Trupp et al.,
1996). In the absence of GFR-1, GDNF fails to bind and activate Ret
in vitro (Jing et al., 1996; Treanor et al., 1996). Mice
bearing null mutations of Ret exhibit similar phenotypic defects to
that of GDNF knock-out animals, including renal agenesis or severe
dysgenesis and lack of enteric neurons, indicating that Ret is a key
component involved in GDNF signaling in vivo (Edery et al.,
1994; Romeo et al., 1994; Schuchardt et al., 1994; Sanchez et al.,
1996).
Two GFR-1-related molecules, GFR-2 and GFR-3, have been
isolated recently (Baloh et al., 1997; Buj-Bello et al., 1997; Jing et
al., 1997; Klein et al., 1997; Sanicola et al., 1997). Receptor-binding, cross-linking, and receptor activation studies have
shown that GFR-2 is a binding receptor for both neurturin and GDNF
and mediates phosphorylation of the Ret tyrosine kinase. However,
GFR-2 exhibits a marked preference for interaction with neurturin
(Baloh et al., 1997; Jing et al., 1997). Similarly, neurturin has been
shown to bind and activate Ret via GFR-1, although much less
efficiently than GDNF (Baloh et al., 1997; Jing et al., 1997). Even
though the ligand for GFR-3 remains unknown, the amino acid sequence
and structural homology of this receptor to GFR-1 and GFR-2
suggest that it is likely to signal via Ret receptor protein tyrosine
kinase as well (Jing at al., 1997).
Ret tyrosine kinase is activated efficiently by GDNF or neurturin when
the -receptors are coexpressed with Ret in the same cells (Jing et
al., 1996; 1997), indicating a functional "cis" interaction. Here
we provide evidence from in vivo expression and in
vitro tyrosine kinase activation that the -receptors may also
mediate Ret activation by GDNF or neurturin "in trans," suggesting a role in regulating neuron-target interactions.
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MATERIALS AND METHODS |
Animals. Embryonic day 18 (E18) fetuses, postnatal
day 7 (P7) pups, and the adults of Sprague Dawley rats were used in
this study. The occurrence of a vaginal plug was defined as E1, and the
day of birth was P1. At least three rats at each age were analyzed.
Embryos and brains were dissected under carbon dioxide anesthesia and
immediately frozen on powdered dry ice. Coronal and sagittal sections
of 14 µm thickness were cut on a cryostat at  20°C and
thaw-mounted onto glass slides. Before the experiments, the slides had
been delipidated with acetone, followed by 100% EtOH (5 min each), and
then dipped in 2% triethoxy-3-aminopropyl silane (Sigma, St. Louis,
MO) for 5 min. The treated slides were washed first with acetone and
then with H2O for 5 min each. Slide-mounted sections were
then stored at 80°C until use (up to 2 months).
Probes. For detection of GDNF family receptor expression
using in situ hybridization, 35S- or
33P-labeled riboprobes were generated from various plasmids
containing the receptors (see the following descriptions) using either
T7 or SP6 RNA polymerases. The Ret probe is a 262 nucleotide (nt) fragment of a rat Ret cDNA that encodes amino acids 105-192 of the
extracellular domain (Iwamoto et al., 1993; Jing et al., 1996). GFR-1 transcripts were detected with two different probes derived from the rat receptor cDNA. The first, GR400, is a 393 nt riboprobe (corresponding to amino acid positions 126-256 of GFR-1) (Jing et
al., 1996). GR400 has a homology of 74.3 and 58.8% with the corresponding regions in GFR-2 and GFR-3, respectively, in the nucleotide level. The second, GR396, is 396 bp and corresponds to amino
acid positions 258-389 of GFR-1 (Jing et al., 1996). The GR396
sequence shares a homology of 59.8% with GFR-2 and 56.3% with
GFR-3 in the corresponding regions in the nucleotide level. The
patterns of GFR-1 expression revealed by both probes are identical.
Data presented in this report are only from experiments with the GR396
probe. GFR-2 mRNA was also detected with two different probes,
RGL240 and RGL205. RGL240 is a 249 nt riboprobe corresponding to amino
acid positions 107-189 of rat GFR-2 and shares 70 and 57.0%
nucleotide sequence homology with rat GFR-1 and GFR-3 in the
corresponding regions, respectively (Jing et al., 1997). RGL205 is 205 bp and derived from amino acid positions 262-330 of the rat GFR-2
(68.8 and 49.3% nucleotide sequence homology with GFR-1 and
GFR-3 in the corresponding regions, respectively) (Jing et al.,
1997). Both probes revealed the same expression pattern of GFR-2,
but only data obtained with RGL205 are presented in this report.
