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The Journal of Neuroscience, July 1, 1998, 18(13):4929-4937
Neurturin Exerts Potent Actions on Survival and Function of
Midbrain Dopaminergic Neurons
Brian A.
Horger1,
Merry
C.
Nishimura1,
Mark P.
Armanini1,
Li-Chong
Wang1,
Kris T.
Poulsen1,
Carl
Rosenblad6,
Deniz
Kirik6,
Barbara
Moffat2,
Laura
Simmons3,
Eugene
Johnson Jr5,
Jeff
Milbrandt4,
Arnon
Rosenthal1,
Anders
Bjorklund6,
Richard A.
Vandlen2,
Mary A.
Hynes1, and
Heidi S.
Phillips1
Departments of 1 Neuroscience,
2 Protein Chemistry, and
3 Molecular Biology, Genentech, South San
Francisco, California 94080, Departments of
4 Pathology and
5 Pharmacology, Washington University Medical
School, St. Louis, Missouri 63110, and
6 Wallenberg Neurocentrum Institute, Lund, Sweden
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ABSTRACT |
Glial cell line-derived neurotrophic factor (GDNF) exhibits potent
effects on survival and function of midbrain dopaminergic (DA) neurons
in a variety of models. Although other growth factors expressed in the
vicinity of developing DA neurons have been reported to support
survival of DA neurons in vitro, to date none of these factors duplicate the potent and selective actions of GDNF in vivo. We report here that neurturin (NTN), a homolog of GDNF, is expressed in the nigrostriatal system, and that NTN exerts potent
effects on survival and function of midbrain DA neurons. Our findings
indicate that NTN mRNA is sequentially expressed in the ventral
midbrain and striatum during development and that NTN exhibits
survival-promoting actions on both developing and mature DA neurons.
In vitro, NTN supports survival of embryonic DA neurons,
and in vivo, direct injection of NTN into the substantia nigra protects mature DA neurons from cell death induced by 6-OHDA. Furthermore, administration of NTN into the striatum of intact adult
animals induces behavioral and biochemical changes associated with
functional upregulation of nigral DA neurons. The similarity in potency
and efficacy of NTN and GDNF on DA neurons in several paradigms stands
in contrast to the differential distribution of the receptor components
GDNF Family Receptor  1 (GFR1) and GFR2 within the ventral
mesencephalon. These results suggest that NTN is an endogenous trophic
factor for midbrain DA neurons and point to the possibility that GDNF
and NTN may exert redundant trophic influences on nigral DA neurons
acting via a receptor complex that includes GFR1.
Key words:
neurturin; GDNF; dopaminergic; trophic; Parkinson's; nigrostriatal; 6-OHDA
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INTRODUCTION |
Glial cell line-derived neurotrophic
factor (GDNF) exhibits potent effects on the survival and function of
midbrain dopaminergic neurons both in vitro and in
vivo (Lin et al., 1993 ; Hoffer et al., 1994; Beck et al., 1995;
Bowenkamp et al., 1995; Hudson et al., 1995; Sauer et al., 1995; Gash
et al., 1996; Hebert et al., 1996). The GDNF receptor complex consists
of two critical elements, both of which are expressed on nigral
dopaminergic (DA) neurons: GDNF Family Receptor 1 (GFR1), a
glycosyl phosphatidylinositol (GPI)-linked protein that exhibits
high-affinity binding for GDNF, and the tyrosine kinase ret (Durbec et
al., 1996; Jing et al., 1996; Treanor et al., 1996; Trupp et al.,
1997). Recent studies have revealed that neurturin (NTN), a homolog of
GDNF, promotes the survival of GDNF-responsive populations of
peripheral neurons (Moore et al., 1996) and that ret is a shared
signaling component of the GDNF and NTN receptor complexes (Kotzbauer
et al., 1996; Sanchez et al., 1996; Sanicola et al., 1997). Together
with a recent report that NTN mRNA is present in the developing
striatum (Widenfalk et al., 1997), these data suggest the possibility
that NTN may influence the development or function of midbrain
dopaminergic neurons.
The present study assessed the actions of NTN on midbrain DA neurons
both in vitro and in vivo. In investigating the
potential actions of NTN on midbrain DA neurons, we confirmed and
extended previous observations on the distribution of mRNA for NTN and components of its receptor complex. In addition, we investigated whether NTN can influence the survival and function of midbrain DA
neurons and examined the possibility that this factor might demonstrate
efficacy in an animal model of Parkinson's disease.
