 |
 Previous Article | Next Article 
The Journal of Neuroscience, March 15, 1999, 19(6):2131-2142
BDNF Is a Target-Derived Survival Factor for Arterial
Baroreceptor and Chemoafferent Primary Sensory Neurons
Roseann
Brady,
Syed Ishrat Ali
Zaidi,
Catherine
Mayer, and
David M.
Katz
Department of Neurosciences, Case Western Reserve University School
of Medicine, Cleveland, Ohio 44106-4975
 |
ABSTRACT |
Brain-derived neurotrophic factor (BDNF) supports survival of 50%
of visceral afferent neurons in the nodose/petrosal sensory ganglion
complex (NPG; Ernfors et al., 1994a ; Jones et al., 1994; Conover et
al., 1995; Liu et al., 1995; Erickson et al., 1996), including arterial
chemoafferents that innervate the carotid body and are required for
development of normal breathing (Erickson et al., 1996). However, the
relationship between BDNF dependence of visceral afferents and the
location and timing of BDNF expression in visceral tissues is unknown.
The present study demonstrates that BDNF mRNA and protein are
transiently expressed in NPG targets in the fetal cardiac outflow
tract, including baroreceptor regions in the aortic arch, carotid
sinus, and right subclavian artery, as well as in the carotid body. The
period of BDNF expression corresponds to the onset of sensory
innervation and to the time at which fetal NPG neurons are
BDNF-dependent in vitro. Moreover, baroreceptor
innervation is absent in newborn mice lacking BDNF. In addition to
vascular targets, vascular afferents themselves express high levels of
BDNF, both during and after the time they are BDNF-dependent. However,
endogenous BDNF supports survival of fetal NPG neurons in
vitro only under depolarizing conditions. Together, these data
indicate two roles for BDNF during vascular afferent pathway
development; initially, as a target-derived survival factor, and
subsequently, as a signaling molecule produced by the afferents
themselves. Furthermore, the fact that BDNF is required for survival of
functionally distinct populations of vascular afferents demonstrates
that trophic requirements of NPG neurons are not modality-specific but
may instead be associated with innervation of particular organ systems.
Key words:
aortic arch; baroreceptor; baroreflex; BDNF; carotid
body; carotid sinus; chemoreceptor; chemoreflex; neurotrophin; nodose
ganglion; petrosal ganglion
| |
INTRODUCTION |
Multiple growth factors are required
to support development of the full complement of primary sensory
neurons that innervate the cardiovascular, respiratory, and
gastrointestinal systems. Thus, null mutations in the genes encoding
brain-derived neurotrophic factor (BDNF; Ernfors et al., 1994a; Jones
et al., 1994; Conover et al., 1995; Liu et al., 1995; Erickson et al.,
1996), neurotrophin-3 (NT-3; Ernfors et al., 1994b; Farinas et al.,
1994), neurotrophin-4 (NT-4; Conover et al., 1995; Liu et al., 1995;
Erickson et al., 1996), and glial cell line-derived neurotrophic
factor (Moore et al., 1996) all result in loss of 40-60% of
neurons in the nodose/petrosal sensory ganglion complex (NPG), the
major source of visceral afferent innervation. The diversity of growth
factor requirements in this system may be partially explained by
sequential dependencies of some neurons on more than one factor.
Specifically, NT-3 and NT-4 appear to act relatively early during NPG
development compared with BDNF, suggesting that some neurons switch
trophic dependence with age (ElShamy and Ernfors, 1997). On the other
hand, >90% of NPG neurons die in double
bdnf/nt4 null mutants, and this loss is virtually
additive of the effects of single bdnf or nt4
homozygous mutations, indicating that BDNF and NT-4 support survival of
largely nonoverlapping populations of neurons (Conover et al., 1995;
Liu et al., 1995; Erickson et al., 1996).
Despite the fact that the NPG complex is one of the major sites of
neuronal loss in BDNF, NT-3, and NT-4 null mutants, the relationship
between growth factor dependence and the location and timing of
neurotrophin expression in visceral target tissues is unknown. This
issue is further complicated by findings that NPG neurons themselves
express BDNF (Wetmore and Olson, 1995; Zhou et al., 1998) and that
endogenous BDNF, acting in an autocrine or paracrine manner, can
support survival of primary sensory neurons under some conditions in
culture (Acheson et al., 1995; Robinson et al., 1996b). It is also
unknown whether neurotrophin dependence is related to specific sensory
modalities, as proposed for somatosensory neurons (Snider, 1994), or
alternatively, to innervation of particular tissues or organ systems.
To approach these questions, the present study examined the
relationship between BDNF expression in developing visceral targets and
survival of visceral afferents, focusing in particular on arterial
baroreceptor neurons. Baroreceptor afferents are mechanosensitive NPG
neurons that innervate specialized regions of the cardiac outflow tract
and respond to changes in arterial blood pressure (Abboud and Thames,
1983). Baroreceptor afferents play a critical role in cardiorespiratory
homeostasis by buffering against rapid changes in arterial pressure
(Abboud and Thames, 1983), and loss of baroreceptor function during
development leads to increased variability in heart rate and blood
pressure (Itskovitz et al., 1983; Yardley et al., 1983). However,
mechanisms that underlie development of baroreceptor innervation are
unknown. Baroreceptor neurons are particularly advantageous for studies
of this kind for two reasons. First, innervation of arterial
baroreceptor targets is almost purely sensory and is therefore not
confounded by the presence of parasympathetic fibers or intrinsic
neurons, as in the other viscera. Second, we found previously that BDNF
is required for development of another population of cardiovascular
afferents, chemoafferent neurons innervating the carotid body (Erickson
et al., 1996). Therefore, chemoafferent and baroreceptor neurons provide a model for examining whether BDNF dependence of NPG neurons is
related to a particular sensory modality, such as chemosensation, or
alternatively, to innervation of a particular organ system, such as the
arterial vasculature.
| |
MATERIALS AND METHODS |
Animals
Pregnant Sprague Dawley rats were obtained from Zivic-Miller
Laboratories (Zelienople, PA). Mice carrying targeted mutations in
either the bdnf or nt4 gene (Conover et al.,
1995) were initially provided by Regeneron Pharmaceuticals (Tarrytown,
NY) and then bred in our institutional animal care facility.
Tissue collection for histological procedures
Newborn or postnatal day 0 (P0) and 1-week-old (P7) rat
and mouse pups were anesthetized with sodium pentobarbital (6 gm/kg, i.p.), perfused transcardially with fixative (see below), and tissues
were removed and post-fixed overnight. Fetuses were removed from
pregnant dams that were killed with carbon dioxide and then fixed
intact by immersion overnight. Two different fixatives were used
depending on the histochemical procedure: for in situ
hybridization and immunostaining with anti-protein gene product
(PGP) 9.5 antibodies, the fixative was 4% paraformaldehyde
(PFA) in 0.1 M sodium phosphate buffer, pH 7.4; for BDNF
and tyrosine hydroxylase (TH) immunostaining, the fixative was 2% PFA
in 0.07 M sodium phosphate buffer, pH 7.2, containing 0.2%
parabenzoquinone (Conner et al., 1997). Intact fetuses and P0 and P7
tissue samples were cryoprotected in 30% sucrose in PBS, pH
7.4, infiltrated with a 1:1 mixture of 30% sucrose-PBS and OCT
embedding medium (Tissue-Tek OCT-4583; Baxter Scientific, McGraw
Park, IL), embedded in OCT, frozen over dry ice, and cut in a cryostat
(10 or 14 µm sections). Tissues used for in situ
hybridization were processed under RNase-free conditions.
