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The Journal of Neuroscience, December 15, 2002, 22(24):10772-10780
 4 Integrins and Vascular Cell Adhesion Molecule-1 Play a Role
in Sympathetic Innervation of the Heart
Kevin L.
Wingerd1,
Nichol L.
Goodman1,
Jason
W.
Tresser1,
Matthew M.
Smail1,
Sergiu T.
Leu1,
Steven J.
Rohan1,
Jan L.
Pring1,
David Y.
Jackson2, and
Dennis O.
Clegg1
1 Neuroscience Research Institute and Department of
Molecular, Cellular and Developmental Biology, University of
California, Santa Barbara, Santa Barbara, California 93106, and
2 Genentech Inc., Department of Bioorganic Chemistry, South
San Francisco, California 94080
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ABSTRACT |
Sympathetic neurons innervate the heart early in postnatal
development, an event that is crucial for proper modulation of blood
pressure and cardiac function. However, the axon guidance cues that
direct sympathetic neurons to the heart, and the neuronal receptors
that recognize those cues, are poorly understood. Here we present
evidence that interactions between the  4 1 integrin on sympathetic
neurons and vascular cell adhesion molecule-1 (VCAM-1) in the heart
plays a role in cardiac innervation.
The 4 subunit was detected on postnatal rat superior cervical
ganglion (SCG) neurons in culture and in cryosections of SCG and heart.
VCAM-1 immunoreactivity was detected on cardiac myocytes that associate
with invading sympathetic neurons. Purified recombinant soluble VCAM-1
(rsVCAM-1) stimulated SCG neurite outgrowth at levels comparable with
laminin 2/4 and fibronectin (Fn), and outgrowth on rs-VCAM-1 and
Fn was blocked by antibodies specific for the 4 and 1 integrin
subunits. Intrathoracic injection of function-blocking antibodies to
4 and VCAM-1, as well as a small molecule inhibitor of 4
integrins, significantly reduced sympathetic innervation of the heart.
These results indicate that the interaction between 4 integrin and
VCAM-1 is important for sympathetic innervation of the heart.
Key words:
integrins; vascular cell adhesion molecule-1; sympathetic
neurons; heart; neurite outgrowth; neural development
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INTRODUCTION |
Sympathetic neurons with cell bodies
in the superior, middle, and inferior cervical and thoracic sympathetic
chain ganglia innervate the heart and, during stimulation from higher
centers, release norepinephrine (NE) (Pappano, 1977 ; Ganguly and
Sherwood, 1991), which increases the rate and strength of cardiac
contractions. The path followed by developing sympathetic axons starts
at the ganglia and follows the basolateral surface of the common
carotid artery to the aorta, through the cardiac plexus down into the heart. Growth cones begin to emerge from the ganglia at
approximately embryonic day 18 (E18) and innervate the myocardium and
precapillary arterioles during the first three postnatal weeks
[postnatal day 0 (P0) through P22] (Berthoud and Powley, 1996).
Innervation of the heart starts with the right atrium (P2), followed by
the right ventricle (P4), blood vessels (P8), and the left ventricle
(P22) (Iversen et al., 1967; Lipp and Rudolph, 1972; Nyquist-Battie et
al., 1994).
Generally, axons are thought to find their way to targets via a
combination of attractive and repulsive soluble factors and extracellular matrix and cell surface substrates in the
microenvironment of the growth cone (Tessier-Lavigne and Goodman,
1996). ECM molecules that induce sympathetic axon outgrowth in
vitro include laminins (Lns), fibronectins (Fns), collagens, and
thrombospondin 1 (Reichardt et al., 1990; Lein et al., 1991). Dendrite
outgrowth apparently relies on different factors, such as osteogenic
protein-1 (Lein et al., 1995). Cell-cell interactions involved in
sympathetic neurite outgrowth are less well characterized, but several
cell adhesion molecules have been identified on sympathetic neurons, including GP130/F11, N-cadherin, DM-Grasp, Nr-CAM, and Thy-1
(Lustig et al., 1999). However, the mechanisms responsible for axon
outgrowth in vivo remain poorly understood.
4 integrins (41 and 47) play crucial roles in
inflammation and hematopoeisis (Lobb and Hemler, 1994; Arroyo et al.,
1996). The 41 integrin binds multiple ligands, including vascular
cell adhesion molecule-1 (VCAM-1) (Osborn et al., 1989), connecting sequence-1 of fibronectin (Guan and Hynes, 1990),
thrombospondin-1 (Yabkowitz et al., 1993), other 4 integrins
(Altevogt et al., 1995), the propolypeptide of von Willebrand factor
(Isobe et al., 1997), intercellular adhesion molecule-4 (Spring
et al., 2001), transglutaminase C (Isobe et al., 1999), and osteopontin
(Bayless et al., 1998). 4 integrins are also expressed by neural
cells, including neural crest cells (Kil et al., 1998), retinal cells (Sheppard et al., 1994; Cann et al., 1996), and dorsal root ganglion neurons (Vogelezang et al., 2001).