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MATERIALS AND METHODS |
In situ hybridization. For in situ
hybridization, mouse embryos were immersion-fixed overnight at 4°C in
4% paraformaldehyde, cryoprotected overnight in 15% sucrose, and
frozen over liquid nitrogen. Postnatal day 1 (P1) and adult mouse
brains were freshly frozen with powdered dry ice. All tissues were
sectioned at 16 µm and processed for in situ hybridization
by a method described previously using
[33P]UTP-labeled RNA probes (Klein et al., 1997).
Sense and antisense probes for NTN were synthesized from a
238-nucleotide DNA fragment of NTN that included nucleotides 351-588
(Kotzbauer et al., 1996) using T7 polymerase. Probes for GFR1 and
GFR2 were as previously described (Klein et al., 1997).
Autoradiographic exposure times were 7 weeks for NTN mRNA and 5 weeks
for GFR1 and GFR2.
For combined immunocytochemistry and in situ hybridization,
adult rats were perfused with 4% paraformaldehyde, and brains were
removed and post-fixed overnight in the same fixative, cryoprotected overnight in 15% sucrose, frozen in dry ice, and sectioned at 35 µm.
Free-floating sections were immunostained for tyrosine hydroxylase (TH)
using immunoperoxidase labeling. Briefly, sections were incubated for 1 hr at 4°C with rabbit anti-TH primary antibody (Chemicon
International, Temecula, CA; AB152, 1:500) followed by goat anti-rabbit
IgG (Vector Laboratories, Burlingame, CA; 1 mg/ml, 30 min at 4°C),
and ABC elite reagent (Vector PK 6100, used at one-half of the
manufacturer's recommended concentration, 30 min at 4°C) each in 0.1 M Tris HCl, pH 7.5, with 0.9% NaCl and 0.1% gelatin. All
incubations were separated by rinses in the same buffer system. For
chromogenic reaction, a DAB substrate kit (Vector SK-4100, 2 min at
20°C) was used. After immunostaining, sections were mounted onto
slides, air-dried, and subjected to in situ hybridization
for GFR2 or GFR1 as described above.
In vitro survival study. Cultures enriched for DA
neurons of the ventral mesencephalon were obtained from embryonic day
14 (E14) rats (plug = E0). Tissues were dissected, treated with
enzyme, triturated to a single cell suspension, and plated as
previously described (Poulsen et al., 1994) with a few exceptions.
Cells were plated on glass coverslips that were placed in 24-well
plates. The concentration of insulin in the medium was decreased from 5 to 2.5 µg/ml. All factors were added once at the time of plating. They were resuspended in 1 mM HCl and diluted with media.
After 4 d the cultures were fixed, stained for TH (Chemicon), and
counted, as described previously (Hynes et al., 1994; Poulsen et al.,
1994).
In vivo survival study: single intranigral injections of
NTN or GDNF. Lesioning, administration of trophic factors, and
analysis of cell survival were conducted as described previously, with minor modifications (Sauer et al., 1995). Forty-five female Sprague Dawley rats (Charles River Laboratories, Hollister, CA) weighing 230-250 gm received injections into both the right and left striata with 0.2 µl of a 3% solution of fluorogold (FG; Fluorochrome Inc., Englewood, CO). Stereotaxic coordinates relative to bregma and dura
were: anteroposterior (AP), +0.5 mm; mediolateral (ML), ±2.8 mm; and
ventrodorsal (VD),  4.5 mm (incisor bar set at 0 mm). One week after
FG administration, a single unilateral injection of 20 µg of 6-OHDA
(Sigma, St. Louis, MO) in 2.8 µl of saline, supplemented with 0.2 mg/ml L-ascorbic acid, was injected into the right striatum
only, using the same stereotaxic coordinates. Seven days after
lesioning, animals were divided into five groups: vehicle-treated
(n = 16); NTN-treated (1 µg, n = 7;
and 10 µg, n = 7); and GDNF-treated (1 µg,
n = 7; and 10 µg, n = 8). Animals were anesthetized, and vehicle, NTN, or GDNF (1 or 10 µg) was injected into the right substantia nigra in a volume of 2 µl of 1 mM HCl (AP, 5.2 mm; ML, 2.0 mm; and VD, 7.0 mm
relative to bregma and dura; incisor bar set at 3.3 mm). All
injections were made with a 26 gauge needle attached to a 10 µl
Hamilton syringe. All surgery was performed under aseptic conditions
following National Institutes of Health animal care guidelines.