In situ hybridization
Rat cDNA, encoding prepro-BDNF (bp 1-1085, GenBank accession
number M61175; Maisonpierre et al., 1991) cloned into the EcoRI site of pBluescript SK( ) phagemid (Stratagene, La
Jolla, CA) and designated as BDNF[pSK-rB(C1)] was a gift from Dr.
G. D. Yancopoulos (Regeneron). The plasmid template was linearized by digestion with either XhoI or NotI to generate
the corresponding sense and antisense transcripts, under the T3 or T7
promoter, respectively. The restriction digest DNA was treated with
proteinase K and extracted with phenol-chloroform. cRNA probes were
synthesized using an RNA transcription kit (Stratagene) as per the
manufacturer's directions, in a reaction mixture containing 14 µCi/µl [ -35S]CTP (Dupont NEN, Boston, MA). The
reaction product was treated with DNase, and the labeled cRNA probes
were recovered by ethanol precipitation. The integrity of the probes
was confirmed by electrophoresis and autoradiography.
Two sets of adjacent tissue sections were treated briefly with protease
(125 µg/ml; Sigma, St. Louis, MO), acetylated with 0.25% (v/v)
acetic anhydride in 0.1 M triethanolamine-HCl, and dehydrated through a graded series of ethanol. Alternate sections were
then incubated overnight, either with sense or antisense probe (80 × 103 dpm/µl) diluted in hybridization solution
[20 mM Tris-HCl buffer, pH 7.4, 0.5 mg/ml tRNA, 0.1 M DTT, 50% formamide, 0.3 M NaCl, 10 mM NaH2PO4, 5 mM
EDTA, 10% dextran sulfate, and 1× Denhardt's solution (Sigma)] at
55°C in a humidified chamber. After hybridization, the slides were
washed for 30 min each in 5× SSC (0.3 M NaCl/0.03 M sodium citrate, pH 7.0) and 2× SSC containing 10 mM DTT at 55°C and treated with RNase A and RNase T1. The
slides were then washed for 30 min in 2× SSC containing 50% formamide
and 10 mM DTT at 65°C and twice for 30 min with 1× SSC
containing 0.066% sodium pyrophosphate and 15 mM DTT at
55°C. The sections were dehydrated through a series of graded ethanol
(30, 60, 80, and 95%) containing 0.3 M ammonium acetate,
then 100% ethanol, air-dried, exposed to radiographic emulsion (NTB2;
Eastman Kodak, Rochester, NY) for 4 weeks, developed in D-19 (Eastman
Kodak), counterstained with cresyl violet-acetate, and coverslipped
with Permount (Fisher Scientific, Pittsburgh, PA).
To verify the specificity of our probes, alternate sections through the
adult hippocampus and embryonic day 16.5 (E16.5) rat fetus were
hybridized with antisense and sense cRNAs and analyzed for antisense
labeling in areas previously shown to express BDNF mRNA. Hybridization
of adult hippocampal sections with the antisense probe resulted in
dense labeling of pyramidal cells in the CA2, CA3 (Fig.
1A), and hilus regions
with moderate labeling of CA1 pyramidal and dentate gyrus granule
cells. This pattern corresponds to previous studies using different
BDNF probes (Hofer et al., 1990; Wetmore et al., 1990; Conner et al.,
1997). In E16.5 fetuses, the antisense probe densely labeled various
neural and non-neural tissues previously shown to express BDNF mRNA,
including lingual papillae (Nosrat and Olson, 1995) and dorsal root
ganglia (Ernfors et al., 1992; Schecterson and Bothwell, 1992) and the
sensory epithelium in the vestibular labyrinth (Fig. 1C;
Ernfors et al., 1992; Pirvola et al., 1992; Ylikoski et al.,
1993; Schecterson and Bothwell, 1994). No signal was detected above
background levels in adult hippocampus or E16.5 fetuses after
hybridization with the sense probe (Fig.
1B,D).
View larger version (125K):
[in this window]
[in a new window]
|
Figure 1.
Localization of BDNF mRNA in control tissues.
Photomicrographs showing localization of BDNF mRNA in the CA3 region of
adult rat hippocampus (A) and in E16.5 vestibular
sensory epithelium (C). Adjacent sections showing
hybridization with sense cRNA probe (B,
D). Asterisks in B
indicate the CA3 region. Sections were counterstained with cresyl
violet. Scale bars, 100 µm.
|
|
Immunocytochemistry
PGP 9.5, neurofilament, and TH immunostaining. Tissue
sections and cultures were stained as previously described (Erickson et
al., 1996) using the following antisera: (1) rabbit anti-PGP 9.5 (1:1000; Accurate, Westbury, NY), (2) mouse anti-neurofilament (NF68,160, 1:100; Sigma), (3) rabbit anti-TH (1:200;
Pel-Freez Biologicals, Rogers, AR), (4) goat anti-rabbit IgG-FITC
(1:200; Boehringer Mannheim, Indianapolis, IN), or (5) goat anti-mouse IgG-rhodamine (1:200; Organon Teknika Cappel, Durham, NC). Whole-mount preparations were permeabilized in dilution buffer (DB; 0.02 M NaH2PO4, 0.02 M Na2HPO4, 0.5 M
NaCl, 0.3% Triton X-100, and 2% BSA, pH 7.4) containing an additional
0.6% Triton X-100.
BDNF immunostaining. Tissues were stained with rabbit
anti-BDNF (1:2000; Amgen, Thousand Oaks, CA) or double-stained with anti-BDNF and mouse anti-TH (1:500; Incstar, Stillwater, MN) as described below. The BDNF antibody does not cross react with NGF, NT-3,
or NT-4 and does not stain brain tissue sections taken from BDNF
knock-out mice (Yan et al., 1997b). BDNF staining was amplified using the Tyramide signal amplification kit (TSA-indirect kit; NEN Life
Science Products, Boston, MA). Sections were (1) quenched with 0.5%
H2O2, washed in DB for 1 hr, blocked
with avidin and biotin (Vector Laboratories, Burlingame, CA) for 15 min, then washed again in DB; (2) incubated overnight at room
temperature with anti-BDNF alone or in combination with anti-TH, in DB
containing 10% goat serum; (3) washed in DB and incubated with
biotinylated goat anti-rabbit IgG (1:200; Vector Laboratories, diluted
in PBS containing 10% goat serum) for 30 min; (4) washed in PBS and
incubated for 30 min with ABC Elite reagent (1:100 in 0.5 M
NaCl-PBS, Vector Laboratories); (5) washed in 0.5 M
NaCl-PBS followed by Tris buffer (0.1 M Tris-HCl, 0.15 M NaCl, and 0.5% Tween 20) and incubated for 4 min in
biotinyl Tyramide solution (1:50, TSA kit); and (6) washed in Tris
buffer (0.15 M NaCl in 0.1 M Tris-HCl) and then rinsed in Tris buffer containing blocking reagent (TSA kit) for 10 min.
For immunoperoxidase staining, the sections were incubated for 30 min
in ABC Elite reagent (1:50), washed with 0.5 M NaCl-PBS, washed with PBS, and reacted with 0.4% 3,3' diaminobenzidine
tetrahydrochloride diluted in PBS containing 0.03% NiCl2
and 0.008% H2O2. For immunofluorescence staining, the sections were incubated for 1 hr in streptavidin-FITC (1:100; Molecular Probes, Eugene, OR) instead of the second treatment with ABC Elite reagent, then washed in PBS, treated with
 -phenylenediamine and coverslipped with glycerol gel. For BDNF/TH
double-labeling, sections were first incubated at step 3 above in goat
anti-mouse Cy3 (1:200; Jackson ImmunoResearch, West Grove, PA)
for 1 hr, washed in DB, and then processed as described for
single-labeling. Control sections were stained as described above,
except that the primary antibody was omitted (see Fig. 8).