VCAM-1, an IgG superfamily member, is best known as a cytokine-induced
protein expressed on vascular endothelium in proximity to inflamed
tissue in which it is recognized by lymphoid cells via integrin
41 (Osborn et al., 1989; Aplin et al., 1998). However, VCAM-1 is
also expressed in early development in many regions, including heart
tissue that is contacted by sympathetic neurons (Sheppard et al.,
1994).
In this study, we show that recombinant soluble VCAM-1 (rsVCAM-1)
promotes robust sympathetic neurite outgrowth that is dependent on
41integrins. We examine the expression pattern of these counter receptors and demonstrate that immunological blockage of both 4
integrin and VCAM-1 results in a decrease in sympathetic innervation of
the heart.
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MATERIALS AND METHODS |
Immunohistochemistry of rat superior cervical ganglion and
heart tissue. Superior cervical ganglion (SCG) and heart tissue were dissected from P1 Long-Evans rats (Charles River Laboratories, Wilmington, MA) and briefly fixed in 4% paraformaldehyde at 4°C (5 min for SCG and 30 min for heart tissue). After rising in PBS for 20 min and overnight cryoprotection in 20% sucrose and 0.1 M sodium phosphate, pH 7.4, at 4°C, the tissue
was embedded in 15% gelatin in phosphate buffer, frozen on dry ice,
and 16 µm sections were cut using a Leica (Nussloch, Germany)
cryostat. SCG and heart sections were first blocked with 3% bovine
serum albumin (BSA), 1% goat serum, and 0.01% Triton X-100 in PBS and then stained with the mouse monoclonal anti-rat 4 antibody TA-2 (10 µg/ml; Chemicon, Temecula, CA) or with the mouse monoclonal anti-rat
VCAM-1 antibody MR106 (10 µg/ml; PharMingen, San Diego, CA). A
polyclonal rabbit antibody against tyrosine hydroxylase (TH) (1:100;
Chemicon) was used to identify sympathetic neurons. Staining was
visualized using the following secondary antibodies: goat anti-mouse
Cy3 (1:800; Jackson ImmunoResearch, West Grove, PA) and goat
anti-rabbit Alexa-488 (1:200; Molecular Probes, Eugene, OR). The
secondary antibody alone was used as the negative control, and it
produced no detectable signal. Micrographs were captured on a Zeiss
(Oberkochen, Germany) microscope equipped for epifluorescence or on a
Bio-Rad (Hercules, CA) 1024 laser scanning confocal microscope.
SCGs were dissected from P1 and P6 rats and prepared for culture as
above. On the following day, the cells were fixed with 4%
paraformaldehyde in PBS for 5 min at 4°C and then stained with one of
the following antibodies: TA-2 and HM-1 (hamster anti-1 integrin; PharMingen) or the secondary antibody alone (goat anti-mouse or hamster; Jackson ImmunoResearch). The cells were then mounted with
Prolong (Molecular Probes) and viewed with an epifluorescence microscope.
Western blot of P1 rat SCG tissue. SCGs from P1 rats were
dissected and frozen on dry ice-chilled glass, and crude membranes were
isolated (0.5 µg/ganglia) (Bono et al., 1983). After determining the
protein concentration using the amido-schwarz assay (Schaffner and Weissmann, 1973), equal amounts of protein (2.8 µg) from each sample were separated by SDS-PAGE and transferred to nitrocellulose for
Western blotting. The rat 4 integrin antibody TA-2 (1 µg/ml) was
used to detect the presence of 4 integrins, and a goat-anti mouse-HRP secondary was used to visualize bands using the ECL unit from
Amersham Biosciences (Piscataway, NJ).
Neurite outgrowth assay. Primary cultures of chicken lumbar
sympathetic ganglia (LSG) (embryonic day 12) and mouse and rat SCG (P1)
were isolated as before and plated on ECM-coated 96-well culture plates
(Corning-Costar, Acton, MA) and incubated as described by Choi et al.