Four weeks after lesion, animals were deeply anesthetized and perfused
with 4% paraformaldehyde. Brains were removed, placed into 4%
paraformaldehyde at 4°C overnight for post-fixation, and then placed
into 30% sucrose before freezing and sectioning. Sections were cut at
35 µm using a freezing sliding microtome. Lesions were verified by TH
staining of sections of the striatum. One animal (NTN-treated) was
eliminated from the study, because it showed no evidence of a striatal
lesion.
For cell counts, 10 serial sections through the substantia nigra were
used. Five sections spaced at 70 µm intervals were used for FG cell
counts, and five alternating sections were processed for TH
immunocytochemistry. The most anterior section of the area sampled
corresponds to the anterior extent of the region in which the pars
compacta of the substantia nigra is separated from the ventral
tegmental area by the medial terminal nucleus of the accessory optic
tract. For counts of FG+ cells, labeled cells exhibiting at least one
neurite and polygonal shape in the substantia nigra were counted at
100× and 200× magnification using fluorescent illumination. Five
sections adjacent to those used for FG counting were processed
free-floating for TH immunocytochemistry using Chemicon anti-TH at a
dilution of 1:1000 and the Vector ABC elite kit with very intense
purple substrate. For TH+ and FG+ cell counts, both the
lesioned-treated and unlesioned sides were counted. For each animal,
the sum of the cells counted on all five sections of the lesioned side
is expressed as a percentage of the total number of cells counted on
all five sections of the unlesioned side. The mean percentages
(lesioned vs unlesioned side) of FG+ and TH+ cells for each group are
reported.
In vivo survival study: multiple intranigral injections of
NTN. In a separate study, 6-OHDA-lesioned female Sprague Dawley rats (B & K Universal, Stockholm, Sweden) weighing 225 gm received repeated injections of NTN into the substantia nigra. In this multiple-injection paradigm, coordinates for FG administration were
slightly modified (AP, +1.0 mm; ML, ±3.0 mm; and VD, 5.0 mm,
relative to bregma and dura with incisor bar at 0 mm). One week after
FG injection, 6-OHDA was administered into the right striatum using the
above coordinates. At the time of 6-OHDA administration, subjects were
implanted with a 22 gauge guide shaft positioned in the scull bone
dorsal to the substantia nigra. Over a 3 wk period, starting 3 d after
6-OHDA administration, seven injections of 5 µg of NTN in 2 µl of 1 mM HCl (n = 6) or vehicle alone
(n = 8) were administered every third day through the
guide shaft using a 28 gauge injection cannula. The rats were killed
5 d after the last injection. To avoid repeated trauma to the
substantia nigra, injections were made ~1 mm dorsal to the pars
compacta using the following coordinates, relative to bregma and dura: AP, 5.0 mm; ML, 2.5 mm; and VD, 6.0 mm (incisor bar set at 3.3
mm).
For histological evaluation, 30 µm sections were cut through the
substantia nigra. Three sections at the level of the medial terminal
nucleus spaced at 120 µm intervals were used for counting of FG+
cells, and three adjacent sections processed for TH immunocytochemistry were used for TH+ cell counts. A third series was processed for FG and
TH double labeling using Cy3-labeled secondary antibodies.
In vivo functional study. These experiments assessed the
effects of NTN or GDNF on nonlesioned nigrostriatal dopaminergic functioning. Male Sprague Dawley (Charles River) rats (280-300 gm;
n = 80) received a unilateral injection of one of three
doses of NTN or GDNF (0.1, 1, or 10 µg) or vehicle (1 mM
HCl) into the right striatum (flat skull coordinates relative to bregma
and dura: AP, +0.5 mm; ML, 2.8 mm; and VD, 4.5 mm). The 2 µl
injection volume was delivered over 5 min using a 26 gauge 10 µl
Hamilton syringe. The cannula was left in place for an additional 3 min after the injection.
After a 4 or 5 d recovery period, the subjects injected with
1 µg of NTN or GDNF, and vehicle-injected controls were tested for
spontaneous locomotor activity using an automated photocell arena (San
Diego Instruments). After a 30 min habituation period, subjects
received a saline injection (1 ml/kg, i.p.) and were monitored for
locomotor activity for 60 min. Twenty-four hours later, subjects were
tested for amphetamine-induced (1 mg/kg, i.p.) locomotor activity using
the same procedure.
One day subsequent to testing for amphetamine-induced locomotor
activity (7 d after intrastriatal injections), tissue from selected
brain regions was harvested. After decapitation, brains were removed
rapidly and chilled in ice-cold saline for 15 sec. Brains were sliced
into 1 mm coronal sections using a chilled stainless steel brain mold.