GFR-3 transcripts were hybridized with a 225 nt riboprobe, pMFR3,
corresponding to amino acid positions 225-300 of the rat GFR-3
(71.1 and 57.0% nucleotide homology with GFR-1 and GFR-2 in the
corresponding regions, respectively) (Jing et al., 1997). The
-receptor probes are specific for each transcript, and no
cross-hybridization has been observed either in our previous Northern
blot analyses (Jing et al., 1997) or in in situ
hybridization experiments in current studies. Sense probes
corresponding to the same regions as the antisense probes were used in
parallel experiments for controls. All antisense and sense probes were synthesized by in vitro transcription with
[35S]- or [33P]UTP (New
England Nuclear).
In situ hybridization. In situ hybridization
was performed as described previously (Zhang et al., 1997). Briefly,
slide-mounted sections were warmed quickly to room temperature and
fixed in 4% paraformaldehyde in 0.1 M phosphate buffer, pH
7.2 (all treatments were performed at room temperature unless otherwise
indicated). The sections were further treated with proteinase K (40 ng/ml) for 30 min, refixed with 4% paraformaldehyde for 15 min,
immersed in triethanolamine (50 mM) in acetic anhydride
solutions (100 mM) for 10 min, and dehydrated. The sections
were hybridized with the respective riboprobe (2.5 × 106 cpm/ml) under stringent conditions (50%
formamide, 10% dextran sulfate, 1× Denhardt's solution, 0.2 mg/ml
Herring sperm DNA, and 10 mM dithiothreitol) for 18-24 hr
at 55°C. After hybridization, the sections were washed in 5× SSC at
65°C for 20 min, followed by 50% formamide in 2× SSC for 30 min at
the same temperature. The sections were washed twice in RNase buffer
(10 mM Tris-HCl, pH 7.5, 0.5 M NaCl, and 5 mM EDTA) for 20 min each and incubated for 30 min at 37°C
in the same buffer containing 20 µg/ml RNase A. Sections were rinsed
in the RNase buffer for 20 min at 37°C. Finally, the sections were
washed in 50% formamide, in 2× SSC at 65°C for 30 min, in 2× SSC
and in 0.1× SSC at room temperature for 15 min each. After washes, the
sections were dehydrated and exposed to x-ray film for 3-6 d. After
film development, the sections were coated with Kodak NTB-2
photographic emulsion, diluted 1:1 with distilled water. The sections
were exposed for 2-3 weeks at 4°C, developed, and counterstained
with thionin or eosin.
The expression analysis of each gene was done on at least three
different animals at the appropriate age. To control the potential variation in hybridization signal between experiments, we treated complete sets of serial tissue sections of E18 embryos and P7 pups
simultaneously under identical conditions for each probe.
Quantitation of in situ hybridization signals.
For the purpose of a general survey of the expression of GDNF family
receptors in disparate regions of the rat nervous system at E18 and P7, a semiquantitative analysis was performed. The relative levels of
signals in all the sections hybridized were visually inspected and
assigned a grade. The strongest and background hybridization were
designated "+++" and "-," respectively. Intermediate signal levels were given "++," "+," and "±," depending on the
relative intensity compared with the strongest and weakest signals.
Complete quantitative analysis was not done because of difficulties
created by signal variations within a particular structure (i.e.,
septum) or cell type (i.e., hippocampal pyramidal cells).