(1994). Briefly, the cells were manually dissociated in media,
trypsinized (0.05% trypsin), and triturated to eliminate clumped
cells. The cells were cultured in serum-free media supplemented with
insulin-transferin-selenium (Invitrogen, Carlsbad, CA),
penicillin-streptomycin-fungizone (Invitrogen), and 100 ng/ml 7s-NGF
(Sigma, St. Louis, MO). The wells were coated overnight with
either merosin (Ln-2/4; Invitrogen) as a positive control, 1% BSA as a
negative control, plasma Fn (Invitrogen), or rsVCAM-1 (a kind gift from
Roy Lobb, Biogen, Cambridge, MA). The function blocking
antibodies TA-2 (4 integrin), 1 mM GRGDNP, 1 mM GRADSP (Biomol, Plymouth Meeting, PA)
and HM-1 (1 integrin) were added to the culture media before
incubation. (The blocking activity of the RGD peptide was
confirmed in assays of chick embryo fibroblast adhesion to
vitronectin.) Cells were incubated overnight at 37°C in a humidified
atmosphere containing 5% CO2. The neurons and
neurites were visualized by staining with the vital dye calcein AM
(fluorescein diacetate; Molecular Probes) and viewed with an
epifluorescence microscope (Culley et al., 2001). Three images of the
best neurite outgrowth from each condition were projected onto a
magnetized bit pad for analysis. The percentage of cells with processes
of any length and the neurite lengths were scored to quantify the
response (Burns et al., 1991; Choi et al., 1994; Culley et al., 2001).
A neurite is defined as a visible process emanating from the cell body.
Statistical analysis was performed using a Student's two-tailed
t test.
Intrathoracic injection of antibodies and 4
antagonist. At P1 and P3, function-blocking antibodies against
4 (TA-2, 20 µg), VCAM-1 (5F10, 20 µg), or IgG isotype controls
were injected intrathoracically into Long-Evans rats. The
isotype-matched IgG controls were injected into littermates of those
animals injected with blocking antibody. The 4 antagonist [similar
to the Genentech (San Francisco, CA) example compound shown by Jackson,
2002, his Table 12] was dissolved in 50% PEG400 (Sigma) and
injected into the intrathoracic cavity of rats at a concentration of 40 mg/kg animal weight on postnatal days 2-4. This concentration was
~10-fold greater than the amount required for a complete block of
neurite outgrowth on rsVCAM-1 in vitro (data not shown). The
antagonist has been shown to be specific for 4 integrins in binding
assays using purified integrins and ligands and in cell adhesion
experiments as described by Jackson (2002). The drug carrier (50%
PEG400) was injected into littermates as a control. At P6, heart, SCG,
and spleen tissues were harvested and frozen immediately in liquid
nitrogen for biochemistry (TA-2, n = 23; animals, 5F10,
n = 11; IgG1, n = 18; IgG2a, n = 3) or fixed for
sectioning (TA-2, n = 11; animals, 5F10,
n = 3; IgG1, n = 8; IgG2a, n = 3; G-016390,
n = 6; PEG400, n = 7) as before. Sections were stained with a goat anti-mouse secondary antibody alone
(to visualize the injected antibody) and with a primary goat anti-TH
described above. The number of TH-positive fibers in the ventricles was
quantified by directly counting in the microscope using a double-blind
procedure. From each animal, three 16 µm transverse sections (246 µm apart) from the medial heart, at the depth of the atrioventricular
valves, were stained with anti-TH antibodies. TH-positive fibers were
counted two to three times for each microscopic field of the section
(~25 fields at 400×) by two to three observers. Fibers were defined
as linear, fine-caliber TH immunoreactivity longer than ~5 µm.
Examples of what was and was not counted are shown in Figure 6. Fibers
per section were recorded for each condition. In some experiments,
digital images were captured, and pixel analysis was performed using
the Scion (Frederick, MD) Image program. The average ± SEM value
for the control animals was 791 ± 267 fibers per three sections.
The amount of NE in the heart was quantified by a radioenzymatic assay
(Coyle and Henry, 1973) and a radioimmunoassay (Analytics,
Gaithersburg, MD). For the first assay, catecholamines were labeled
using catechol-O-methyltransferase and
S-adenosyl-L-[methyl-3H]
methionine and were solvent extracted, and the counts were determined.
For the second assay, NE was quantified using the RIA kit from Alpco
Diagnostics (Windham, NH). A standard curve of NE allowed the
calculation of nanograms of NE per gram of heart tissue. Hematocrit
measurement was performed as described by Bozzini et al. (1989).
Statistical analysis was performed using a Student's two-tailed
t test.
Terminal deoxynucleotidyl transferase-mediated biotinylated UTP
nick end labeling of SCG sections from TA-2- and 4
antagonist-treated animals. Terminal deoxynucleotidyl
transferase-mediated biotinylated UTP nick end labeling (TUNEL)
of SCG sections was used to detect apoptotic cells within the SCG. The
assay was performed according to Johnson et al. (1999). Briefly, 16 µm sections (160 µm apart) from the central portion of the SCGs
were collected. Sections were incubated in PBS (1 hr) and 70% ethanol
(30 min), permeabilized, and incubated with dUTP-biotin and terminal
transferase. TUNEL-positive nuclei were visualized with avidin-Cy3
(1:250; Jackson ImmunoResearch), three sections from two to six animals
at P6 (TA-2, n = 9 sections; 5F10, n = 6 sections; control IgG, n = 18 sections) were counted, and TUNEL-positive cells per square millimeter were quantified.