Anterior, central, and posterior striatal samples were harvested from
three sequential coronal sections using an 11 gauge punch. The central
striatal sections included the intrastriatal injection site. Nucleus
accumbens samples were harvested using a 13 gauge punch from coronal
brain slices corresponding to the anterior striatum. Substantia nigra
samples were collected using a 16 gauge punch centered in the medial
pars reticulata and included a small portion of the pars compacta
subregion.
The separation and quantification of DA and its major metabolite DOPAC
was conducted using ion pair reverse-phase HPLC with electrochemical
detection modified from that described previously (Horger et al.,
1995). A C18 octadecyl silica 3 µm minibore (3.2 × 100 mm)
column (Varian, Walnut Creek, CA) was perfused with a mobile phase
consisting of (in mM): 30 sodium citrate, 13.7 sodium
phosphate, 2.3 sodium octane sulfonic acid, and 0.025 EDTA with 6.5%
(v/v) acetonitrile, 0.6% (v/v) tetrahydrofuran, and 0.1% (v/v)
diethylamine, pH 3.1, at a constant rate of 1 ml/min. A Coulochem II
(ESA, Chelmsford, MA) electrochemical detector applied a 60 mV
potential to electrode 1 and a +200 mV potential to electrode 2 of a
coulometric analytical cell (model 5011). Protein content was
determined using the Bio-Rad (Richmond, CA) protein assay. Data from
the injected side were analyzed as a percentage of values obtained from
the noninjected hemisphere.
Recombinant GDNF and NTN. Rat GDNF was expressed in
Escherichia coli and purified using a modification of a
method described in earlier work (Henderson et al., 1994). The
insoluble fraction after lysis of E. coli cells was
suspended in 6 M guanidine hydrochloride buffer, pH 8, and
treated with sodium sulfite (0.1 M) and sodium tetrathionate (10 mM) to sulfonate the cysteine residues
(4°C for 16 hr). After dialysis against 4 M urea buffer
and centrifugation, monomeric GDNF was partially purified by anion
exchange chromatography and then refolded in a buffer containing 4 M urea, 15% glycerol, 0.1 M phosphate, and 4 mM cysteine, pH 8, at 4°C. The GDNF dimer was then
purified by anion exchange, cation exchange, and hydrophobic interaction chromatography. The final pool was dialyzed exhaustively against 1 mM HCl, aliquoted, and lyophilized.
Human NTN was expressed in E. coli as a
histidine-tagged fusion protein. After lysis of the E. coli
cells and S-sulfonation of the cysteine residues, the monomeric NTN was
partially purified by metal affinity, cation exchange, and anion
exchange chromatography. Refolding and isolation of dimeric NTN was
similar to the method described above for GDNF.
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RESULTS |
NTN mRNA is expressed in the nigrostriatal system
Examination of NTN mRNA distribution by in
situ hybridization revealed NTN to be expressed within the
developing rodent nigrostriatal system, appearing sequentially within
the midbrain and striatum (Fig. 1). In
the mouse, from E11.5 to E13.5, as dopaminergic neurons are
differentiating, moderate to strong hybridization for NTN mRNA was
observed in the ventral midbrain. During later embryogenesis and early
postnatal life (E15.5 to P1), as nigral dopaminergic neurons extend
axonal projections to their target areas, NTN expression was maintained
at moderate levels within the ventral midbrain, and signal appeared at
moderate levels within the striatum. In the adult brain, modest
expression of NTN was maintained within the striatum, whereas only a
weak, inconsistent hybridization signal appeared in the substantia
nigra. The temporal pattern of NTN mRNA expression observed in the
mouse nigrostriatal system bears similarity to previous reports of GDNF
expression (Poulsen et al., 1994; Nosrat et al., 1996) and suggests
that NTN may exert influences on developing or adult nigral DA
neurons.
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Figure 1.
NTN mRNA appears sequentially in the ventral
midbrain (vm) and caudate putamen (cp) of
the developing mouse brain. Sections of E13.5 brain hybridized with
antisense probe to NTN (A) display strong
hybridization in the ventral midbrain (vm), whereas no
hybridization is seen in the developing caudate putamen
(cp) above the background seen with sense strand control
probe (B). At P1, (C, E, G) as
well as in the adult brain (D, F) hybridization
is seen in both the ventral midbrain and caudate putamen. The signal in
the adult caudate (F, H) is associated with cells
displaying a nuclear morphology characteristic of neurons. Scale bars:
B, E, F, 1 µm (these apply to A, C,
D, respectively); G, 1 µm;
H, 0.1 µm.
