 |
 Previous Article | Next Article 
The Journal of Neuroscience, February 1, 2002, 22(3):854-862
Tumor Necrosis Factor Inhibits Neurite Outgrowth and Branching of
Hippocampal Neurons by a Rho-Dependent Mechanism
Harald
Neumann1, 3,
Rüdiger
Schweigreiter2, 4,
Toshihide
Yamashita2,
Katja
Rosenkranz1,
Hartmut
Wekerle1, and
Yves-Alain
Barde2, 4
Departments of 1 Neuroimmunology and
2 Neurobiochemistry, Max-Planck Institute of Neurobiology,
82152 Martinsried, Germany, 3 Neuroimmunology, European
Neuroscience Institute Göttingen, 37073 Göttingen, Germany,
and 4 Friedrich Miescher Institute for Biomedical Research,
4058 Basel, Switzerland
 |
ABSTRACT |
In response to injury and inflammation of the CNS, brain
cells including microglia and astrocytes secrete tumor necrosis
factor- (TNF). This pro-inflammatory cytokine has been
implicated in both neuronal cell death and survival. We now provide
evidence that TNF affects the formation of neurites. Neurons cultured
on astrocytic glial cells exhibited reduced outgrowth and branching of
neurites after addition of recombinant TNF or prestimulation of glial
cells to secrete TNF. This effect was absent in neurons of TNF
receptor-deficient mice cultured on prestimulated glia of wild-type
mice and was reverted by blocking TNF with soluble TNF receptor IgG
fusion protein. TNF activated in neurons the small GTPase RhoA. By
inactivating Rho with C3 transferase, the inhibitory effect of TNF on
neurite outgrowth and branching was abolished. These results suggest
that glia-derived TNF, as part of an injury or inflammatory process, can inhibit neurite elongation and branching during development and regeneration.
Key words:
neurite; morphogenesis; Rho; GTPases; TNF; cytokine; TNF
receptor; glia
| |
INTRODUCTION |
During development and regeneration,
vertebrate neurons undergo profound morphological changes that include
substantial cytoskeletal restructuring. These changes are induced by
contact with other cells and diffusible extracellular signals (Hu and
Reichardt, 1999 ). Contact-dependent modulation involves membrane-bound
molecules such as cadherins, integrins, and cell adhesion molecules of
the immunoglobulin superfamily. Diffusible signal molecules include neurotransmitters, neurotrophic factors, and guidance molecules such as
semaphorins (Chisholm and Tessier-Lavigne, 1999). In particular, neurotrophins have remarkable effects on neurite outgrowth and arborization (Bibel and Barde, 2000). Recently, a direct link between
Rho GTPases and neurotrophin signaling was revealed in experiments
demonstrating an interaction between RhoA and the p75 neurotrophin
receptor (p75NTR). Members of the Rho
family of small GTPases, including Rac, Cdc42, and Rho, have been
shown to be crucial intracellular regulators of the cytoskeleton in
neurons (Luo et al., 1997; Threadgill et al., 1997; Luo, 2000). In
transfected cells, p75NTR was demonstrated
to constitutively activate RhoA, whereas neurotrophin binding rapidly
reduced the activation of the GTPase (Yamashita et al., 1999). The
downregulation of RhoA mediated by p75NTR
was proposed to be part of a mechanism accelerating
neurotrophin-induced axonal elongation (Yamashita et al., 1999; Tucker
et al., 2001). The tumor necrosis factor receptor (TNFR) and the
p75NTR receptors are members of the same
receptor family. Interestingly, previous experiments have implicated
these receptors and their ligand TNF in modulating the cytoskeleton in
non-neuronal cells. TNF induced stress fibers and focal adhesion
formation mediated by the GTPase Rho in endothelial cells
(Wojciak-Stothard et al., 1998), epithelial cells (Koukouritaki et al.,
1999), and fibroblasts (Puls et al., 1999).