Histochemical staining for acetylcholinesterase was performed as
previously described (Katz and Karten, 1985).
Cell cultures
Pregnant dams were killed by exposure to carbon dioxide, and P0
rat pups were deeply anesthetized with sodium pentobarbital and then
decapitated. Petrosal ganglia were removed from E16.5 fetuses and
newborn pups and washed in Ca2+- and
Mg2+-free PBS (Life Technologies,
Gaithersburg, MD). Ganglia were digested in either dispase (E16.5
ganglia; Collaborative Biomedical Products, Bedford, MA) or 0.25%
trypsin (P0 ganglia; Worthington Biochemicals, Lakewood, NJ) diluted in
Ca2+- and Mg2+-free PBS for 35 min at 37°C followed by trituration through fire-polished Pasteur
pipettes. Cells were plated at a density of one ganglion per well onto
glass coverslips coated with poly-D-lysine (0.1 mg/ml,
Sigma) and laminin (0.3 mg/ml, Sigma). Cultures were grown in
Leibovitz's L-15/CO2 medium containing 10% NuSerum
(Collaborative), 5% heat-inactivated rat serum, fresh vitamin mixture
(Mains and Patterson, 1973), penicillin (50 IU/ml, Life Technologies),
and streptomycin (50 µg/ml, Life Technologies) for 3 d in the
absence or presence of either recombinant BDNF (10 ng/ml; Regeneron), TrkB-Fc (5 µg/ml, Regeneron), elevated KCl (40 mM final
concentration), or 40 mM KCl plus TrkB-Fc. Cultures were
stained with either anti-neurofilament (E16.5) or anti-PGP (P0)
antibodies to visualize neurons. Neuron numbers were obtained by
counting all neurofilament-positive or PGP-positive cells per culture.
Statistical analysis was performed using ANOVA followed by
Scheffé's multiple comparison procedure. p values
<0.05 were considered significant.
| |
RESULTS |
Vascular afferent survival in bdnf and
nt4 null mutant mice
We previously found that targeted disruption of bdnf,
but not nt4, alleles leads to death of chemoafferent neurons
that innervate the carotid body (Erickson et al., 1996). To determine
whether baroreceptor afferents are also BDNF-dependent, we examined
innervation of the principal baroreceptor regions of the cardiac
outflow tract, i.e., the aortic arch, carotid sinus, and the origin of
the right subclavian artery, in whole-mount preparations from newborn
wild-type, bdnf null, and nt4 null mutant mice.
In samples from wild-type animals (n = 8), a dense
plexus of highly arborized fibers and flattened terminal swellings,
characteristic of baroreceptor innervation (Heymans and Neil, 1958),
was present at the origin of the right subclavian artery (Fig.
2A) in the aortic arch
(Fig. 3A) and carotid sinus
(Fig. 3D). In contrast, all samples from
bdnf/ animals (n = 10) were devoid of
baroreceptor innervation (Figs. 2B,
3B,E). Sympathetic innervation to
the vessels, however, was intact (Fig. 2C). In
nt4 null mutants (n = 4), on the other hand,
the pattern and density of baroreceptor innervation was
indistinguishable from wild-type controls (Fig.
3C,F). To rule out the possibility that the lack of fiber staining in bdnf null mutants was
caused by downregulation of PGP immunoreactivity rather than loss of fibers, additional samples were stained for two other neuronal markers,
acetylcholinesterase and neurofilament proteins. Again, baroreceptor
innervation was present in samples from wild-type (n = 4), but not bdnf/ (n = 8) mice (data not
shown).
View larger version (95K):
[in this window]
[in a new window]
|
Figure 2.
Baroreceptor innervation is absent in newborn
bdnf/ mice. Photomicrographs of PGP-immunostained,
whole-mount preparations showing the presence (A)
and absence (B) of baroreceptor fibers at the
origin of the right subclavian artery in a wild-type and
bdnf/ mouse, respectively. Sympathetic fibers are
present (C) in the aorta of the same
bdnf/ preparation shown in B. Scale
bar, 100 µm.
|
|
View larger version (181K):
[in this window]
[in a new window]
|
Figure 3.
Baroreceptor innervation is absent in newborn
bdnf/ mice and present in nt4/
mice. Photomicrographs showing localization of PGP immunoreactivity in
whole-mount preparations of the aortic arch
(A-C) and carotid sinus
(D-F) in wild-type
(A, D), bdnf/
(B, E), and nt4/
(C, F) mice. In wild-type mice,
the aortic arch (A) and carotid sinus
(D) are densely innervated by baroreceptor fibers
and punctate terminal swellings. Baroreceptor fibers and terminals are
absent in the aortic arch (B) and carotid sinus
(E) of bdnf/ mice and are
present in nt4/ mice, C and
F, respectively. Arrowheads in
A and C point to the incoming aortic
depressor nerve fiber bundle that is mostly outside the field of view
in C. Scale bar, 100 µm.
|
|
| |
Localization of BDNF mRNA and protein in baroreceptor regions of
the fetal vasculature |
To define the relationship between BDNF dependence of
baroreceptor neurons and developmental expression of BDNF, we examined the distribution of BDNF mRNA and protein in the vasculature of fetal
rats using in situ hybridization and immunocytochemistry, respectively, and compared these data with the timing and location of
baroreceptor innervation using immunocytochemical staining for PGP 9.5 to identify nerve fibers.
BDNF mRNA and protein, as well as nerve fibers, were undetectable
within any baroreceptor regions before E14.5. However, between E14.5
and 16.5, high levels of BDNF mRNA and protein appeared in all of the
principal arterial baroreceptor regions, including the right subclavian
artery at its origin from the brachiocephalic trunk (Figs.
4A,C,
5A,C),
the aortic arch (Fig.
6A,C),
and the carotid sinus (Figs.
7A,B,
8A), coincident with the appearance of baroreceptor
fibers. There was a striking correspondence between the distribution of
BDNF at each of these sites and the pattern of baroreceptor innervation
revealed by PGP staining. In the right subclavian artery, for example,
BDNF mRNA and protein (Figs. 4A,C, 5A,C) and nerve fibers (Figs.
4B,D,
5B,D) exhibited a circumferential distribution that was highly restricted to the origin of the artery at
the bifurcation of the brachiocephalic trunk. A similar correspondence was evident between the distribution of nerve fibers and sites of high
BDNF expression in the aortic arch (Fig. 6) and carotid sinus (Fig. 7).
In addition to the baroreceptor regions of the cardiac outflow tract,
BDNF mRNA and protein were also observed in some cells associated with
the mesenchyme surrounding the pulmonary trunk (data not shown). BDNF
mRNA and protein were undetectable in all other portions of the
arterial tree, including the descending aorta, left subclavian artery,
and common carotid arteries.
View larger version (120K):
[in this window]
[in a new window]
|
Figure 4.