SCG neuron numbers were counted as described by Smolen et al. (1983),
with modifications. Briefly, 16 µm serial cryosections were collected
from the entire SCG. Every 16th section was stained with methylene blue
and eosin (HEMA 3 stain; Biochemical Sciences, Swedesboro, NJ), and
nuclei were counted in the entire section. Cell counts for the entire
SCG were then determined using the algorithm described by Smolen et al.
(1983).
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RESULTS |
4 integrins are expressed by sympathetic neurons
To determine whether 4 integrins were expressed by SCG neurons,
cryosections of P1 SCG were immunolabeled with the anti-4 monoclonal
antibody TA-2 (Fig. 1). Immunoreactivity
was observed on both cell bodies and processes (inset) of
SCG neurons, which were identified by staining for TH. Not all
TH-positive cells stained for 4, however (Fig. 1C,
green). In addition, non-neuronal TH-negative cells and
processes within the ganglia also expressed 4. Judging from the
morphology of these cells, they include both glial cells and
ED1-positive macrophages (data not shown).
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Figure 1.
Immunolocalization of 4 integrins on SCG
neurons. Cryostat sections from P1 rat SCG were double immunolabeled
with the anti-rat 4 antibody TA-2 (red,
A) and a polyclonal anti-TH antibody
(green, B). A composite image of
A and B is shown in C.
Insets show a magnified neuronal cell and process from a
different micrograph. In cultured P1 neurons, integrin 4
(red, D) and 1
(green, E) immunoreactivity was
observed on neuronal cell bodies and neurites
(arrowhead), as well as on non-neuronal cells
(curved arrow), and punctate 4 staining was also
observed on isolated growth cones (F, open
arrows). G, Immunoblot of P1 SCG membranes
probed with the anti-4 antibody TA-2. Scale bars:
A-E, 50 µm; insets in
A-C, 25 µm; F, 10 µm.
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In cultured P1 SCG neurons, 4 immunoreactivity was observed on cell
bodies, neurites, and growth cones (Fig.
1D,F). Flat non-neuronal
cells also expressed 4 integrins (Fig. 1D,
curved arrow). The integrin 1 subunit, which we believe
pairs with 4, was also observed on cell bodies and processes on both
neurons and glia (Fig. 1E). Immunoblots of SCG
membranes probed with the same 4 antibody detected faint but
reproducible bands at 140 and 80 kDa, which is consistent with known
4 banding patterns under nonreducing conditions (Vogelezang et al.,
2001). These data show that integrins are distributed over the entire
surface of SCG neurons, including growth cones, in which they could
play a role in axon extension.
4 integrins were also detected on SCG fibers in sections of rat
heart (Fig. 2A), which
were identified by labeling for TH (Fig. 2B). In the
first postnatal week, most of these fibers are restricted to the atrial
regions. In addition, local interneurons, with cell bodies in the
intracardiac ganglia, also displayed 4 immunoreactivity (Fig.
2D). These neurons, which relay electrical impulses
to control contractions, are TH negative (Fig. 2E)
but do express choline acetyl transferase (ChAT) and peripherin (Per) (Fig. 2G-I) (Horackova et al., 1999). Some 4
immunoreactivity was also detected on myocardial cells, as has been
reported for E13 mouse heart tissue (Sheppard et al., 1994). These
experiments show that 4 integrins are found in growing sympathetic
axons, as well as other cell types.
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Figure 2.
Immunolocalization of 4 integrins and VCAM-1 in
heart tissue. P1 (A-C, G-L) and P6
(D-F) heart cryosections were stained
with TA-2 (red, A,
D) and anti-TH (green,
B, E, I). In
A-C, a portion of the medial wall of the right atrium
is shown. C is a composite image of A and
B. TH-positive fibers express 4 (arrows).
In D-F, a section through an intracardiac ganglia is
shown (F is a composite of D and
E). Cell bodies of TH-negative neurons express 4
(open arrowheads, D). These local
interneurons also express ChAT (red, G)
and peripherin (blue, H).
J-L show a section of the right atrium stained with the
anti-VCAM-1 antibody MR106 (red,
J) and anti-TH (green,
K), with a composite of J and
K shown in L. VCAM-1 immunoreactivity was
observed in close proximity to TH-positive sympathetic fibers
(filled arrowheads), which sometimes follow
VCAM-1-positive blood vessels (curved arrow).
Insets show a magnified view of the blood vessel
indicated by the curved arrow. Scale bars:
A-L, 50 µm; insets, 25 µm.
Ch, ChAT; VC, VCAM-1.