In the CNS, in contrast to neurotrophins that are mainly produced by
neurons, TNF is preferentially produced by activated glial cells,
microglia, and astrocytes during brain injury or inflammatory processes
(Hopkins and Rothwell, 1995). For instance, TNF protein has been
localized in glial cells after experimental autoimmune
encephalomyelitis (Renno et al., 1995). TNF protein was also detected
in neurons by immunohistochemistry after mechanical (Tchelingerian et
al., 1993) or ischemic brain injury (Bruce et al., 1996). Furthermore,
TNF gene transcription and protein production have been observed during
development in total brain tissue extracts (Munoz-Fernandez and Fresno,
1998; Zhao and Schwartz, 1998). In culture, astrocytes secrete TNF at
low level, but cytokine secretion is strongly increased after treatment
with inflammatory stimuli such as IFN- combined with IL-1 (Chung
and Benveniste, 1990). TNF is produced as a propeptide, which
integrates into the cell membrane as a stable homotrimer or can be
clipped off at the transmembrane domain by the metalloproteinase
TNF--converting-enzyme [TACE, ADAM-17 (Blobel, 1997)]. The
biological activity of TNF is mediated via either the TNFRI (p55 TNF
receptor, CD120a) or the TNFRII (p75 TNF receptor, CD120b), which have
overlapping signaling capabilities (Rothe et al., 1994; Hsu et al.,
1996).
To elucidate the significance of TNF on neuronal morphology, we
cocultured hippocampal neurons at low density with glial cells. After
treatment with recombinant TNF or stimulation of glial cells to elicit
TNF, we observed a marked reduction in length and branching of
neurites. Furthermore, we found that RhoA becomes activated in cultures
of enriched neurons by TNF and provide evidence that this GTPase is
causally involved in the inhibitory effect of recombinant or secreted TNF.
| |
MATERIALS AND METHODS |
Mice. C57BL/6 mice were obtained from the animal
house facilities of the Max-Planck Institutes of Neurobiology and
Biochemistry (Martinsried, Germany). C57BL/6 TNFRI- plus
TNFRII-deficient mice were obtained by crossing C57BL/6
TNFRII-deficient mice (back crossed for 10 generations with C57BL/6;
The Jackson Laboratory, Bar Harbor, ME) with TNFRI-deficient mice
(backcrossed nine generations with C57BL/6; Klaus Pfeffer, Technical
University, Munich). Homozygous mice deficient for both TNF receptors
(TNFRI plus TNFRII) were confirmed by established PCR protocols (K. Pfeffer, Technical University, Munich, Germany/The Jackson Laboratory,
Bar Harbor, ME) and then maintained as homozygotes in our animal
house facility.
Murine hippocampal neurons. Primary hippocampal neuronal
cell cultures were prepared as described previously (Neumann et al., 1995). Briefly, hippocampi were isolated from whole brains of embryonic
day 16 mice, and the meninges were removed. The trimmed tissue was
dissociated by trituration through a fire-polished Pasteur pipette.
Cells (5 × 103/ml) were plated on
astrocyte-enriched glia culture or into dishes that had been pretreated
with poly-L-ornithine (0.5 mg/ml; Sigma, St.
Louis, MO) in 0.15 M boric acid. Cells were
cultured in chemically defined medium containing basal medium Eagle
(BME; Invitrogen, Gaithersburg, MD) with B27 supplement [2%
(v/v), Invitrogen] and glucose [1% (v/v) 45%; Sigma]. Cells were
treated with TNF (murine recombinant TNF, 10 ng/ml; Roche Products,
Hertforshire, UK), TNF receptor IgG fusion protein (recombinant human
TNF receptor p55IgG1 fusion protein, 20 µg/ml; gift from Dr. Werner
Lesslauer, Roche), or human control IgG (20 µg/ml; Dianova, Hamburg)
as indicated in Results.