Localization of BDNF mRNA and protein, and
baroreceptor fibers in the fetal right subclavian artery (ventral
aspect). Photomicrographs showing localization of BDNF mRNA
(A), BDNF immunoreactivity
(C), and PGP-stained baroreceptor fibers
(B, and at higher magnification in D) in
sagittal sections through the origin of the right subclavian artery at
E16.5. The circumferential distribution of baroreceptor innervation
(B, D,
arrowheads) corresponds to the distribution of BDNF mRNA
(A, arrowheads) and protein
(C). In all sections in this and subsequent
figures, rostral is up and dorsal is to the
right. Sections in A and C
were counterstained with cresyl violet. AA, Aortic arch;
CCA, common carotid artery; SCA,
subclavian artery; Th, thymus;
n.X, vagus nerve. Scale bars, 100 µm.
|
|
View larger version (121K):
[in this window]
[in a new window]
|
Figure 5.
Localization of BDNF mRNA and protein, and
baroreceptor fibers in the fetal right subclavian artery (dorsal
aspect). Photomicrographs showing localization of BDNF mRNA
(A, arrow), BDNF
immunoreactivity (C, arrow), and
PGP-stained baroreceptor fibers (B, and at higher
magnification in D) in sagittal sections through the
origin of the right subclavian artery at E16.5. The level depicted in
these sections is medial to that shown in Figure 4. Sections in
A and C were counterstained with cresyl
violet. Abbreviations and scale bars as in Figure 4.
|
|
View larger version (126K):
[in this window]
[in a new window]
|
Figure 6.
Localization of BDNF mRNA and protein, and
baroreceptor fibers in the fetal aortic arch. Photomicrographs showing
localization of BDNF mRNA (A), BDNF
immunoreactivity (C), and PGP-stained
baroreceptor fibers (B, D) in the E16.5 aortic arch
(AA; arrowheads) at the level of the
junction with the pulmonary trunk (PT). Note the
correspondence between the distribution of baroreceptor fibers
ramifying in the outer wall of the arch (B,
arrowheads and at higher magnification in
D) and BDNF mRNA and protein
(A, C,
arrowheads). ADN, Aortic depressor nerve;
DA, descending aorta;
n.X, vagus nerve. Scale bars, 100 µm.
|
|
View larger version (142K):
[in this window]
[in a new window]
|
Figure 7.
Localization of BDNF mRNA and baroreceptor fibers
in the fetal carotid sinus. Photomicrographs showing the localization
of BDNF mRNA (A, B) and PGP-stained
baroreceptor fibers (C, D) in adjacent
sagittal sections through the E16.5 carotid sinus (CS).
A and C pass through the lumen of the
sinus and show BDNF mRNA (A) and baroreceptor
fibers (C) in the adventitial layer of the sinus
wall. B and D pass tangentially through
the adventitial layer. BDNF mRNA labeling can also be seen over cells
in the nodose ganglion (NG) in B. Note
the higher magnification in C and D.
Sections in A and B were counterstained
with cresyl violet. CB, Carotid body;
CCA, common carotid artery; SCG,
superior cervical ganglion. Scale bars, 100 µm.
|
|
In addition to baroreceptor target tissues, visceral sensory neurons in
the NPG also exhibited high levels of BDNF mRNA and protein (Figs.
7B, 8A,
respectively), and BDNF-positive fibers were also found within the
carotid sinus and carotid body (data not shown).
View larger version (133K):
[in this window]
[in a new window]
|
Figure 8.
Localization of BDNF immunoreactivity in the fetal
carotid sinus and carotid body. A, BDNF immunostaining
of the carotid sinus (CS), carotid body
(CB), and nodose ganglion (NG). The level
of this section is similar to that shown in Figure 7A.
B, Control section, stained as in A,
except that the primary antibody was omitted. Both sections were
counterstained with cresyl violet. Scale bar, 100 µm.
|
|
After E16.5, BDNF mRNA and protein levels in the vasculature declined
sharply and could not be detected in the baroreceptor regions of the
aortic arch, right subclavian artery, or carotid sinus by P0 (data not
shown). In contrast, BDNF staining in NPG neurons increased after E16.5
and remained high at P0.
| |
Localization of BDNF mRNA and protein in the fetal
carotid body |
The carotid body first appears at E13.5 as a condensation of
undifferentiated mesenchymal cells associated with the third pharyngeal
arch artery (Kondo, 1975). Initial innervation of the carotid body
primordium also begins at this stage with the arrival of a small number
of fibers from the carotid sinus nerve (Kondo, 1975; Hertzberg et al.,
1994). BDNF mRNA and protein were both detectable within a small number
of cells in the carotid body primordium on E13.5 (data not shown).
Expression in carotid body cells increased until E16.5 (Fig.
8A) and then rapidly declined to undetectable levels
by birth. At the peak of BDNF protein expression on E16.5, levels of
BDNF mRNA had already begun to decline to near background levels
(compare Figs. 7A, 8A).
In addition to intrinsic carotid body cells, nerve fibers innervating
the carotid body also exhibited BDNF immunoreactivity, suggesting that
chemoafferent neurons themselves contain BDNF. To approach this issue,
we made use of the fact that a large subset of chemoafferent neurons in
the petrosal ganglion (PG) is dopaminergic and thereby expresses the
catecholamine-synthesizing enzyme TH. TH is not expressed by other
subsets of PG neurons and is, therefore, a highly specific marker for
the chemoafferent population (Katz and Black, 1986; Finley et al.,
1992b). Double staining with BDNF and TH antibodies revealed that
virtually all dopaminergic neurons in the P0 PG exhibit BDNF
immunoreactivity (Fig.
9B,C),
demonstrating that chemoafferent neurons themselves contain BDNF.
View larger version (64K):
[in this window]
[in a new window]
|
Figure 9.
BDNF mRNA and protein expression in NPG neurons,
including the chemoafferent population. A,
Photomicrograph showing localization of BDNF mRNA in a section through
the E16.5 NPG complex. B, C,
Photomicrographs of a double-labeled section showing colocalization of
BDNF (B) and tyrosine hydroxylase
(C) immunoreactivity in ganglion cells in the
newborn PG. Arrows indicate a subset of the
double-labeled cells. TH is a specific marker for PG neurons that
innervate the carotid body, and virtually all TH-positive ganglion
cells are also BDNF-positive. Scale bars, 100 µm.
|
|
| |
Regulation of visceral afferent survival by endogenous BDNF |
The fact that PG neurons, including chemoafferents,
express BDNF raised the possibility that endogenous BDNF could support survival of these neurons via an autocrine (Acheson et al., 1995) or
paracrine mechanism (Robinson et al., 1996b). To test this possibility,
dissociate cultures of E16.5 and P0 PG neurons were exposed to either
BDNF (10 ng/ml) or a depolarizing concentration of KCl (40 mM) in the presence or absence of TrkB-Fc, an immunological reagent that inhibits TrkB activation by binding BDNF (Shelton et al.,
1995). Very few E16.5 PG neurons survived in the absence of exogenous
BDNF (Fig. 10A,
Control), and addition of BDNF resulted in a
sevenfold increase in PG cell survival (Fig. 10A).
KCl depolarization, a treatment that has previously been shown to
release endogenous BDNF from hippocampal cells (Griesbeck et al.,
1995), was as effective as exogenous BDNF in support- ing PG
neuron survival, and this effect was significantly inhibited by TrkB-Fc
(Fig. 10A). In contrast, in cultures of P0 neurons,
neither BDNF nor KCl increased survival above control. Moreover,
survival of P0 neurons, under all conditions, was unaffected by
addition of TrkB-Fc (Fig. 10B), despite the fact that
the cells exhibit abundant BDNF immunoreactivity in culture (Fig.
10C).
View larger version (21K):
[in this window]
[in a new window]
|
Figure 10.