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VCAM-1 is expressed in heart
To determine whether the 4 ligand-counter receptor VCAM-1 is
expressed in regions of the heart contacted by sympathetic axons, heart
sections were double immunolabeled with anti-VCAM-1 (MR106) and anti-TH
(Fig. 2J-L). VCAM-1 immunoreactivity was observed throughout the myocardium but was especially evident in regions surrounding blood vessels (Fig. 2J, curved
arrow). This is consistent with previous work that found VCAM-1 to
be expressed on the basolateral surface of the smooth muscle lining
around precapillary arterioles (Duplaa et al., 1997). Both the
precapillary arterioles and myocardium are innervated by sympathetic
neurons, and VCAM-1 immunoreactivity could be detected in the vicinity
of TH-positive fibers within the myocardium (Fig.
2J-L, filled arrowheads). Thus, VCAM-1 is expressed at the right time and place to play a role in sympathetic innervation.
rsVCAM-1 induces neurite outgrowth by sympathetic neurons
To see whether 4 integrins expressed by SCG neurons were
active, we cultured sympathetic neurons from rat, mouse, and chick on a
carpet of rsVCAM-1 and stained them with calcein AM (Fig. 3). Neurons from all three species
mounted a vigorous response to rsVCAM-1, intermediate between the
response elicited by Ln-2/4 and Fn. Seventy percent of rat SCG neurons
extended neurites on rsVCAM-1 compared with 80% on Ln-2/4 and ~50%
on Fn.
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Figure 3.
rsVCAM-1 induces neurite outgrowth by sympathetic
neurons. E10 Chicken lumbar sympathetic ganglion neurons
(A) and P1 mouse (B) and
rat (C) SCG neurons were visualized by calcein AM
staining after overnight culture on rsVCAM-1. Rat SCG neurite
morphology on rsVCAM-1 was similar to that on Ln-2/4
(E) and Fn (F). Neurite
lengths on rsVCAM-1, Ln-2/4, Fn, and BSA are quantified in
D. Scale bar, 50 µm.
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The outgrowth on rsVCAM-1 was blocked by antibodies to the integrin
4 and 1 subunits (Fig. 4). The
anti-4 antibody TA-2 inhibited neurite outgrowth on both rsVCAM-1
(Fig. 4D) and Fn (Fig. 4F) but had
no effect on outgrowth on Ln-2/4 (Fig. 4E). MR4-1
(a nonfunction-blocking 4 integrin antibody) did not inhibit neurite
outgrowth on any of the substrates (data not shown). Outgrowth on Fn
was not inhibited by 1 mM RGD peptide (Fig.
4J). We confirmed that the RGD peptide was active in
assays of chick embryo fibroblast adhesion to vitronectin. The 1
function-blocking antibody (HM-1) inhibited SCG outgrowth on
rsVCAM-1 as well (Fig. 4G,H). Because antibodies to either 4 or 1 reduced the outgrowth to the minimal level observed on BSA (<10%), we interpret this as a complete block.
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Figure 4.
Neurite outgrowth on rsVCAM-1 is mediated by
41 integrins. P1 rat SCG neurons were cultured on rsVCAM-1
(A, D, G,
H), Ln-2/4 (B, E),
Fn (C, F), and BSA
(I). Neurites were visualized by staining
with calcein AM. Cultures were treated with the anti-4 antibody TA-2
at 50 µg/ml (D-F), anti-1 antibody at 5 µg/ml (G) or 10 µg/ml
(H), or 1 mM RGD or
RAD peptide (J). Scale bar, 50 µm.
Percentage of cells with neurites for each condition is indicated in
J. The level of outgrowth on BSA was <10% (data not
shown). * indicates 95% confidence level; ** indicates 99% confidence
level; Student's two-tailed t test. No
AB, No antibody.
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Although the 4 subunit is capable of pairing with 7 as well as
1, we were unable to detect any 7 immunoreactivity in sections of
mouse SCG tissue (data not shown). Although we cannot rule out the
presence of small amounts of 47, the blocking data indicate that
the integrin heterodimer 41 is responsible for outgrowth on rsVCAM-1 by sympathetic neurons.
4 integrin and VCAM-1 immunological blockade
in vivo
To test whether 4 integrins and VCAM-1 play a role in
sympathetic innervation of the heart in vivo, we injected
purified, function-blocking anti-4 and anti-VCAM-1 antibodies into
the thoracic cavity of neonatal rats. As a control, we injected
equivalent amounts of isotype-matched non-immune IgG. After two rounds
of injections at P1 and P3, hearts, SCG, and spleen tissues were processed for either histology or NE quantification. NE has proved to
be a reliable biochemical marker for sympathetic neurons (Clegg et al.,
1989).
To determine the distribution of injected antibodies, sections of
tissue were incubated with a goat anti-mouse secondary antibody (Fig.