Murine astrocyte-enriched glial cells. Hippocampi of
embryonic day 16 C57BL/6 mice were isolated and dissociated into
single-cell suspensions as described for neuronal hippocampal
preparations. Cells were plated in 50 ml tissue culture flasks that had
been pretreated with poly-L-lysine (5 µg/ml;
Sigma). Cells were cultured in serum containing medium with
MEM-D-valine (Invitrogen), 10% heat-inactivated
FCS (Pan System, Wuerzburg, Germany), and 1% L-glutamine. Microglial cells were removed by
several rounds of shaking on a rotary shaker. Astrocyte-enriched glial
cells were cultured for 10-20 d and then plated in BME with B27
supplement [2% (v/v), Invitrogen] and glucose [1% (v/v), 45%;
Sigma] at a density of 2 × 104/ml
before experimentation. In total, 94% (±3% SD) of cells were astrocytes as determined by immunolabeling with rabbit antibodies directed against GFAP (10 µg/ml; Dako, Glostrup, Denmark). Murine recombinant IFN- (100 U/ml; HyCult Biotechnology, Amsterdam, The Netherlands) and murine recombinant Il-1 (10 ng/ml; Biosource and Roche Molecular Biochemicals) were added to the cells for 24 hr as
indicated in Results.
RT-PCR for TNFRI, TNFRII, and TNF. Single-cell RT-PCR was
performed as described previously (Neumann et al., 1995). Cytoplasm was
sampled from individual hippocampal neurons with a micropipette after
whole-cell recording configuration of the patch-clamp technique. Samples of the extracellular fluid and pipette solution served as
negative controls. The content of the micropipette was transferred into
a test tube and directly used for reverse transcription. Reverse
transcription of RNA was performed with dithiothreitol (10 mM; Invitrogen), ribonuclease inhibitor (20 U;
Promega, Madison, WI), hexamer random primer (1 µl; Roche Molecular
Biochemicals), the four deoxyribonucleotide triphosphates (0.5 mM; Amersham Biosciences), and Moloney murine
leukemia virus transcriptase (100 U; Invitrogen) for 1 hr at
42°C. As a control, cytoplasmic mRNA of myelin oligodendrocyte glycoprotein peptide-specific CD4-positive T lymphoblasts was collected through the micropipette and reverse transcribed as described
above. Cytoplasmic RNA of astrocytes was collected with RNAzol B
(Wak-Chemie, Bad Soden, Germany) and reverse transcribed as described
above. Oligonucleotide sequences were selected with the program Primer3
(Whitehead Institute, MIT, Cambridge, MA). Forward and reverse primer
pairs were chosen from two different exons and were, respectively,
5'-CCCGGTGGAGGC- CCGAAG-3' and 5'-GCTGGGGAGGGGGCTGGA-3' for TNFRI;
5'-AGTGCGGCCCTGGCTTCGG-3' and 5'-GTTGGGGACTCGGGC- GCAC-3' for
TNFRII; 5'-GGGGTGATCGGTCCCCAAAGG-3' and 5'-CGGGGCAGCCTTGTCCCTTG-3' for
TNF; and 5'-TCCGCCCC- TTCTGCCGATG-3' and 5'-CACGGAAGGCCATGCCAGTGA-3' for glyceraldehyde-3-phosphate dehydrogenase (GAPDH).
PCR reaction was performed in a final volume of 50 µl containing 1 µl of the transcribed cDNA probe, the four deoxyribonucleotide triphosphates (0.2 mM each; Amersham Biosciences),
2.5 U Ampli Taq polymerase (Perkin-Elmer, Roche Molecular
Systems), and 1× PCR buffer (Perkin-Elmer, Roche Molecular Systems)
covered with two drops of mineral oil (Sigma). PCR amplification was
performed on a programmed thermocycler (MultiCycler, MJ Research Inc.). After denaturing of the cDNA at 95°C for 3 min, denatured primers (100 pmol each) were added at 80°C. PCR was performed for 50 cycles (93°C for 1 min; 60°C for 1 min; 72°C for 1 min) and
followed by one final interval at 72°C for 5 min. Ten microliters of
the PCR reaction were loaded in parallel with the molecular weight marker ( X 174, HaeIII digested; Amersham Biosciences) on
a 1.7% Agarose gel containing ethidium bromide. The enzyme GAPDH
served as a control for the quality and quantity of cDNA. Individual T
lymphoblasts analyzed as a positive control for the single-cell RT-PCR
approach showed gene transcripts of both TNF receptors. PCR products
derived from individual neurons were purified from ethidium
bromide-stained Agarose gels using a gel extraction method (Quiagen,
Hilden, Germany) and directly sequenced (MediGenomix, Martinsried, Germany).