Endogenous BDNF supports survival of fetal PG
neurons under depolarizing conditions in culture. Dissociate cultures
of E16.5 (A) or P0 (B) PG
neurons were grown for 3 d in either control medium or in the
presence of BDNF (10 ng/ml), 40 mM KCl, TrkB-Fc alone (5 µg/ml), or 40 mM KCl plus TrkB-Fc. Bars
represent the number of neurofilament-positive cells per ganglion
plated ± SEM. ANOVA was followed by Scheffe's multiple
comparison procedure; *p  0.01. C,
P0 NPG neurons grown for 3 d in culture exhibit BDNF
immunoreactivity. Non-neuronal cells, seen in the background, were not
BDNF-positive. Scale bar, 100 µm.
|
|
| |
DISCUSSION |
The present study demonstrates that BDNF is required for
development of the arterial baroreceptor system. Based on the timing of
BDNF expression in baroreceptor targets and the inability of fetal NPG
neurons to survive in the absence of exogenous BDNF in culture, we
propose that target-derived BDNF is required for baroreceptor survival
during the onset of vascular innervation in the fetus. In addition, the
fact that baroreceptor regions were completely devoid of
innervation in newborn bdnf null mutants indicates that loss
of BDNF cannot be compensated for by NT-4, the other high-affinity
ligand for the BDNF receptor, TrkB (Berkemeier et al., 1991;
Klein et al., 1992).
In conjunction with our previous studies demonstrating loss of carotid
body afferent neurons in bdnf null mutants (Erickson et al., 1996), the present findings demonstrate that arterial chemoafferent and baroreceptor neurons share a common developmental requirement for BDNF, despite the fact that they subserve
markedly distinct sensory modalities. Chemoafferent neurons are
activated transynaptically by glomus cell receptors in the
carotid body that respond to changes in arterial
pO2, pCO2, and pH (Eyzaguirre and
Zapata, 1984; Gonzalez et al., 1994). In contrast, arterial baroafferents are mechanoreceptors that terminate as free endings, primarily in the vascular adventitia, and respond to deformations of
the vessel wall caused by changes in arterial blood pressure (Abboud
and Thames, 1983). The functional heterogeneity of BDNF-dependent vascular afferents contrasts with findings in the somatosensory system
that neurotrophin dependencies are modality-specific (Snider, 1994;
Lewin, 1996) and indicates that, in the visceral sensory system, growth
factor requirements may be correlated with innervation of particular
organ systems or tissues, rather than with particular sensory
modalities. This is further supported by our finding that both chemo-
and baroreceptor innervation appear to be unaffected in nt4
null mutants (Erickson et al., 1996; present study), despite the fact
that 50% of NPG afferents die in these animals (Conover et al., 1995;
Liu et al., 1995; Erickson et al., 1996).
The onset of BDNF mRNA and protein expression in both the carotid body
and the cardiac outflow tract coincides with the arrival of sensory
innervation. This is comparable to the sequence of events described for
cutaneous sensory innervation in the mouse, in which initial expression
of NGF mRNA and protein in the skin coincides with the initial
appearance of afferent fibers (Davies et al., 1987). In contrast, BDNF
mRNA expression in trigeminal targets in the mouse (Buchman and Davies,
1993) and in chick heart (Robinson et al., 1996a) precedes the earliest
arrival of sensory axons, suggesting there is not an invariant
relationship between the timing of afferent innervation and target
expression of trophic factors in all systems. The period of BDNF
expression in the carotid body and cardiac outflow tract, between
E13.5-14.5 and E16.5, also overlaps the time at which NPG neurons are
BDNF-dependent in vitro (present study), consistent with a
role for BDNF as a classic, target-derived survival factor for
chemoafferent and baroreceptor neurons during initial target
innervation. Although BDNF expression in the carotid body falls
markedly after E16.5 and is undetectable by P0, chemoafferent neurons
remain target-dependent after birth (Hertzberg et al., 1994). These
findings indicate that chemoafferent neurons probably switch their
trophic requirements from BDNF to another target-derived factor or
factors during late fetal development, as has been proposed for other
populations of sensory neurons (Buchman and Davies, 1993).
In fetal animals, we observed some expression of BDNF in the mesenchyme
surrounding the pulmonary trunk. Preliminary studies suggest this
labeling is associated with neural crest-derived ectomesenchymal cells
that participate in vessel wall formation (D. Katz, unpublished
observations). In addition to its neurotrophic role, BDNF has
been shown to stimulate vascular smooth muscle cell migration in
vitro (Donovan et al., 1995). It is possible, therefore, that BDNF
not only supports survival of vascular afferents during initial target
innervation but also acts locally at some sites to influence vascular morphogenesis.
The fact that many NPG neurons express BDNF mRNA and protein at fetal
stages raises the possibility that endogenous, in addition to
target-derived, BDNF could support afferent survival by an autocrine
(Acheson et al., 1995) or paracrine mechanism (Robinson et al., 1996b).
However, in culture, few neurons survived in the absence of exogenous
BDNF or potassium depolarization, indicating that endogenous BDNF was
either not released under control conditions or was released at too low
a concentration to support survival. However, even in explant cultures,
in which autocrine or paracrine interactions would be maximized by the
high cell density within the intact ganglion, the vast majority of
E16.5 PG neurons are dependent on exogenous BDNF when grown under
nondepolarizing conditions (Hertzberg et al., 1994). We think it
likely, therefore, that target-derived, rather than endogenous BDNF, is
responsible for supporting survival of fetal NPG neurons in
vivo. However, because BDNF expression (Lindholm et al., 1994) and
release (Ghosh et al., 1994) can be regulated by depolarizing stimuli,
it is possible that PG neurons grown under nondepolarizing conditions
in culture lose expression of endogenous BDNF and die as a result.
Therefore, we cannot rule out the possibility that activity-dependent
cues play a role in vascular afferent development by promoting
expression and release of endogenous BDNF in vivo. We
consider it more likely, however, particularly in the newborn, that
BDNF expressed by NPG neurons is related to a transynaptic signaling
role, as has recently been proposed for other populations of
BDNF-containing neurons (von Bartheld et al., 1996; Altar et al., 1997;
Fawcett et al., 1998). Indeed, the BDNF receptor TrkB is expressed by
neurons within the brainstem nucleus tractus solitarius (Yan et al.,
1997a), the principal target of visceral afferent projections to
the brain (Finley and Katz, 1992a). Baroreceptor afferents are already
active in the fetus (Brinkman et al., 1969; Shinebourne et al., 1972; Itskovitz and Rudolph, 1982; Itskovitz et al., 1983; Yardley et al.,
1983), raising the possibility that they release endogenous BDNF in an
activity-dependent manner during prenatal development in
vivo. The fact that exogenous BDNF and KCl stimulation both increased survival of fetal, but not newborn, NPG neurons, is consistent with the finding that TrkB expression declines with age in
the afferent neurons themselves (Zhou and Helke, 1996).
Our findings are in only limited agreement with the pattern of BDNF
mRNA expression described by Scarisbrick et al. (1993) in the fetal
vasculature. In that study, the authors reported that BDNF mRNA was
localized to the aortic arch and descending aorta of fetal rats and
that this pattern of expression persisted throughout life. These data
are not supported by our finding that neither BDNF mRNA nor BDNF
protein were detectable in the descending aorta at any stage and that
BDNF expression in the aortic arch was restricted to the fetus.
Moreover, the BDNF probe used by Scarisbrick et al. (1993) failed to
detect BDNF mRNA in any of the other peripheral tissues known to
synthesize BDNF, including the dorsal root ganglia, lingual taste buds,
and vestibular sensory epithelium (Ernfors et al., 1992; Pirvola et
al., 1992; Schecterson and Bothwell, 1992, 1994; Ylikoski et al., 1993;
Nosrat and Olson, 1995), raising concern about the mRNA species
identified in their study.