Ret tyrosine kinase activation assay. The effect of GFR-1
provided in trans on Ret tyrosine kinase activation was assayed with
both soluble recombinant human GFR-1 protein fused to the human IgG
Fc domain (GFR-1/Fc) or GFR-1/Fc immobilized on protein A-Sepharose beads. For assay with soluble GFR-1/Fc, conditioned medium (CM) of a 293T cell line secreting the receptor-Fc fusion protein, constructed previously (Jing et al., 1997), was used. To
prepare the immobilized GDNF/GFR-1/Fc complex, we added human recombinant GDNF to 1 ml of CM at a concentration of 50 nM
and incubated the mixture at room temperature for 45 min. Protein A-Sepharose beads were then added to the GDNF and CM mixture and further incubated at room temperature for 30 min. The
GDNF/GFR-1/Fc/protein A-Sepharose complex was collected by
centrifugation in a microcentrifuge at 14,000 rpm for 5 min, washed
three times with 1 ml of binding buffer (DMEM containing 2 mg/ml bovine
serum albumin and 25 mM HEPES, pH 7.0) prewarmed to 37°C,
and resuspended to 1 ml of binding buffer for Ret activation assay. To
examine the stability of the complex, we incubated 50 µl aliquots of
GDNF/GFR-1/Fc/protein A-Sepharose beads in binding buffer at 37°C
for various periods of time (0-10 min). The beads were separated from
the liquid phase by filtration through 0.45 µm filters. Filtered
solutions were then analyzed by SDS-PAGE along with an equivalent
amount of CM (50 µl). The gel was transferred to a nitrocellulose
filter, and the amount of the GFR-1/Fc protein dissociated from
protein A beads during incubation was determined by Western blot
analysis using horseradish peroxidase-conjugated protein A.
To test the ability of GFR-1 to activate Ret receptor protein
tyrosine kinase in trans, we seeded Neuro-2a cells, which express high
levels of Ret, in six-well cluster tissue culture dishes at a density
of 1.5 × 106 cells/well 24 hr before Ret
activation. Cells were then treated with CM containing soluble
GFR-1-Fc or with protein A-Sepharose-immobilized GDNF/GFR-1/Fc
complexes at 37°C for 5 min. For negative controls, parallel cultures
were treated with 1 ml of binding buffer, buffer with protein
A-Sepharose only, buffer with 50 nM GDNF alone, buffer with
the same amount of GFR-1/Fc alone, buffer with both GDNF and protein
A-Sepharose beads, or buffer with GFR-1/Fc/protein A-Sepharose bead
complexes. Treated Neuro-2a cells were then lysed, and the cell lysates
were immunoprecipitated using an anti-Ret antibody. The
immunoprecipitates were fractionated by SDS-PAGE and blotted using an
antiphosphotyrosine antibody as described previously (Jing et al.,
1996).
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RESULTS |
Colocalization of Ret and GDNF family -receptors in the
developing rat
To examine the potential mechanisms of interaction between Ret and
the -receptors in vivo, we compared expression of these molecules during rodent development. Embryonic (E18) and postnatal (P7)
rats were examined in detail by in situ hybridization using antisense riboprobes specific to each of the receptors. These studies
showed that Ret was coexpressed with at least one of the -receptors
in many different types of cells known to be responsive to GDNF or
neurturin.
Non-neural tissues
High levels of expression of Ret, GFR-1, and GFR-2 were
detected in the kidney and intestine in E18 rat embryos (Figs.
1, 2,
3; Table
1). Moderate Ret, low GFR-1, and weak
GFR-2 expressions were also observed in the lung (Fig. 2; Table 1).
In the kidney, the expression of Ret was restricted to the ureteric
buds along the edge of the tissue (Fig. 3). GFR-1 was also
transcribed at high levels in the ureteric buds. In addition, GFR-1
transcripts were observed in the maturing nephrons, with decreasing
levels in increasingly mature structures (Fig. 3). In contrast,
GFR-2 was transcribed diffusely in the mesenchymal tissues
surrounding the nephrons, with slightly higher levels along the edge of
the kidney (Fig. 3). GFR-3 expression was not apparent at this
stage, although at postnatal day 7, diffuse signals were detected (data not shown). Thus in the kidney, Ret and GFR-1 were colocalized in
the ureteric buds, whereas GFR-2 was observed in tissues surrounding the ureteric buds. The distinct localization of GFR-1 and GFR-2 suggests unique roles of these receptors in kidney morphogenesis.
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Figure 1.
Expression of Ret, GFR-1, GFR-2, and
GFR-3 in E18 rat embryos. Serial parasagittal sections were
hybridized to antisense riboprobes of Ret, GFR-1, GFR-2, and
GFR-3, respectively. The first panel of this and the
following figures is a bright-field picture of a serial section
counterstained with thionin or eosin. The other panels
are dark-field pictures of sections hybridized with the indicated
probes. Sense probes of the receptors revealed no specific
hybridization patterns. DRG, Dorsal root ganglia;
Int, intestine; Kid, kidney;
5Gn, trigeminal ganglia. Scale bar, 1.75 mm.