Immunofluorescence labeling of neurons for TNFRI and TNFRII.
Hippocampal neurons cultured without glial cells for 1 week were washed
with PBS, fixed in 4% paraformaldehyde, incubated with rat
monoclonal antibodies directed against TNFRI (2 µg/ml; HM-104; Biermann, Bad Nauheim, Germany) and TNFRII (2 µg/ml; HM-102;
Biermann) followed by secondary fluorochrome Cy3-conjugated goat
antibody directed against rat IgG (10 µg/ml; Dianova). Subsequently,
after extensive washing, cells were incubated with the neuron-specific mouse monoclonal antibody specific for -tubulin III (1 µg/ml; Sigma) and secondary dichlorotriazinyl
aminofluorescein-conjugated goat antibody directed against mouse
IgG (10 µg/ml; Dianova). Optical sections along the z-axis
were scanned with a confocal laser-scanning microscope (Leica) equipped
with a 63× oil objective. Baseline labeling was determined with rat
control antibodies and secondary fluorochrome Cy3-conjugated goat
antibodies directed against rat IgG.
Precipitation and Western blot analysis of
GTP-RhoA. Primary hippocampal neurons cultured without
glial cells were lysed in 50 mM Tris, pH 7.2, 1%
Triton X-100, 150 mM NaCl, 10 mM MgCl2, with leupeptin
(10 µg/ml), aprotinin (10 µg/ml), and PMSF (1 mM). Sepharose beads conjugated with a GST-tagged
Rho binding domain of Rhotekin were produced as described (Ren et al.,
1999). Cell lysates were clarified by centrifugation at
13,000 × g at 4°C for 5 min, and the supernatants
were incubated with ~20 µg of Rhotekin conjugated to beads at 4°C
for 45 min (Ren et al., 1999). The beads were washed four times
with washing buffer [50 mM Tris, pH 7.2, 1%
Triton X-100, 150 mM NaCl, 10 mM MgCl2, leupeptin (10 µg/ml), aprotinin (10 µg/ml), and PMSF (1 mM)]. Bound Rho proteins were detected by gel
electrophoresis followed by Western blotting using a monoclonal
antibody directed against and specifically recognizing RhoA
(2bc4, 0.1 µg/ml; Santa Cruz Biotechnology, Santa Cruz, CA) and
secondary peroxidase-conjugated antibodies directed against mouse IgG
and the ECL detection system (Amersham Biosciences).
Neurite morphometry of -tubulin III-immunolabeled
neurons. Primary hippocampal neurons were cultured at a low
density on glial cells to allow morphological analysis of single
neurons. The cells were fixed in 4% paraformaldehyde and incubated
with primary mouse monoclonal antibody directed against -tubulin III (1 µg/ml, Sigma) and secondary fluorochrome Cy3-conjugated goat antibody directed against mouse IgG (10 µg/ml; Dianova). Images of
-tubulin III-labeled neurons were captured with a 20× or 40× objective with a laser scanning microscope (Leica). Neurites of scanned
cells were traced using Optimas software. Data of the morphometry of
individual neurons were collected and scored for total neurite length
per cell, axonal length per cell, number of primary processes per cell,
and branch points per cell. Neuronal survival was analyzed by
determination of the density of -tubulin III-positive cells that
survived per each experimental group. Primary processes were defined as
neurites originating at the neuronal somata. Axons were defined as the
longest primary process per cell. Experiments were repeated at
least three times, and data are presented as mean ± SEM of
independent experiments.