In conclusion, our results demonstrate a previously unrecognized role
for BDNF in development of the arterial baroreceptor system and
indicate that target-derived BDNF is particularly important for
vascular afferent survival during initial stages of peripheral target
innervation. These findings are consistent with a role for BDNF as a
classic retrograde survival factor, similar to NGF in the somatosensory
system (Davies et al., 1987). In addition, however, the fact that
vascular afferents themselves express BDNF at later stages, when they
no longer require BDNF for survival, indicates that BDNF may also play
a transynaptic role in vascular afferent pathway development.
| |
FOOTNOTES |
Received Nov. 17, 1998; accepted Jan. 4, 1999.
This work was supported by a Public Health Service Grant (NHLBI) to
D.M.K. We thank Dr. George Yancopoulos and his colleagues at Regeneron
Pharmaceuticals for generously providing bdnf and nt4 mutant mice, TrkB-Fc, and the bdnf
plasmid used for making our cRNA probes, and Dr. Qiao Yan of Amgen for
a generous gift of BDNF antibody. We also acknowledge the outstanding
technical assistance of Mrs. Hua Jun He and thank Drs. Agnieszka
Balkowiec, Jeffery Erickson, and Jerry Silver, and Teresa Brosenitsch,
for thoughtful comments on this manuscript, and Dr. Stephen Davies for
help with Figure 9.
The first two authors contributed equally to this study and are listed alphabetically.
Correspondence should be addressed to Dr. David M. Katz, Department of
Neurosciences, Case Western Reserve University School of Medicine,
10900 Euclid Avenue, Cleveland, OH 44106-4975.
| |
REFERENCES |
-
Abboud F,
Thames M
(1983)
Interaction of cardiovascular reflexes in circulatory control.
In: Handbook of physiology. The cardiovascular system. Peripheral circulation and organ blood flow (Geiger SR,
ed), pp 675-753. Bethesda, MD: American Physiological Society.
-
Acheson A,
Conover JC,
Fandl JP,
DeChiara TM,
Russell M,
Thadani A,
Squinto SP,
Yancopoulos GD,
Lindsay RM
(1995)
A BDNF autocrine loop in adult sensory neurons prevents cell death.
Nature
374:450-453[Medline].
-
Altar CA,
Cai N,
Bliven T,
Juhasz M,
Conner JM,
Acheson AL,
Lindsay RM,
Wiegand SJ
(1997)
Anterograde transport of brain-derived neurotrophic factor and its role in the brain.
Nature
389:856-860[Medline].
-
Berkemeier LR,
Winslow JW,
Kaplan DR,
Nikolics K,
Goeddel DV,
Rosenthal A
(1991)
Neurotrophin-5: a novel neurotrophic factor that activates trk and trkB.
Neuron
7:857-866[Web of Science][Medline].
-
Brinkman CR,
Lander III C,
Weston P,
Assali NS
(1969)
Baroreceptor functions in the fetal lamb.
Am J Physiol
217:1346-1351[Free Full Text].
-
Buchman VL,
Davies AM
(1993)
Different neurotrophins are expressed and act in a developmental sequence to promote the survival of embryonic sensory neurons.
Development
118:989-1001[Abstract].
-
Conner JM,
Lauterborn JC,
Yan Q,
Gall CM,
Varon S
(1997)
Distribution of brain-derived neurotrophic factor (BDNF) protein and mRNA in the normal adult rat CNS: evidence for anterograde axonal transport.
J Neurosci
17:2295-2313[Abstract/Free Full Text].
-
Conover JC,
Erickson JT,
Katz DM,
Bianchi LM,
Poueymirou WT,
McClain J,
Pan L,
Helgren M,
Ip NY,
Boland P,
Friedman B,
Wiegand S,
Vejsada R,
Kat AC,
DeChiara TM,
Yancopoulos GD
(1995)
Neuronal deficits, not involving motor neurons, in mice lacking BDNF and/or NT4.
Nature
375:235-238[Medline].
-
Davies AM,
Bandtlow C,
Heumann R,
Korsching S,
Rohrer H,
Thoenen H
(1987)
Timing and site of nerve growth factor synthesis in developing skin in relation to innervation and expression of the receptor.
Nature
326:353-358[Medline].
-
Donovan MJ,
Miranda RC,
Kraemer R,
McCaffrey TA,
Tessarollo L,
Mahadeo D,
Sharif S,
Kaplan DR,
Tsoulfas P,
Parada L,
Toran-Allerand CD,
Hajjar DP,
Hempstead BL
(1995)
Neurotrophin and neurotrophin receptors in vascular smooth muscle cells. Regulation of expression in response to injury.
Am J Pathol
147:309-324[Abstract].
-
ElShamy WM,
Ernfors P
(1997)
Brain-derived neurotrophic factor, neurotrophin-3, and neurotrophin-4 complement and cooperate with each other sequentially during visceral neuron development.
J Neurosci
17:8667-8675[Abstract/Free Full Text].
-
Erickson JT,
Conover JC,
Borday V,
Champagnat J,
Barbacid M,
Yancopoulos G,
Katz DM
(1996)
Mice lacking brain-derived neurotrophic factor exhibit visceral sensory neuron losses distinct from mice lacking NT4 and display a severe developmental deficit in control of breathing.
J Neurosci
16:5361-5371[Abstract/Free Full Text].
-
Ernfors P,
Merlio J-P,
Persson H
(1992)
Cells expressing mRNA for neurotrophins and their receptors during embryonic rat development.
Eur J Neurosci
4:1140-1158[Web of Science][Medline].
-
Ernfors P,
Lee K-F,
Jaenisch R
(1994a)
Mice lacking brain-derived neurotrophic factor develop with sensory deficits.
Nature
368:147-150[Medline].
-
Ernfors P,
Lee K-F,
Kucera J,
Jaenisch R
(1994b)
Lack of neurotrophin-3 leads to deficiencies in the peripheral nervous system and loss of limb proprioceptive afferents.
Cell
77:503-512[Web of Science][Medline].
-
Eyzaguirre C,
Zapata P
(1984)
Perspectives in carotid body research.
J Appl Physiol
57:931-957[Abstract/Free Full Text].
-
Farinas I,
Jones KR,
Backus C,
Wang X-Y,
Reichardt LF
(1994)
Severe sensory and sympathetic deficits in mice lacking neurotrophin-3.
Nature
369:658-661[Medline].
-
Fawcett JP,
Bamji SX,
Causing CG,
Aloyz R,
Ase AR,
Reader TA,
McLean JH,
Miller FD
(1998)
Functional evidence that BDNF is an anterograde neuronal trophic factor in the CNS.
J Neurosci
18:2808-2821[Abstract/Free Full Text].
-
Finley JC,
Katz DM
(1992)
The central organization of carotid body afferent projections to the brainstem of the rat.
Brain Res
572:108-116[Web of Science][Medline].
-
Finley JC,
Polak J,
Katz DM
(1992)
Transmitter diversity in carotid body afferent neurons: dopaminergic and peptidergic phenotypes.
Neuroscience
51:973-987[Web of Science][Medline].
-
Ghosh A,
Carnahan J,
Greenberg ME
(1994)
Requirement for BDNF in activity-dependent survival of cortical neurons.
Science
263:1618-1623[Abstract/Free Full Text].
-
Gonzalez C,
Almaraz L,
Obeso A,
Rigual R
(1994)
Carotid body chemoreceptors: From natural stimuli to sensory discharges.