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Figure 2.
Expression of Ret, GFR-1, GFR-2, and
GFR-3 in E18 rat kidney and intestine. Serial cross-sections through
the kidney and intestine of E18 rat embryos were hybridized to
antisense riboprobes of the four receptors. DRG, Dorsal
root ganglia; Int, intestine; Kid,
kidney; SC, spinal cord. Scale bar, 1.65 mm.
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Figure 3.
Expression of Ret, GFR-1, and GFR-2 in E18
rat kidney. Serial cross-sections of E18 rat embryos through the kidney
were hybridized to the three receptor riboprobes as described in detail
in Materials and Methods. Note that Ret and GFR-1 were coexpressed
in ureteric buds, whereas GFR-2 was detected in the mesenchymal
tissues surrounding both the ureteric buds and the maturing nephrons.
Scale bar, 0.25 mm.
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Neural tissues
The coexpression of Ret and the -receptors was also observed in
the nervous system. High levels of Ret, GFR-1, and GFR-3 and
moderate levels of GFR-2 mRNAs were detected in E18 trigeminal ganglia (see Figs. 1, 6, 7; Table 1) and
superior cervical ganglia (Table 1). Strong expression of Ret and
GFR-3 and moderate expression of GFR-1 and GFR-2 were also
observed in dorsal root ganglia (Fig 4; Table 1). In the spinal cord,
high levels of Ret and GFR-1 expression were observed in the ventral
horn where motoneuron cell bodies are located (Fig. 4). A low level
signal for GFR-1 and GFR-2 was also detected in other regions of
the spinal cord, whereas GFR-3 mRNA was absent throughout (Figs. 2,
4; Table 1). In the pons, high levels of Ret and GFR-1 were detected
in the hypoglossal nucleus and facial nucleus (Fig.
5). Weak GFR-2 expression was also
detected in these regions (Fig. 5). In addition, low levels of Ret and
moderate levels of GFR-1 and GFR-2 were transcribed in the
trigeminal nuclei (Fig. 5). In the midbrain, transcripts for both Ret
and GFR-1, but not GFR-2, were detected in the substantial nigra
at high levels (Fig. 6). In the thalamus,
Ret, GFR-1, and GFR-2 were detected in the reticular and ventral medial nucleus (Fig. 6). In addition, coexpression of Ret, GFR-1, and/or GFR-2 was also observed in the hypothalamus, zona incerta, amygdala, and retina (Table 1). In contrast to Ret, GFR-1, and GFR-2, GFR-3 was absent from the brain at both embryonic and postnatal stages (Figs. 1, 7; Table 1).
These observations indicate that Ret is often accompanied by at least
one of the three known -receptors.
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Figure 4.
Expression of Ret, GFR-1, GFR-2, and
GFR-3 in E18 rat spinal cord. Serial cross-sections of E18 rat
embryos through the spinal cord were hybridized with riboprobes against
the four receptors, respectively. Control sense probe did not show any
specific patterns of hybridization signal (data not shown).
DRG, Dorsal root ganglia. Scale bar, 0.6 mm.
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Figure 5.
Expression of Ret, GFR-1, and GFR-2 in the
brainstem. Serial horizontal sections of E18 embryonic head were
hybridized to the antisense probes of Ret, GFR-1, and GFR-2,
respectively. Hybridization with sense probes for these receptors
showed no specific hybridization patterns (data not shown).
Hypg, Hypoglossal nucleus; n5n, the
principle (motor) trigeminal nucleus; n5p, the principle
(sensory) trigeminal nucleus; n7n, facial motor nuclei.
Scale bar, 0.5 mm.
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Figure 6.
Expression of Ret, GFR-1, GFR-2, and
GFR-3 in the P7 thalamus and substantia nigra. Panels
for GFR-3 and on the left for Ret, GFR-1, and
GFR-2 are coronal sections through the reticular nucleus of the
thalamus, and panels on the right are
coronal sections through the posterior hippocampus and substantia
nigra. Ctx, Cortex; Hip, hippocampus;
MHb, medial habenular nucleus; Rt,
reticular nucleus of the thalamus; SN, substantia nigra;
VM, ventromedial thalamic nucleus; ZI,
zona incerta; 5Gn, trigeminal ganglia. Scale bar, 2.4 mm.