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NTN receptor components are expressed in and around nigral
DA neurons
Although GFR1 mRNA is prominently expressed in the pars
compacta of the substantia nigra and the ventral tegmental area, a more
modest and diffuse signal for GFR2 is observed in the ventral
midbrain (Fig. 2A,B).
In sections stained for TH, the majority of TH+ nigral cells displayed
equivocal signal for GFR2, whereas intense hybridization was
observed for GFR1 in association with TH+ cells of the substantia
nigra (Fig. 2C-I). Strong signal for GFR2 was,
however, observed in regions immediately adjacent to midbrain DA
neurons, including the dorsolateral aspect of the pars compacta of the
substantia nigra, the medial and lateral terminal nuclei of the
accessory optic tract, and the interpeduncular nuclei (Fig.
2C,D,G). Sections from animals killed at 1 week after intrastriatal 6-OHDA showed no evidence for upregulation of either GFR2 or GFR1 expression (data not shown).
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Figure 2.
mRNA for GFR2 is localized in the vicinity of
nigral DA neurons. GFR2 mRNA (A) expression is
much more diffuse and weak than GFR1 (B) in
the region of the pars compacta of the substantia nigra. Colocalization
of TH staining (brown) and in situ
hybridization for mRNA (white silver grains) for GFR2
(C) reveals that the majority of GFR2
expression in the adult ventral midbrain is not produced by DA neurons
but by cells residing nearby. In particular, a band of
GFR2-expressing cells is seen in a zone that is dorsolateral to the
pars compacta. D-F, Dark-field images of the same
sections shown under bright-field illumination in G-I.
All sections were immunostained for TH (brown).
In situ hybridizations were performed for GFR2
(D, G), GFR1 (E, H), and sense
strand control probe (F, I). Marginally more
silver grains are seen for GFR2 hybridization over TH+ cells
(D, G) than in sections hybridized with a sense
strand control probe to GFR1 (F, I). Scale
bars: B, 0.5 µm (applies to A);
C, I, 1 µm (I applies to
D-I).
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NTN promotes survival of DA neurons in vitro
To determine whether NTN can act to promote survival of midbrain
DA neurons, cultures of E14 rat ventral midbrain were investigated. This culture system revealed that, like GDNF, NTN can exert potent actions on the survival of TH-expressing cells from the developing midbrain (Fig. 3A). The
potency and efficacy of NTN was similar to that observed for GDNF.
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Figure 3.
NTN promotes survival of midbrain DA neurons
in vitro and in vivo. Values in
A-C represent mean ± SEM; *p < 0.05; **p < 0.0001 (vs control).
A, NTN promotes survival of TH+ cells in cultures of E14
rat ventral mesencephalon. Survival responses to maximally effective
concentration of NTN are very similar to those seen with optimal doses
of GDNF. B, Single bolus injection of NTN can provide
partial protection of FG+ or TH+ nigral cells after intrastriatal
6-OHDA administration. Single intranigral injections of 1 or 10 µg of
NTN or GDNF, administered 1 week after the toxic insult, produce
comparable sparing of FG+ cells after 6-OHDA. A single intranigral
injection of 10 µg of NTN can produce sparing of TH+ cells, whereas 1 µg is not effective. Note the comparable effects of similar doses of
GDNF and NTN at both doses on TH+ cells. C, Repeated
administration of NTN rescued all FG+ cells, but because a high
proportion of the FG+ cells were TH-negative, the TH+ cell number was
not significantly increased in the NTN-treated rats. In a series of
double-labeled sections, the percentage of FG+ cells that expressed TH
was reduced not only in the NTN-treated nigra but also in the controls
treated with vehicle alone (from 80 ± 3% on the nontreated
intact side to 52 ± 6% on the treated side), indicating a
potential deleterious effect of repeated administration of the acidic,
hypotonic vehicle (data not shown). D, Appearance of FG+
nigral cells after neurotoxic insult and rescue with GDNF or NTN. The
top left panel represents a control substantia nigra
(contralateral to 6-OHDA administration), whereas the top right
panel depicts a vehicle-treated substantia nigra 4 weeks after
ipsilateral intrastriatal 6-OHDA treatment. The lesioned nigra shows
very few surviving neurons but many small cells of microglial
morphology. The bottom panels demonstrate that a single
bolus injection of 10 µg of either NTN or GDNF protects the survival
of many fluorogold-labeled neurons at 4 weeks after 6-OHDA
administration. E, Appearance of TH+ cells after
neurotoxic insult and rescue with GDNF or NTN. Top left
and top right panels depict substantia nigra 4 weeks
after 6-OHDA to the contralateral (left) or ipsilateral
(right) striatum. The brain in the top right
panel was treated by injection of vehicle into the pars
compacta of the substantia nigra. Partial protection of TH-expressing
cells is seen after a single bolus injection of 10 µg of either NTN
or GDNF into the pars compacta.