Physiol Rev
74:829-898[Free Full Text].
-
Griesbeck O,
Blochl A,
Carnahan JF,
Nawa H,
Thoenen H
(1995)
Characterization of brain-derived neurotrophic factor (BDNF) secretion from hippocampal neurons.
Soc Neurosci Abstr
21:1046.
-
Hertzberg T,
Fan G,
Finley JCW,
Erickson JT,
Katz DM
(1994)
BDNF supports mammalian chemoafferent neurons in vitro and following peripheral target removal in vivo.
Dev Biol
166:801-811[Web of Science][Medline].
-
Heymans C,
Neil E
(1958)
In: Reflexogenic areas of the cardiovascular system. Boston, MA: Little, Brown.
-
Hofer M,
Pagliusi SR,
Hohn A,
Leibrock J,
Barde YA
(1990)
Regional distribution of brain-derived neurotrophic factor mRNA in the adult mouse brain.
EMBO J
9:2459-2464[Web of Science][Medline].
-
Itskovitz J,
LaGamma EF,
Rudolph AM
(1983)
Baroreflex control of the circulation in chronically instrumented fetal lambs.
Circ Res
52:589-596[Abstract].
-
Itskovitz J,
Rudolph AM
(1982)
Denervation of arterial chemoreceptors and baroreceptors in fetal lambs in utero.
Am J Physiol
242:H916-H920.
-
Jones KR,
Farinas I,
Backus C,
Reichardt LF
(1994)
Targeted disruption of the BDNF gene perturbs brain and sensory neuron development but not motor neuron development.
Cell
76:989-999[Web of Science][Medline].
-
Katz DM,
Black IB
(1986)
Expression and regulation of catecholaminergic traits in primary sensory neurons: relationship to target innervation in vivo.
J Neurosci
6:983-989[Abstract].
-
Katz DM,
Karten HJ
(1985)
Topographic representation of visceral target organs within the dorsal motor nucleus of the vagus nerve of the pigeon Columba livia.
J Comp Neurol
242:397-414[Web of Science][Medline].
-
Klein R,
Lamballe F,
Bryant S,
Barbacid M
(1992)
The trkB tyrosine protein kinase is a receptor for neurotrophin-4.
Neuron
8:947-956[Web of Science][Medline].
-
Kondo H
(1975)
A light and electron microscopic study on the embryonic development of the rat carotid body.
Am J Anat
144:275-293[Web of Science][Medline].
-
Lewin GR
(1996)
Neurotrophins and the specification of neuronal phenotype.
Philos Trans R Soc Lond B Biol Sci
351:405-411[Web of Science][Medline].
-
Lindholm D,
Castren E,
Berzaghi M,
Blochl A,
Thoenen H
(1994)
Activity-dependent and hormonal regulation of neurotrophin mRNA levels in the brain-implications for neuronal plasticity.
J Neurobiol
25:1362-1372[Web of Science][Medline].
-
Liu X,
Ernfors P,
Wu H,
Jaenisch R
(1995)
Sensory but not motor neuron deficits in mice lacking NT4 and BDNF.
Nature
375:238-241[Medline].
-
Mains RE,
Patterson PH
(1973)
Primary cultures of dissociated sympathetic neurons. I. Establishment of long-term growth in culture and studies of differentiated properties.
J Cell Biol
59:329-345[Abstract/Free Full Text].
-
Maisonpierre PC,
LeBeau MM,
Espinosa III R,
Ip NY,
Belluscio L,
de la Moute SM,
Squinto S,
Furth ME,
Yancopoulos GD
(1991)
Human and rat brain-derived neurotrophic factor and neurotrophin-3: gene structures, distributions, and chromosomal localizations.
Genomics
10:558-568[Web of Science][Medline].
-
Moore MW,
Klein RD,
Farinas I,
Sauer H,
Armanini M,
Phillips H,
Reichardt LF,
Ryan AM,
Carver-Moore K,
Rosenthal A
(1996)
Renal and neuronal abnormalities in mice lacking GDNF.
Nature
382:76-79[Medline].
-
Nosrat CA,
Olson L
(1995)
Brain-derived neurotrophic factor mRNA is expressed in the developing taste bud-bearing tongue papillae of rat.
J Comp Neurol
360:698-704[Web of Science][Medline].
-
Pirvola U,
Ylikoski J,
Palgi J,
Lehtonen E,
Arumae U,
Saarma M
(1992)
Brain-derived neurotrophic factor and neurotrophin 3 mRNAs in the peripheral target fields of developing inner ear ganglia.
Proc Natl Acad Sci USA
89:9915-9919[Abstract/Free Full Text].
-
Robinson M,
Adu J,
Davies AM
(1996a)
Timing and regulation of trkB and BDNF mRNA expression in placode-derived sensory neurons and their targets.
Eur J Neurosci
8:2399-2406[Web of Science][Medline].
-
Robinson M,
Buj-Bello A,
Davies AM
(1996b)
Paracrine interactions of BDNF involving NGF-dependent embryonic sensory neurons.
Mol Cell Neurosci
7:143-151[Web of Science][Medline].
-
Scarisbrick IA,
Jones EG,
Isackson PJ
(1993)
Coexpression of mRNAs for NGF, BDNF, and NT-3 in the cardiovascular system of the pre- and postnatal rat.
J Neurosci
13:875-893[Abstract].
-
Schecterson LC,
Bothwell M
(1992)
Novel roles for neurotrophins are suggested by BDNF and NT-3 mRNA expression in developing neurons.
Neuron
9:449-463[Web of Science][Medline].
-
Schecterson LC,
Bothwell M
(1994)
Neurotrophin and neurotrophin receptor mRNA expression in developing inner ear.
Hear Res
73:92-100[Web of Science][Medline].
-
Shelton DL,
Sutherland J,
Gripp J,
Camerato T,
Armanini MP,
Phillips HS,
Carroll K,
Spencer SD,
Levinson AD
(1995)
Human trks: molecular cloning, tissue distribution, and expression of extracellular domain immunoadhesins.
J Neurosci
15:477-491[Abstract].
-
Shinebourne EA,
Vapaavuori EK,
Williams RL,
Heymann MA,
Rudolph AM
(1972)
Development of baroreflex activity in unanesthesized fetal and neonatal lambs.
Circ Res
31:710-718[Abstract/Free Full Text].
-
Snider WD
(1994)
Functions of the neurotrophins during nervous system development: what the knockouts are teaching us.
Cell
77:627-638[Web of Science][Medline].
-
von Bartheld CS,
Byers MR,
Williams R,
Bothwell M
(1996)
Anterograde transport of neurotrophins and axodendritic transfer in the developing visual system.
Nature
379:830-833[Medline].
-
Wetmore C,
Olson L
(1995)
Neuronal and nonneuronal expression of neurotrophins and their receptors in sensory and sympathetic ganglia suggest new intercellular trophic interactions.
J Comp Neurol
353:143-159[Web of Science][Medline].
-
Wetmore C,
Ernfors P,
Persson H,
Olson L
(1990)
Localization of brain-derived neurotrophic factor mRNA to neurons in the brain by in situ hybridization.
Exp Neurol
109:141-152[Web of Science][Medline].
-
Yan Q,
Radeke MJ,
Matheson CR,
Talvenheimo J,
Welcher AA,
Feinstein SC
(1997a)
Immunocytochemical localization of TrkB in the central nervous system of the adult rat.
J Comp Neurol
378:135-157[Web of Science][Medline].