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Figure 7.
Expression of Ret and GFR receptors in the P7
forebrain. Serial coronal sections through the forebrain were
hybridized with antisense probes to Ret, GFR-1, GFR-2, and
GFR-3, respectively. Sense probes revealed no specific hybridization
signals (data not shown). Ctx, Cortex;
End, endopiriform nucleus; Hyp,
hypothalamus; LS, lateral septum; MS,
medial septum; Sep, septum; VP, ventral
pallidum; 5Gn, trigeminal ganglia. Scale bar, 2 mm.
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Unique expression of the GDNF family -receptors in projection
targets of Ret-positive neurons in the nervous system
In addition to the coexpression of one or more of the
-receptors with Ret in a variety of different neuronal and
non-neuronal tissues, various levels of GFR-1 and GFR-2
expression were observed in many brain regions without significant Ret
expression in the same location at the same developmental stages (see
Figs. 7-10; Table 2). However, although Ret was not expressed in these
same regions, it was transcribed invariably at high levels in the
efferent neurons. Several efferent-target systems showed such
differential expression. In the hippocamposeptal system, both GFR-1
and GFR-2 were transcribed at high levels in the lateral septum, the
major subcortical target region of the hippocampal neurons in the CA
regions (Figs. 7, 8). In contrast, little
expression of these two receptors was observed in the medial septum,
which sends projections to the hippocampus. Consistent with mediating
hippocamposeptal interactions, Ret was clearly expressed in the
hippocampal CA3 neurons (Fig. 8). Ret expression in the hippocampus
appeared to start at late embryogenesis or the early postnatal period,
because significant expression was observed at P7 but not at E18 (data
not shown; Fig. 8). Furthermore, Ret expression was not accompanied by
any -receptors in CA3 at this stage, although they were expressed at
low levels in the adult (data not shown) (also see Trupp et al.,
1997).
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Figure 8.
Expression of Ret, GFR-1, and GFR-2 in the
rat hippocamposeptal system. Coronal sections through the P7
hippocampus (top two panels) and horizontal sections
through the E18 septum (bottom four panels) were
hybridized to antisense probes of Ret, GFR-1, and GFR-2.
CA1, CA3, Cornu ammonis subregion 1 and
3; Cg, cingulate cortex; DG, dentate
gyrus; IL, inferolimbic cortex; LS,
lateral septum; MS, medial septum. Scale bars:
hippocampus, 0.35 mm; septum, 0.45 mm.
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In the trigeminal sensory system, trigeminal ganglia cells innervate
the whiskerpads. High levels of GFR-1 and GFR-2 were transcribed
in the whiskerpads, whereas no significant Ret expression was observed
in this area (Fig. 9). In contrast, high
levels of Ret, along with all three known -receptors, are expressed
in the trigeminal ganglia (see previous section; Figs. 1, 7; Table 1).
The third system that showed a clear target expression of the
-receptors was the thalamocortical system. High levels of GFR-2
were transcribed specifically in layer 4 cortical neurons with no
apparent Ret expression (Fig. 10; Table
2). Layer 4 cortical neurons are known to
be innervated by neurons in the thalamus, where significant expression
of Ret as well as GFR-1 and GFR-2 were detected (Fig. 6). In
addition, high levels of GFR-1 and GFR-2 expression were also
observed in the superior colliculus, whereas high levels of Ret, along
with GFR-1, were expressed in the retina (Tables 1, 2). These
observations suggest that the interaction between GDNF family trophic
factors, the -receptors, and Ret may mediate neuron-target
interaction in many neural systems.
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Figure 9.
Expression of Ret, GFR-1, and GFR-2 in
the whiskerpads. Serial frontal sections through the whiskerpads were
hybridized to the antisense riboprobes of the three receptors,
respectively. High levels of GFR-1 and GFR-2 were detected in the
vibrissae (arrows), with no apparent Ret expression. The
bright ring in the center of the vibrissae in the Ret
dark-field picture is caused by eosin staining and is not a true
hybridization signal. Scale bar, 10 µm.
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Figure 10.