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NTN promotes survival of DA neurons in vivo after
6-OHDA exposure
The ability of NTN to promote survival of embryonic rat midbrain
DA neurons in vitro raised the possibility that NTN might be
effective in promoting survival of DA neurons in the adult brain. In
examining the ability of an intranigral injection of NTN to promote the
survival and TH expression of DA neurons after striatal 6-OHDA
administration, we observed that the efficacy of single injections of
NTN is similar to that of comparable doses of GDNF (Fig.
3B,D,E). Our results indicated that a single intranigral injection of NTN, administered 1 week after the toxic insult, can lead
to a significant sparing of nigral DA neurons, identified either by the
retrograde tracer FG or by immunocytochemistry for TH (Fig.
3B,D,E).
To determine whether NTN may act on a subset of nigral DA neurons or on
the entire population, we examined the ability of repeated injections
of NTN to rescue DA neurons. Using the same lesion paradigm used above,
repeated administration of NTN over the substantia nigra (5 µg every
third day for 3 weeks) resulted in a complete protection of FG+ cells
(Fig. 3C). The complete rescue of FG+ cells suggested that,
like GDNF (Sauer et al., 1995), NTN was capable of influencing all
nigral DA neurons. Although repeated administration of NTN is capable
of promoting the survival of all retrogradely labeled nigral cells, the
paradigm used here did not maintain TH expression of surviving neurons.
In contrast to a single injection of NTN (Fig. 3B,D,E),
repeated intranigral administration did not significantly increase the
number of TH+ neurons in the substantia nigra (Fig. 3C).
NTN upregulates neurochemical and behavioral parameters of DA
neuron function
Locomotor activity was assessed after injection of 1 µg of NTN
and GDNF into the right striatum. As depicted in Figure
4A, locomotor activity
after an intraperitoneal injection of saline was not altered by NTN or
GDNF administration into the striatum. By contrast, locomotor activity
induced by systemic administration of amphetamine (1 mg/kg, i.p.) was
augmented after an intrastriatal injection of NTN or GDNF. As
illustrated in Figure 4B, there was no difference
between groups in the 30 min preinjection habituation period. After the
amphetamine challenge, however, control subjects exhibited a moderate
increase in activity counts peaking 20 min after injection. This
amphetamine-induced increase in locomotor activity was significantly
augmented in both NTN- and GDNF-injected subjects (Fig.
4B). Relative to controls, activity counts of
NTN-injected subjects were significantly elevated at all postinjection
time points except the first. In the GDNF-injected group a significant increase in locomotor activity was observed at the 30, 40, and 50 min
postamphetamine time points.
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Figure 4.
Intrastriatal injection of NTN or GDNF augments
amphetamine-induced locomotor activity and increases striatal DA
utilization. A, B, Injections of NTN or GDNF (1 µg)
into the right hemisphere do not significantly alter spontaneous
open-field locomotor activity but do augment amphetamine-induced
locomotor activity. A, B, Mean ± SEM number of
interrupted photocell beams 30 min before and 60 min after saline
(A) or amphetamine (1 mg/kg, i.p.)
(B) administration. Asterisks
indicate significant differences from vehicle-injected controls
(p < 0.05). C, Mean ± SEM ratio of the metabolite DOPAC to DA in each brain region sampled 1 week after unilateral administration of NTN, GDNF, or vehicle in the
right striatum. Data are depicted as percent of the noninjected
(intact) hemisphere. Significant increases from vehicle-injected
controls as determined by Fisher's post hoc analyses
are indicated by an asterisk
(p < 0.05). Except for the 1 and 10 µg
doses of NTN in the posterior striatum, individual doses within the
same treatment group were significantly different from each other
(p < 0.05). Subsequent comparisons revealed
a significantly greater effect of the 0.1 µg dose of NTN relative to
the same dose of GDNF at all three striatal sites. In the nucleus
accumbens, DA utilization was increased by both 1 and 10 µg doses of
GDNF, whereas only the highest dose of NTN reached significance.
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Because NTN and GDNF were administered unilaterally (right striatum),
all neurochemical data are expressed as a percentage of the noninjected
hemisphere. Table 1 lists the absolute
values of DA (nanograms per milligram of protein) recovered from each brain region of control animals along with ratios of the major metabolite DOPAC to DA (DA utilization). Relative to controls, no
significant differences in tissue content of DA were observed in any
region after NTN or GDNF administration (data not shown). There were,
however, significant differences in DA utilization observed in the NTN-
and GDNF-administered groups relative to vehicle-injected controls.