5). The anti-4 antibody bound to
TH-positive fibers in the heart (Fig. 5A-C). We also saw a
significant accumulation of the antibody on peripherin-positive
intracardiac ganglion cells (Fig. 5D-F). Injected
4 antibody was able to penetrate into the SCG as well (Fig.
5M,N). The injected
anti-VCAM-1 antibody could be detected in the atria, but we could not
detect antibody in all regions that contained TH-positive fibers (Fig.
5G-I). We do not know whether this is attributable
to poor penetration or retention or whether it is attributable
to inefficient detection of the antibody. This anti-VCAM-1 antibody
does not work well for immunochemistry (data not shown).
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Figure 5.
Penetration of injected antibodies. Heart
(A-L) and SCG (M-O) of
animals that received intrathoracic injections were stained with goat
anti-mouse secondary antibody to detect injected antibodies. Injected
anti-4 antibody (red, A,
D) bound to fibers in the atrium and ventricles of the
heart that were positive for TH (green,
B, E) and peripherin
(blue, F) immunoreactivity. The
VCAM-1 antibody localized to the atria in heart tissue, but not all
areas with the TH-positive fibers were stained
(G-I). Injected mouse IgG1 or
IgG2a control antibodies did not bind to TH-positive fibers
(J-L). Injected anti-4 antibody diffused to
the SCG, in which it bound to TH-positive cell bodies
(M) and fibers (N).
Injected mouse IgG control antibody was not detected in the SCG
(red, O). (The background
green fluorescence in O is attributable
to background staining of the goat anti-rabbit IgG secondary that was
included in the experiment). Scale bar, 50 µm. ab,
Antibody; VC, VCAM-1.
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We assayed sympathetic innervation of the hearts of injected animals by
both immunohistochemical and biochemical assays. First, we quantified
the number of TH-positive fibers in heart ventricles. Using a
double-blind protocol, the numbers of fibers were counted directly in
the microscope for animals injected with anti-4, anti-VCAM-1, and
control antibodies. Typical sections for anti-4-injected animals and
controls are shown in Figure 6. 4
blockade reduced ventricular TH-positive fibers by 33%, and VCAM-1
blockade resulted in a 39% reduction (Fig.
7). The IgG control antibody-injected animals were used to establish a baseline of P6 ventricular
innervation. The same results were obtained when digital images were
captured and subjected to pixel analysis using the Scion Image software (see Materials and Methods).
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Figure 6.
Injection of anti-4 reduces sympathetic fiber
density in the heart. Cardiac cryosections from animals injected with
anti-4 (B, D, F,
H) or mouse IgG1 control
(A, C, E,
G) were stained with anti-TH to reveal sympathetic
fibers. Filled arrowheads indicate examples of TH
immunoreactivity scored as a fiber; open arrowheads
indicate examples of faint immunofluorescence that was not scored as a
fiber. Scale bar, 50 µm.
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Figure 7.
Intrathoracic injection of anti-4 and
anti-VCAM-1 antibodies reduces sympathetic innervation of the heart.
Cardiac norepinephrine levels (black bars) from animals
injected with anti-4 and anti-VCAM-1 antibodies showed a 33 ± 9% (n = 23 animals) and 39 ± 5%
(n = 9 animals) reduction compared with controls.
Quantification of the TH-positive fibers within the ventricles (average
number of fibers per section of the experimental animal divided by the
average number of fibers per section of the control animals;
white bars) revealed a 33 ± 7%
(n = 11 animals) and 30 ± 9%
(n = 3 animals) reduction, respectively. Treatment
with the 4 antagonist (n = 6 animals) yielded a
43 ± 5% reduction of fiber density compared with control animals
injected with carrier (n = 7 animals). Error bars
represent the SEM. * indicates 95% confidence level; **
indicates 99% confidence level; Student's two-tailed t
test.
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A small molecule inhibitor of 4 integrins was also injected into
neonatal rats. This treatment reduced ventricular fibers to a similar
extent (43 ± 5%).
As a biochemical measure of sympathetic innervation, we assayed NE
levels in injected hearts using two different NE assay protocols.
Blocking 4 integrins reduced cardiac NE by 33%, and blockade of
VCAM-1 resulted in a 39% reduction (Fig. 7). These data agree with the
fiber quantification above. Immunological blockade significantly
reduced the density of sympathetic fibers and NE levels in the heart
(95-99% confidence) (Fig. 7).