Expression of GFR-1 and GFR-2 in the
cortex. Coronal sections of the adult rat brain were hybridized to the
antisense probes of GFR-1 and GFR-2. Sense probes of GFR-1 and
GFR-2 showed no specific hybridization signals on adult brain
sections (data not shown). Similar expression was observed in E18 and
P7 rat brain. cc, Corpus callosum; Ctx,
cerebral cortex; DEn, dorsal endopiriform nucleus;
Hip, hippocampus; LV, lateral ventricle;
Rt, reticular nucleus; 1-6, cortical
layers 1-6. Scale bars: top panels, 1.45 mm;
lower panels, 0.54 mm.
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High levels of GFR-1 expression were also observed in the bed
nucleus of the stria terminalis, the claustrum, the ventral pallidum,
the dorsal endopiriform nucleus, and the habenular nucleus (Table 2).
No or little Ret expression was observed in these areas. The
significance of GFR-1 expression in these regions has not been fully
investigated at the present time.
Activation of receptor tyrosine kinase Ret by GDNF and GFR-1
in trans
Our in situ hybridization studies indicated that Ret
may interact with the -receptors expressed either in the same cells (interaction in cis) or in target neurons (interaction in trans). It
has been demonstrated previously that interaction in cis between Ret
and GFR-1 or GFR-2 mediates the biological activity of the GDNF
family ligands by coexpressing these receptors in the same cells (Jing
et al., 1996, 1997; Treanor et al., 1996). To test the ability of
GFR-1 to mediate Ret activation in trans, we provided GFR-1/Fc
either in soluble form or immobilized to protein A-Sepharose beads
(Fig. 11A) to
Ret-expressing Neuro-2a cells in the presence of GDNF. Both the soluble
and the immobilized GDNF/GFR-1 complex strongly activated Ret
tyrosine kinase (Fig. 11). In contrast, GFR-1/Fc alone, whether
soluble or immobilized, failed to activate Ret. GDNF alone also has
very little activity in activating Ret, both in the presence and in the
absence of protein A-Sepharose beads (Fig. 11B).
These observations provide biochemical evidence that GFR-1 can
indeed interact with Ret in trans in mediating GDNF function.
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Figure 11.
Activation of Ret tyrosine kinase in trans by
soluble or immobilized GDNF/GFR-1 complex. A, Stable
association of GDNF/GFR-1/Fc complex with protein A-Sepharose beads.
The GDNF/GFR-1/Fc complex was immobilized on protein A-Sepharose
beads by mixing GDNF (50 nM) with the conditioned medium of
GFR-1-producing 293T cells and with protein A-Sepharose beads as
described in Materials and Methods. To examine whether there was
dissociation of the GDNF/GFR-1/Fc complex from the protein A beads,
we resuspended aliquots of the protein A complex in binding buffer and
incubated these at 37°C for various times as indicated. The
supernatants were then analyzed with Western blot for the presence of
dissociated GDNF/GFR-1/Fc complex as described in Materials and
Methods. An aliquot of the conditioned medium containing an
approximately equivalent amount of GFR-1/Fc was included in the blot
for comparison (GFR-1/Fc lane). No dissociated
GFR-1/Fc was detected (0-10 min lanes). B,
Activation of Ret receptor tyrosine kinase by soluble or protein
A-immobilized GDNF/GFR-1/Fc complex. Soluble or protein
A-immobilized GDNF/GFR-1/Fc complex was added to Neuro-2a cells that
express Ret and incubated for 5 min. The treated cells were then
analyzed for Ret activation as described in Materials and
Methods.
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DISCUSSION |
The molecular mechanism for GDNF and neurturin signaling has been
well characterized in vitro. Both ligands exert their
actions via a receptor complex composed of a ligand-binding receptor, either GFR-1 or GFR-2, and a signal-transducing component, the receptor protein tyrosine kinase Ret (Jing et al., 1996, 1997; Treanor
et al., 1996; Baloh et al., 1997; Buj-Bello et al., 1997; Klein et al.,
1997; Sanicola et al., 1997). Because both components of the receptor
complex are required for GDNF and neurturin signaling, interaction of
the GDNF family -receptors with Ret is essential for the function of
these ligands. In this study we have compared the expression of Ret and
three -receptors during rodent development to determine the mode of
their interactions in vivo and provided in vitro
evidence that GFR-1 can activate Ret in trans. These observations
suggest that Ret and the -receptors may mediate not only the trophic
effects of the GDNF family ligands on neurons by interacting in cis but
also may regulate the functions of these ligands in neuron-target
interactions by binding in trans.