Individual one-way ANOVAs for NTN- and GDNF-injected subjects for each
brain region revealed significant effects on DA utilization after
intrastriatal NTN or GDNF in all three striatal regions and the nucleus
accumbens (Fig. 4C). Post hoc analyses indicated
dose-dependent increases in DA utilization in each striatal region
(p < 0.05). In the nucleus accumbens, significant increases in DA utilization were observed after
administration of 1 and 10 µg of GDNF and 10 µg of NTN
(p < 0.5).
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DISCUSSION |
The potent actions of GDNF on midbrain DA neurons and its presence
in the developing nigrostriatal system support the hypothesis that GDNF
may serve as a trophic factor for midbrain DA neurons (Lin et al.,
1993; Hoffer et al., 1994; Beck et al., 1995; Bowenkamp et al., 1995;
Hudson et al., 1995; Sauer et al., 1995; Gash et al., 1996; Hebert et
al., 1996); however, mice deficient in GDNF show no loss of these cells
(Moore et al., 1996). These findings raise the possibility that DA
neurons may be controlled during development by redundant trophic
influences. Although other growth factors localized to the vicinity of
developing DA neurons exhibit survival-promoting effects in
vitro, actions of these factors in vivo have been
disappointing (Hynes et al., 1994; Poulsen et al., 1994; Sauer et al.,
1995; Jordan et al., 1997). Given the ability of NTN, a recently
described homolog of GDNF, to promote survival of GDNF-responsive
populations of peripheral neurons (Kotzbauer et al., 1996), we sought
to determine whether NTN might exhibit trophic activities on midbrain
DA neurons.
We report here that NTN expression is developmentally regulated in the
nigrostriatal system and that NTN exhibits potent actions on the
survival and function of midbrain DA neurons. Our results indicate that
NTN mRNA is sequentially expressed in the ventral midbrain and
striatum, indicating that NTN protein is likely to be available to both
developing and mature nigral DA neurons. Furthermore, we find in three
separate paradigms that NTN is at least as potent and efficacious as
GDNF in stimulating midbrain DA neuron survival or function. These
results indicate that midbrain DA neurons are as responsive to NTN as
to GDNF and point to the possibility that these homologous factors may
act in concert to regulate the development and/or function of midbrain
DA neurons.
Both in vitro and in vivo assays revealed NTN to
be a potent factor in dopaminergic neuron cell survival. In direct
comparisons, the potency and efficacy of NTN on survival of DA neurons
was indistinguishable from that observed for GDNF. In vitro,
optimal concentrations of GDNF and NTN support the same number of
midbrain DA neurons, and each agent showed maximal effects between 10 and 100 ng/ml. To date, no clear additive effects of GDNF and NTN have
been observed in this culture system. In vivo, a single
administration of either NTN or GDNF led to a nearly threefold increase
in surviving nigral cells (as detected by the retrograde tracer
fluorogold) after intrastriatal injection of 6-OHDA. In addition, a
single injection of NTN (10 µg) significantly increased the number
TH-expressing neurons in the substantia nigra. These findings indicate
that NTN is capable of promoting the survival and maintenance of TH expression of both embryonic and adult nigral DA neurons.
Repeated intranigral injections of NTN effectively rescued all
fluorogold-labeled cells, strongly suggesting that all nigral DA
neurons are responsive to NTN. The failure of repeated nigral injections of NTN to promote protection of TH expression stands in
contrast to the effects seen with a single bolus of NTN and to previous
observations on GDNF (Sauer et al., 1995). It should be noted, however,
that the current study used smaller quantities and less frequent
injections of NTN (7 × 5 µg) than were previously used for GDNF
(14 × 10 µg) and that the vehicle used differed in the two
studies. In this regard, the possible deleterious effects of multiple
injections of a nonphysiological (acid) vehicle on TH expression should
not be overlooked (Fig. 3C, legend). Regardless of the
actions of NTN on TH expression, the ability of NTN to produce a
complete rescue of FG+ cells argues that NTN is capable of influencing
the entire population of nigral DA neurons.
In addition to the survival-promoting effects of NTN, we observed that
intrastriatal administration of NTN produced a dose-dependent increase
in DA utilization in the striatum. The biochemical effects of
intrastriatal administration of NTN or GDNF were accompanied by an
augmentation of amphetamine-induced locomotor activity, a behavioral
index of functional activation of the nigrostriatal pathway. Although
both NTN and GDNF produced an increase in striatal DA utilization, the
data suggest that GDNF may be less efficacious than NTN at lower doses.