-
Yan Q,
Rosenfeld RD,
Matheson CR,
Hawkins N,
Lopez OT,
Bennet D,
Welcher AA
(1997b)
Expression of brain-derived neurotrophic factor (BDNF) protein in the adult rat central nervous system.
Neuroscience
78:431-48[Web of Science][Medline].
-
Yardley RW,
Bowes G,
Wilkinson M,
Cannata JP,
Maloney JE,
Ritchie BC,
Walker AM
(1983)
Increased arterial pressure variability after arterial baroreceptor denervation in fetal lambs.
Circ Res
52:580-588[Abstract].
-
Ylikoski J,
Pirvola U,
Moshnyakov M,
Palgi J,
Arumae U,
Saarma M
(1993)
Expression patterns of neurotrophin and their receptor mRNAs in the rat inner ear.
Hear Res
65:69-78[Web of Science][Medline].
-
Zhou H,
Helke CJ
(1996)
Presence and localization of neurotrophin receptor tyrosine kinase (TrkA, TrkB, TrkC) mRNAs in visceral afferent neurons of the nodose and petrosal ganglia.
Mol Brain Res
38:63-70[Medline].
-
Zhou XF,
Chie ET,
Rush RA
(1998)
Distribution of brain-derived neurotrophic factor in cranial and spinal ganglia.
Exp Neurol
149:237-242[Web of Science][Medline].
Copyright © 1999 Society for Neuroscience 0270-6474/99/1962131-12$05.00/0
This article has been cited by other articles:
|
|
|
|
 
Z.-Y. Wang, E. B. Olson Jr., D. E. Bjorling, G. S. Mitchell, and G. E. Bisgard
Sustained hypoxia-induced proliferation of carotid body type I cells in rats
J Appl Physiol,
March 1, 2008;
104(3):
803 - 808.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Wang, S.-a. Chan, M. Ogier, D. Hellard, Q. Wang, C. Smith, and D. M. Katz
Dysregulation of brain-derived neurotrophic factor expression and neurosecretory function in mecp2 null mice.
J. Neurosci.,
October 18, 2006;
26(42):
10911 - 10915.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Q. Yao, M. A. Haxhiu, S. I. Zaidi, S. Liu, A. Jafri, and R. J. Martin
Hyperoxia enhances brain-derived neurotrophic factor and tyrosine kinase B receptor expression in peribronchial smooth muscle of neonatal rats
Am J Physiol Lung Cell Mol Physiol,
August 1, 2005;
289(2):
L307 - L314.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. G.M. Molin, R. E. Poelmann, M. C. DeRuiter, M. Azhar, T. Doetschman, and A. C. Gittenberger-de Groot
Transforming Growth Factor {beta}-SMAD2 Signaling Regulates Aortic Arch Innervation and Development
Circ. Res.,
November 26, 2004;
95(11):
1109 - 1117.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. A. Fox and M. S. Byerly
A mechanism underlying mature-onset obesity: evidence from the hyperphagic phenotype of brain-derived neurotrophic factor mutants
Am J Physiol Regulatory Integrative Comp Physiol,
June 1, 2004;
286(6):
R994 - R1004.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. L. Carroll
Plasticity in Respiratory Motor Control: Invited Review: Developmental plasticity in respiratory control
J Appl Physiol,
January 1, 2003;
94(1):
375 - 389.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Balkowiec and D. M. Katz
Cellular Mechanisms Regulating Activity-Dependent Release of Native Brain-Derived Neurotrophic Factor from Hippocampal Neurons
J. Neurosci.,
December 1, 2002;
22(23):
10399 - 10407.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Postigo, A. M. Calella, B. Fritzsch, M. Knipper, D. Katz, A. Eilers, T. Schimmang, G. R. Lewin, R. Klein, and L. Minichiello
Distinct requirements for TrkB and TrkC signaling in target innervation by sensory neurons
Genes & Dev.,
March 1, 2002;
16(5):
633 - 645.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. A. Fox, R. J. Phillips, E. A. Baronowsky, M. S. Byerly, S. Jones, and T. L. Powley
Neurotrophin-4 Deficient Mice Have a Loss of Vagal Intraganglionic Mechanoreceptors from the Small Intestine and a Disruption of Short-Term Satiety
J. Neurosci.,
November 1, 2001;
21(21):
8602 - 8615.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y. Qian, B. Fritzsch, S. Shirasawa, C.-L. Chen, Y. Choi, and Q. Ma
Formation of brainstem (nor)adrenergic centers and first-order relay visceral sensory neurons is dependent on homeodomain protein Rnx/Tlx3
Genes & Dev.,
October 1, 2001;
15(19):
2533 - 2545.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Roosen, A. Schober, J. Strelau, M. Bottner, J. Faulhaber, G. Bendner, S. L. McIlwrath, H. Seller, H. Ehmke, G. R. Lewin, et al.
Lack of Neurotrophin-4 Causes Selective Structural and Chemical Deficits in Sympathetic Ganglia and Their Preganglionic Innervation
J. Neurosci.,
May 1, 2001;
21(9):
3073 - 3084.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. T. Erickson, T. A. Brosenitsch, and D. M. Katz
Brain-Derived Neurotrophic Factor and Glial Cell Line-Derived Neurotrophic Factor Are Required Simultaneously for Survival of Dopaminergic Primary Sensory Neurons In Vivo
J. Neurosci.,
January 15, 2001;
21(2):
581 - 589.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Bibel and Y.-A. Barde
Neurotrophins: key regulators of cell fate and cell shape in the vertebrate nervous system
Genes & Dev.,
December 1, 2000;
14(23):
2919 - 2937.
[Full Text]
|
|
|
|
|
|
|
A. Balkowiec and D. M. Katz
Activity-Dependent Release of Endogenous Brain-Derived Neurotrophic Factor from Primary Sensory Neurons Detected by ELISA In Situ
J. Neurosci.,
October 1, 2000;
20(19):
7417 - 7423.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. F. Donnelly
Developmental aspects of oxygen sensing by the carotid body
J Appl Physiol,
June 1, 2000;
88(6):
2296 - 2301.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Balkowiec, D. L. Kunze, and D. M. Katz
Brain-Derived Neurotrophic Factor Acutely Inhibits AMPA-Mediated Currents in Developing Sensory Relay Neurons
J. Neurosci.,
March 1, 2000;
20(5):
1904 - 1911.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
U. Pirvola, L. Xing-Qun, J. Virkkala, M. Saarma, C. Murakata, A. M. Camoratto, K. M. Walton, and J. Ylikoski
Rescue of Hearing, Auditory Hair Cells, and Neurons by CEP-1347/KT7515, an Inhibitor of c-Jun N-Terminal Kinase Activation
J. Neurosci.,
January 1, 2000;
20(1):
43 - 50.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
B. Rohrer, J. I. Korenbrot, M. M. LaVail, L. F. Reichardt, and B. Xu
Role of Neurotrophin Receptor TrkB in the Maturation of Rod Photoreceptors and Establishment of Synaptic Transmission to the Inner Retina
J. Neurosci.,
October 15, 1999;
19(20):
8919 - 8930.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Lommatzsch, A. Braun, A. Mannsfeldt, V. A. Botchkarev, N. V. Botchkareva, R. Paus, A. Fischer, G. R. Lewin, and H. Renz
Abundant Production of Brain-Derived Neurotrophic Factor by Adult Visceral Epithelia : Implications for Paracrine and Target-Derived NeurotrophicFunctions
Am. J. Pathol.,
October 1, 1999;
155(4):
1183 - 1193.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
Top
Abstract
Introduction