Coexpression of Ret and the -receptors: potential interactions
in cis
Comparison of the expression of Ret and -receptors showed
that in most GDNF- and/or neurturin-responsive tissues, Ret is coexpressed with one or more of the -receptors. In agreement with
previous knock-out studies indicating that GDNF and Ret are essential
for embryonic development of kidney and intestine (Schuchardt et al.,
1994; Moore et al., 1996; Pichel et al., 1996; Sanchez et al., 1996),
we found both GFR-1 and Ret are highly expressed in these tissues at
E18. Significant loss in trigeminal and spinal cord motoneurons,
superior cervical ganglion neurons, and dorsal root ganglion neurons in
Ret- and GDNF-null mice (Durbec et al., 1996a; Moore et al., 1996;
Sanchez et al., 1996) is also well correlated with the coexpression of
Ret and the -receptors in these neurons (Table 1). In superior
cervical ganglia, where both GDNF and neurturin exhibit trophic
activities, both GFR-1 and GFR-2 are coexpressed with Ret.
Although its ligand is as yet unknown, GFR-3 is colocalized with Ret
in all tissues where it is expressed, including the dorsal root and
trigeminal ganglia (Figs. 1, 2, 4, 6, 7; Table 1). This suggests that
Ret may also serve as the signaling receptor for the GFR-3
ligand.
Both Ret and one or more of the -receptors are also
coexpressed in several tissues that are not known to be targets of
either GDNF or neurturin. For example, high levels of Ret and GFR-1 transcripts were detected in the retina and thalamus (Table 1). The
presence of Ret and the -receptors suggest that GDNF and related
trophic factors may be required for the survival of neurons in these
regions as well. The extensive coexpression suggests that the function
of GDNF and neurturin may be mediated by interaction in cis between Ret
and the -receptors expressed in the same neurons. This is consistent
with previous studies showing that coexpression of GFR-1 or GFR-2
with Ret in Neuro-2a cells is sufficient to mediate Ret activation by
GDNF or neurturin (Jing et al., 1996, 1997; Treanor et al., 1996).
Coexpression of Ret and the -receptors was observed in both pre- and
postnatal tissues (Table 1), suggesting that in cis interaction may be
important throughout rat development.
Differential expression of the -receptors in the targets
of Ret-positive neurons: potential interactions in trans
In several tissues examined, the -receptors are also expressed
at high levels without Ret. The most prominent examples are the lateral
septum, whiskerpads, cortex, and superior colliculus. These regions
transcribe high levels of GFR-1 and/or GFR-2 mRNAs but with no
significant Ret expression. These observations in developing rats are
similar to previously reported expression patterns of GFR-1 and
Ret in the adult brain (Trupp et al., 1997). The lack of Ret expression
in these sites suggests that the -receptors may function by
alternate mechanisms. It has been proposed that the -receptors may
serve as GDNF or neurturin reservoirs to capture and present their
ligands in trans to attract Ret-expressing axons, thus serving as
target-derived chemotactic or trophic factors to guide incoming axons
(Trupp et al., 1997). Consistent with this proposal, the -receptors
are expressed in several regions that are targets of Ret-expressing
neurons. These regions include the vibrissae, which is innervated by
the trigeminal sensory neurons expressing high levels of Ret. Likewise,
the high levels of GFR-1 and GFR-2 in the lateral septum may trap
GDNF and neurturin and serve as chemotactic signals for incoming
Ret-positive axons from neurons in hippocampal CA3 region. In addition,
the presence of high GFR-2 expression in cortical layer 4, the
specific target layer for thalamic neurons that transcribe high levels
of Ret, provides further support to a possible role of GDNF family
ligands and receptors in neuron-target interactions. It is
intriguing to note that low levels of GFR-2 transcripts were
observed in cortical layers 5 and 6 as well but that no expression was
observed in layer 2/3. These observations suggest that incoming
thalamic axons may be promoted to grow into the cortex across layers 5 and 6 to end in layer 4, where the highest level of GFR-2 expression has been found.
Although more detailed analyses are needed to examine the precise
temporal regulation of expression, the presence of both Ret and the
-receptor transcripts in trigeminal, thalamocortical, and the
retinotectal systems at E18, a time when active ingrowth of axons into
their targets occurs, is consistent with roles in neuron-target
interactions. The ingrowth of the hippocampal axons to the lateral
septum occurs from E21 to P14 in the rat (Linke et al., 1995). Thus the
delayed expression of Ret in the hippocampal CA regions also correlates
with the timing of axonal growth into the septal target. Taken
together, the complementary expression of Ret and the -receptors in
projecting and target fields supports the view that the signaling and
the ligand-binding receptors may interact in trans to regulate
neuron-target interactions.