Increased striatal DA utilization was significantly greater in response
to the lowest dose of NTN tested (0.1 µg) relative to the same dose
of GDNF (Fig. 4). Further studies are needed to determine whether these
results reflect differences in the responsiveness of nigral neurons to
equivalent concentrations of the two growth factors or whether
differences in distribution and stability of the proteins may account
for the apparent differences in activity. Similarly, the greater
neurochemical effects of GDNF in the nucleus accumbens relative to NTN
may reflect differential responsivity of mesoaccumbal DA neurons or may
reflect greater diffusion of GDNF from the intrastriatal injection site
into the nucleus accumbens.
Recent studies have revealed that the GPI-linked protein GFR2, (also
referred to as TrnR2, NTN-R, or GDNFR ), exhibits high-affinity binding for NTN and, together with the tyrosine kinase ret, can form a
signaling complex for NTN (Baloh et al., 1997; Buj-Bello et al., 1997;
Klein et al., 1997). Thus, the tyrosine kinase ret is a shared
signaling component of the GDNF and NTN receptor complexes (Kotzbauer
et al., 1996; Sanchez et al., 1996; Sanicola et al., 1997). These same
studies have yielded mixed results about the potency with which NTN can
interact with GFR1 but indicate that under some conditions GFR1
can participate in NTN signaling (Baloh et al., 1997; Buj-Bello et al.,
1997; Klein et al., 1997; Sanicola et al., 1997). Localization studies
to date have revealed the presence of both GFR1 and ret on nigral DA
neurons. The relationship of GFR2 expression in the ventral midbrain
to the location of DA neurons is less clear, but one report indicates
that GFR2 mRNA in the region of the substantia nigra is not
associated with DA neurons (Widenfalk et al., 1997).
The present results confirm and extend previous observations on the
distribution of GFR2 in the ventral mesencephalon of the adult rat
(Klein et al., 1997; Widenfalk et al., 1997). Consistent with previous
reports, GFR1 mRNA is prominently expressed in the pars compacta of
the substantia nigra and the ventral tegmental area, whereas a more
modest and diffuse signal for GFR2 is observed in the region of the
substantia nigra. Hybridizations performed on sections immunostained
for the presence of TH reveals the presence of little, if any, GFR2
mRNA in nigral DA neurons. These results are consistent with the
observation that GFR2 does not colocalize with TH+ cells in the E14
rat ventral mesencephalon (Wang et al., 1997). Assuming that NTN
signals via a complex involving GFR2 and ret, the similarity of
potency and efficacy of NTN and GDNF on DA neurons is difficult to
reconcile with the relative lack of GFR2 expression on DA neurons.
Although we cannot rule out the possibility that NTN signals via low
levels of GFR2 present on the surface of DA neurons, our data point
to the possibility that NTN might signal in vivo through
GFR1. Alternatively, it is possible that GFR2 expressed by cells
in the vicinity of nigral DA neurons may be presented to nigral DA
neurons either by cell-cell contact or by shedding and diffusion of
protein. The ability of soluble GFR2 to act in vitro to
confer responsiveness of motor neurons to NTN (Klein et al., 1997)
supports this possibility.
The current findings indicate that NTN is expressed in the developing
and adult nigrostriatal system and can exert potent influences on the
survival and phenotypic expression of nigral dopaminergic neurons.
Furthermore, the data indicate that NTN can upregulate nonlesioned
intact nigrostriatal DA neurons. The potency and efficacy of NTN is
equal or greater than that observed for GDNF on all measures of
nigrostriatal survival or function investigated. Taken together, these
results suggest that NTN might be an endogenous trophic factor for DA
neurons and point to the possibility that NTN might be a useful agent
to treat Parkinson's disease.
| |
FOOTNOTES |
Received Dec. 11, 1997; revised April 7, 1998; accepted April 15, 1998.
This work was supported in part by National Institutes of Health Grants
RO1AG13729 and RO1AG13730 and by Grant 04X-3874 from the Swedish
Medical Research Council. We thank Wayne Anstine for preparation of
figures, Evelyn Berry for manuscript preparation, and Brigitte Devaux
for helpful suggestions and coordination of resources.
B.H. and M.N. contributed equally to this manuscript.
Correspondence should be addressed to Dr. Heidi Phillips, Genentech,
Inc., One DNA Way, South San Francisco, CA 94080.
| |
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Top
Abstract
Introduction