Trituration of neurons together with C3 transferase. The C3
exoenzyme from Clostridium botulinum (C3 transferase) was
produced in bacteria as glutathione S-transferase (GST)
fusion protein and purified as described (Nobes and Hall, 1995).
Trituration together with C3 transferase was performed as described
previously (Borasio et al., 1989; Jin and Strittmatter, 1997). Briefly,
primary hippocampal neurons were suspended in 25 mM Tris-HCl, pH 7.5, 150 mM
NaCl, 5 mM MgCl2, with C3
transferase at 0.1 mg/ml directly after isolation from the brain
tissue, and passed 50 times through a 200 µl pipette tip. After
trituration, neurons were plated on the glial cells as described above.
Flow cytometry for membrane-bound TNF. The
astrocyte-enriched glial cells were collected from the culture by short
trypsinization (trypsin-EDTA solution; Invitrogen). Cells were washed
with PBS, and unspecific binding sites were blocked with 2% bovine
serum albumin (Sigma). Then, cells were incubated with polyclonal
rabbit anti-TNF antibody (1:100, Genzyme) followed by dichlorotriazinyl aminofluorescein-conjugated goat anti-rabbit antibody (10 µg/ml, Dianova). Polyclonal rabbit IgG (Dianova) followed by dichlorotriazinyl aminofluorescein-conjugated secondary antibody was used as a control. Cells were incubated with 0.5 µg/ml propidium iodide to distinguish living from dead cells and analyzed with a flow cytometer (FACScan, Becton Dickinson).
Measurement of released TNF. To measure TNF secreted by
astrocyte-enriched glia, cells were kept in serum-free medium for 6 hr.
The supernatant was collected and assayed via ELISA according to the
instructions of the manufacturer (OptEIA mouse TNF mono/mono, PharMingen).
| |
RESULTS |
TNF receptor expression in primary hippocampal neurons
Primary neurons were cultured from hippocampal tissue derived from
embryonic mice. TNF receptor gene transcripts were analyzed in primary
neuronal cultures by single-cell RT-PCR of individual neurons. Neurons
were first unequivocally identified by whole-cell patch-clamp
electrophysiology, and then the cell cytoplasm was collected with the
micropipette. Gene transcripts for TNFRI as well as TNFRII were
detected in the majority of single neurons (Fig.
1) and confirmed by sequencing.
Specifically, 21 of 25 analyzed neurons were positive for TNFRI and 19 of 25 were positive for TNFRII, whereas in 18 of 25 neurons both TNF
receptor types were detected.
View larger version (84K):
[in this window]
[in a new window]
|
Figure 1.
TNF receptor gene transcription in hippocampal
neurons. Single-cell RT-PCR of cultured primary hippocampal neurons.
Gene transcripts for TNFRI and TNFRII were detected in the majority of
neurons. Co-amplification of gene transcripts for GAPDH served as a
control. M, Molecular weight marker
X174/HaeIII; C, negative PCR control;
N1-N9, samples of single neurons.
|
|
Protein expression of TNF receptors in primary hippocampal neurons was
analyzed by immunohistochemistry. Neurons were immunolabeled with rat
monoclonal antibodies directed against mouse TNFRI or TNFRII and
subsequently double labeled with antibodies directed against the
neuronal cytoskeleton protein -tubulin III. Background labeling was
determined with control rat immunoglobulin. Intracellular granular
staining for TNFRI and TNFRII was obtained in the neuronal somata and
processes of neurons (Fig. 2). In total,
81.8% (±7.9% SEM) of hippocampal neurons identified by -tubulin
III immunohistochemistry showed TNFRI labeling, and 77.6% (±5.7%
SEM) showed TNFRII labeling. Immunolabeling for TNFRI as well as
TNFRII gave only background staining in hippocampal neurons derived
from TNFRI- plus TNFRII-deficient mice.
View larger version (123K):
[in this window]
[in a new window]
|
Figure 2.