Activation of Ret tyrosine kinase in trans by GDNF/GFR-1
complex in vitro
A critical prediction of the proposal that Ret may interact with
the -receptors in trans is that the -receptors provided from
outside the Ret-expressing cells should be able to mediate Ret
activation by GDNF or neurturin. To test this prediction, we examined
the ability of both soluble and protein A-Sepharose bead-immobilized
GDNF/GFR-1/Fc complex to activate Ret tyrosine kinase expressed on
the surface of Neuro-2a cells. Both the soluble and the immobilized
complex greatly stimulated Ret kinase activity, even though it was
provided in trans. Our observations confirm and extend previous studies
that showed that GDNF and neurturin activate Ret kinase in the presence
of soluble GFR-1 and GFR-2 (Jing et al., 1996; Treanor et al.,
1996; Klein et al., 1997), providing further biochemical support for a
functional interaction in trans.
Multiple mechanisms of regulation of nervous system development by
the GDNF family trophic factors
Target-derived neurotrophic factors play key roles in maintaining
the survival and integrity of the efferent neurons and pathways in the
nervous system. The ability of the GDNF family ligands to maintain
neuronal survival suggests that these molecules may serve as
target-derived factors to regulate the survival of projecting neurons
and to provide attractive guidance to incoming Ret-positive axons.
The expression patterns revealed here suggest that there are many
mechanisms to regulate neuronal survival and neuron-target interaction
by the GDNF family trophic factors and their receptors. For neurons
coexpressing Ret and one of the -receptors, expression of GDNF or
related ligands in the target tissues would be sufficient to generate
target-derived attractive guidance cues or survival signals. It is
important to note that these target-derived factors may serve as
positive guidance cues or survival signals or both. Evidence that GDNF
and neurturin are transcribed in the striatum, the projection target of
the substantia nigra neurons that express both Ret and GFR-1,
supports this proposal (Schaar et al., 1993; Stromberg et al., 1993;
Springer et al., 1994; Suvanto et al., 1996; Trupp et al., 1997;
Widenfalk et al., 1997). An alternative mechanism is to express
-receptors to serve as traps for GDNF and related ligands in the
target tissues. These ligand and GFR complexes may then interact in
trans with Ret expressed on incoming axons. In this study, we present
evidence that the -receptors are indeed expressed in targets of
Ret-expressing neurons in several systems including the trigeminal,
hippocamposeptal, thalamocortical, and the retinotectal pathways. We
further demonstrated that in vitro Ret can be activated
efficiently in trans by the GDNF/GFR-1 complex, supporting a key
role for the -receptors in target regulations of the projecting
neurons.
Because GDNF and related trophic factors are diffusible, it may be
difficult to restrict these factors to particular regions of the brain.
Furthermore, peripheral sources such as the kidney may provide high
levels of GDNF or neurturin throughout the brain during development
before the blood-brain barrier has been established. Therefore the
highly localized expression of the -receptors may thus provide a key
mechanism for the functional specificity of GDNF and related trophic
factors. Taken together, the actions of the GDNF family ligands in
neuronal survival and/or neuron-target interactions are likely to be
regulated by multiple mechanisms.
| |
FOOTNOTES |
Received Feb. 17, 1998; accepted March 31, 1998.
This research is funded in part by National Science Foundation Grant
IBN-9409930, NIH Grant IROINS 36788-01, and by a grant from the
Alzheimer's Foundation. We acknowledge M. Fang, Z. Hu, and M. Qi for
construction of the probes used in in situ hybridization experiments and G. W. Mcauliffe and D. Crockett for insightful help in histology.
T.Y. and S.S. contributed equally to this work.
Correspondence should be addressed to Dr. Renping Zhou, Laboratory for
Cancer Research, Department of Chemical Biology, College of Pharmacy,
Rutgers University, Piscataway, NJ 08855 or Dr. Shuqian Jing, Amgen
Inc., Amgen Center, Thousand Oaks, CA 91320-1789.
| |
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Abstract
Introduction