To determine whether the blockade of 4 and VCAM-1 caused an increase
in apoptosis in the SCG, we assayed tissue from antibody-injected animals for the presence of TUNEL-positive nuclei. An increase in SCG
cell death could account for the decrease in sympathetic tissue in the
heart. However, there was no difference in the number of TUNEL-positive
cells in the SCG tissue from animals injected with the
function-blocking antibodies compared with the non-immune antibody
controls (Fig. 8). Because apoptotic
cells might be too rapidly cleared to be detected by TUNEL, we also
counted total SCG neuron numbers in animals treated with the 4 small
molecule inhibitor. The treated animals had an average of 24,264 ± 2824 neurons per ganglia, and the control animals had 22,670 ± 5215 neurons per ganglia. Thus, we could not detect any cell death induced by perturbation of 4-VCAM-1 interactions.
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Figure 8.
Injection of anti-4 and anti-VCAM-1 does
not alter apoptosis in the SCG. No difference was detected in the
number of TUNEL-positive nuclei (arrowhead) within SCG
tissue of animals injected with anti-4, anti-VCAM-1, or control
antibodies. Scale bar, 50 µm. Results were not significantly
different, as analyzed using the Student's two-tailed t
test.
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As would be predicted from previous work (Arroyo et al., 1996),
blockade of the 4 integrin would be expected to cause improper development of reticulocytes in the bone marrow and lead to anemia. The
TA-2-injected animals had a hematocrit of 16% compared with the
control and anti-VCAM-1-injected animals, which had hematocrits of
35%. Thus, the reduction in sympathetic innervation brought about by
blockade of 4 could be a secondary consequence of anemia. As a
control, another experiment was conducted to determine whether this
reduction of red blood cells contributed to the decrease in sympathetic
fibers in the heart. Animals were injected with phenyl hydrazine (25 mg/kg) to induce anemia at P1. This treatment resulted in a hematocrit
of 16% at P6, similar to the 4-injected animals (Chen et al.,
1986). Hearts were sectioned and stained for the presence of
TH-positive fibers that were quantified as before. There was no
apparent reduction in the TH-positive fibers within the hearts of the
anemic animals (data not shown). We do not think that the anemia
induced by the blockade of 4 integrins contributes to the reduction
of sympathetic tissue in the heart (see Discussion).
Consistent with this interpretation, treatment with the small molecule
inhibitor only marginally decreased hematocrit (from 35 to 29%) yet
decreased sympathetic fibers as much as the antibody treatments.
| |
DISCUSSION |
We demonstrated that 4 integrins on sympathetic neurons mediate
neurite outgrowth on VCAM-1 in vitro and that this
interaction is important in vivo during innervation of the
heart. Although many previous studies have implicated integrins in axon
outgrowth (Clegg et al., 2000), the involvement of 4 in sympathetic
outgrowth was unexpected. The 41 heterodimer is well known for
its role in inflammation, but experiments presented here, along with
several other recent studies, suggest a significant role in neural
development and regeneration.
Previous studies showed that 4 integrins are abundantly expressed on
neural crest cells (Sheppard et al., 1994; Stepp et al., 1994; Kil et
al., 1998). This expression is maintained on developing sensory neurons
into adulthood, in which it can mediate interactions with Fn fragments
that are upregulated during injury (Vogelezang et al., 2001). As shown
here, expression is also maintained on neonatal sympathetic neurons.
4 integrins were detected all over the SCG neuronal surface,
including on growth cones, in which they are positioned to play a role
in axon outgrowth. We could detect 4 immunoreactivity on sympathetic
fibers in the heart at P1 and P6, during a time of active sympathetic
axon extension. Furthermore, we show that the 4 integrins are active
in that they mediate outgrowth on Fn and rsVCAM-1. Our data suggest
that neuronal 4 is pairing with the 1 subunit on neurons, because 7 expression has not been detected on neurons (Brezinschek et al.,
1996; Wagner et al., 1996) and because anti-1 antibody completely blocks 4-mediated neurite outgrowth (Fig. 4). Thus, 41 is
present at the right place and time to mediate sympathetic axon extension.
The 41 integrin is a multifunctional receptor capable of binding
a number of ECM and cell surface ligands. In considering growth cones
that enter heart tissue, a number of these ligands might be potential
binding partners. Fibronectin and transglutaminase C are both expressed
in heart tissue during early development (Sheppard et al., 1994;
Rongish et al., 1996; Lee et al., 2000). Fibronectin is localized
primarily in the atria in the adult rat (Mamuya and Brecher, 1992). The
expression pattern of transglutaminase C in postnatal heart has not
been examined. Osteopontin has been detected around macrophages and
fibroblasts but only during wound healing (Murry et al., 1994). Here we
show that VCAM-1 is expressed in heart tissue, especially on blood
vessels that are followed by sympathetic growth cones. Although apical
expression of VCAM-1 by endothelial cells in vessels would be expected
from previous studies, it has also been shown to be on the basolateral
side of smooth muscle (Duplaa et al., 1997). The staining we observed was on the outside of the vessels, and it coincided with staining for
smooth muscle actin (data not shown). This VCAM-1 would be accessible
to sympathetic growth cones.