Immunodetection of TNFRI and TNFRII molecules in
primary hippocampal neurons. Neurons were immunolabeled with rat
monoclonal antibodies directed against TNFRI or TNFRII and rat control
antibodies. Neurons were subsequently double labeled with antibody
directed against -tubulin III. Scale bar, 10 µm.
|
|
Reduced neurite outgrowth and branching of primary hippocampal
neurons in response to TNF
Low-density cultures of primary hippocampal neurons were performed
by culturing neurons together with glial cells. This low-density culture system allows detailed morphometric analysis of individual neurons. Astrocyte-enriched glial cells were obtained from
primary hippocampal brain cells after removal of microglia. Hippocampal neurons derived from E16 embryonic C57BL/6 or TNF receptor-deficient C57BL/6 mice were cultured on these astrocyte-enriched glial cells in
chemically defined medium at low density, resulting in individual neurons without neuron-neuron contacts. Within a few hours, the neurons showed outgrowth of neurites up to 100 µm on the glial cell layer.
To analyze the effects of TNF on neurons, recombinant mouse TNF was
added a few hours after plating to the neurons on the glial cell layer.
After 16 hr, cells were fixed and immunolabeled with -tubulin III.
Neurites were traced and analyzed with an image analysis system.
Neurite morphology of TNF-treated cell cultures was completely
different from untreated cultures (Fig. 3), whereas neuronal survival was not
altered by the TNF treatment (Table 1).
Neurons treated with TNF showed reduced branching of their processes,
and most neurites were almost equal in length without clear distinction
of an axon-like process. The total neurite length per neuron and the
axonal length, defined as the length of the longest neurite per neuron,
were determined. Treatment with TNF (10 ng/ml, 16 hr) decreased the
total neurite length per cell from 453 µm (±18.9 µm SEM) to 230 µm (±27.6 µm SEM) as well as the axonal length from 148 µm (±24
µm SEM) to 70 µm (±15.6 µm SEM) (Fig.
4). No change in the number of primary
processes originating from the neuronal somata was detectable after
treatment with TNF. However, there was a reduction in the number of
branch points per cell in response to TNF. Untreated neurons showed on average 5.5 (±0.46 SEM) branch points per cell, whereas neurons treated with TNF exhibited 1.8 (±0.31 SEM) branch points per cell (Fig. 4). TNF affected neurite length and morphology via neuronal TNF
receptors. Hippocampal neurons derived from TNFRI- plus
TNFRII-deficient mice were cultured on glial cells derived from C57BL/6
wild-type mice. In this case the neurons did not show alterations in
total neurite length, axonal length, and number of branch points after treatment with TNF (Fig. 4). Furthermore, we cultured hippocampal neurons derived from C57BL/6 wild-type mice on glial cells derived from
TNFRI- plus TNFRII-deficient mice. TNF again reduced neurite outgrowth
and branching of neurons (Fig. 4), indicating that the effect of TNF on
neurite morphology was directly mediated via the TNF receptors of the
neurons.
View larger version (25K):
[in this window]
[in a new window]
|
Figure 3.
Computer-assisted tracing of -tubulin
III-labeled neurites. Primary hippocampal neurons were cultured for 16 hr on astrocyte-enriched glial cells. Neurons were immunolabeled with
antibodies against -tubulin III, and neurites of captured images
were traced with image analysis software. Treatment with 10 ng/ml TNF
reduced neurite outgrowth and branching of neurites. Scale bar, 10 µm.
|
|
View larger version (54K):
[in this window]
[in a new window]
|
Figure 4.
Morphometric analyses of primary hippocampal
neurons cultured for 16 hr on astrocyte-enriched glia. Neurons and
glial cells were derived from E16 C57BL/6 mice
(Wild-type) or C57BL/6 TNFRI- plus TNFRII-deficient mice
(Neurons TNFR  /, Glia TNFR /).
The cultures were either untreated (gray columns)
or treated for 16 hr with 10 ng/ml TNF (black columns).