We showed that a genetically engineered form of the seven IgG domain
VCAM-1 (lacking the transmembrane and cytoplasmic domains) possesses a
neurite outgrowth-promoting activity for sympathetic neurons in
vitro. To our knowledge, this is the first demonstration of such
an activity for VCAM-1. Alternatively, spliced mRNAs encode transmembrane forms of VCAM-1 with six, seven, and eight extracellular IgG domains, and a three-domain
glycosylphosphatidylinositol-linked form is also known (Osborn
et al., 1989; Hession et al., 1991; Moy et al., 1993). The seven-domain
form is the most abundantly expressed (Hession et al., 1991). This form
of VCAM-1 was able to induce outgrowth from 70% of P1 SCG neurons, a
level intermediate between Ln-2/4 and Fn. The morphology of processes
and growth cones on these substrates was indistinguishable. VCAM-1 is
expressed in other locations during early development and may support
outgrowth by other neurons (Sheppard et al., 1994). We found that
retinal neurons and DRG neurons can also respond to rsVCAM-1 in
vitro (data not shown).
4 integrins also mediate neurite outgrowth on Fn (Fig. 3). The
almost complete block of neurite outgrowth by anti-4 antibodies was
surprising, because other integrins, such as 51, which bind the
RGD site in Fn, might be expected to play a role. However, RGD peptides
did not inhibit the outgrowth of sympathetic neurons on Fn. The full
range of integrins expressed by SCG neurons is not yet clear.
Because mice lacking 4 or VCAM-1 die at early embryonic times
(Gurtner et al., 1995; Kwee et al., 1995; Yang et al., 1995), it has
been difficult to study their functions in later development, and, as
with other inquiries, genetic strategies and other perturbations have
given conflicting results. For example, peptide and antibody perturbation experiments suggest a role in neural crest cell migration (Kil et al., 1998). However, 4 null crest cells appear to migrate normally (Haack and Hynes, 2001). Crest-derived glial cells lacking 4 do show increased apoptosis, however, indicating a role in glial
cell survival. We used function-blocking antibodies to investigate functions of 4 and VCAM-1 in sympathetic innervation. Antibodies to
both proteins inhibited the formation of fibers and the resulting accumulation of NE within the heart. Although only a 30-40% reduction was observed, these results are significant, and even a bit remarkable, given the wide number of adhesive interactions that might contribute to
axon extension. Sympathetic neurons express a number of integrins, including the 1 and 3
subunits, and many integrin ligands and cell adhesion molecules
are present in pathways followed by sympathetic axons (Reichardt et
al., 1990; DeFreitas et al., 1995; Murase and Hayashi, 1998).
The mechanism of inhibition in these experiments is still under
investigation. One possible explanation was that the neurons were
simply not surviving, because 4 and other integrins have been
implicated in preventing apoptosis (Haack and Hynes, 2001). However, we
could not detect any increase in TUNEL-positive neurons in the SCGs of
treated animals, nor were any differences in neuronal numbers or
pyknotic nuclei observed (data not shown). Another explanation was that
the anemia caused by anti-4 antibodies decreased sympathetic
innervation by some secondary means. However, induction of anemia using
phenyl hydrazine did not decrease sympathetic innervation. Furthermore,
the anti-VCAM-1 antibody decreased sympathetic density but did not
cause anemia. Because 4 integrins are expressed on cardiac myocytes,
the blocking antibody could affect these cells in some way that would
lead indirectly to an alteration in innervation. It is possible that
the axons are not growing at all, or are rerouted to a different
location, or are not maintained once reaching the target. Experiments
are underway to further investigate this question.
Our data support a role for 41-VCAM-1 interactions in
sympathetic innervation of the heart. By studying the molecules
involved in the proper development of the sympathetic nervous system,
it may be possible to elucidate the origin of pathologies involving overdevelopment and underdevelopment of these neurons (Chen et al.,
2001).
| |
FOOTNOTES |
Received Aug. 13, 2002; revised Sept. 25, 2002; accepted Oct. 1, 2002.
This work was supported by California Tobacco Related Disease Research
Program Grant 9RT-0212 and National Institutes of Health/National Eye
Institute Grant EY06916. We thank Roy Lobb for the generous gift of
rsVCAM-1.
Correspondence should be addressed to Dennis O. Clegg, Neuroscience
Research Institute, University of California, Santa Barbara, Santa
Barbara, CA 93106. E-mail: clegg{at}lifesci.ucsb.edu.
N. L. Goodman's present address: University of California, San
Diego, La Jolla, CA 92093.
S. J. Rohan's present address: Medical College of Wisconsin,
Milwaukee, WI 53226.
| |
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ABSTRACT
INTRODUCTION