TNF reduced the total neurite length, axonal length, and number of
branch points of neurons derived from C57BL/6 mice, but not TNFR /
mice. The reduction in neurite outgrowth and branching was independent
of the TNF receptor expression of the glia. Data are presented as
mean ± SEM of three independent experiments.
|
|
TNF production by cytokine-stimulated glial cells
In contrast to normal glial cells, reactive glial cells, in
particular activated microglia and astrocytes of the injured brain, have been shown to produce TNF. In culture, gene transcription of TNF
in astrocytes can be induced by combined treatment with the
pro-inflammatory cytokines IL-1 and IFN-. Therefore, we pretreated our astrocyte-enriched glial cells with IFN- (100 U/ml)
and ILl-1 (10 ng/ml) for 24 hr. After pretreatment, gene transcripts
for TNF were detected via RT-PCR (Fig.
5). In contrast, no TNF gene transcripts
were amplified from untreated glial cell culture. Treatment with
IL-1 or IFN- alone resulted in low but detectable gene
transcription of TNF.
View larger version (28K):
[in this window]
[in a new window]
|
Figure 5.
Detection of TNF gene transcripts, membrane-bound
TNF, and TNF released in response to cytokine stimulation of glia.
Astrocyte-enriched glial cells were untreated (Con) or
treated with 100 U/ml IFN- (IFN), 10 ng/ml
IL-1 (IL1), or IFN- plus IL-1
(IFN/IL1) for 24 hr. A,
Analysis of TNF gene transcripts by RT-PCR. Glia showed low amounts of
TNF gene transcripts after treatment with IFN- or IL-1 alone,
whereas high amounts of TNF gene transcripts were detected after
combined treatment with IFN- and ILl-1. Coamplification of gene
transcripts for GAPDH served as a control. M, Molecular
weight marker X174/HaeIII; Neg,
negative PCR control. B, Membrane-bound TNF was detected
on astrocyte-enriched glial cells with fluorescence-labeled rabbit
antibody directed against TNF and flow cytometry. Data are presented as
mean ± SEM of three independent experiments. C,
Soluble TNF released within 6 hr was detected in the supernatant of
cytokine-stimulated glia. Data are presented as mean ± SEM of
three independent experiments.
|
|
To confirm TNF protein synthesis and secretion by astrocyte-enriched
glial cells, we analyzed membrane-bound TNF by flow cytometry. Untreated and cytokine-stimulated glial cells were incubated with antibodies directed against TNF. Membrane-bound TNF was detected in
29% (±5.4% SEM) of glial cells pretreated for 24 hr with IFN- plus IL-1 (Fig. 5). Membrane-bound TNF was already seen after treatment with IFN- alone (24 ± 9%).
The amount of TNF secreted within 6 hr by glial cells was determined by
ELISA. Treatment with IFN- plus IL-1 stimulated glial cells to
release TNF up to 1000 pg/ml within 6 hr (Fig. 5). Thus, the combined
treatment with IFN- and IL-1 resulted in significant gene
transcription, membrane localization, and secretion of TNF.
Inhibition of outgrowth and branching of neurites by TNF from
reactive glia
Primary hippocampal neurons derived from E16 embryonic C57BL/6 or
TNF receptor-deficient C57BL/6 mice were cultured on astrocyte-enriched glial cells derived from C57BL/6 wild-type mice now pretreated with
IFN- and IL-1 to produce sufficient amounts of TNF. After 16 hr,
these neurons showed decreased total neurite length, decreased axonal
length, and decreased number of branch points (Fig.
6) compared with neurons cultured on
unstimulated glial cells (Fig. 4). To analyze whether this reduced
outgrowth and branching of neurons on stimulated glia were indeed
induced by TNF, we neutralized the endogenously secreted TNF in the
culture.
View larger version (50K):
[in this window]
[in a new window]
|
Figure 6.
Morphometric analyses of primary hippocampal
neurons cultured for 16 hr on reactive glia that has been pretreated
for 24 hr with IFN- and IL-1 to induce TNF production. Neurons
were derived from E16 C57BL/6 mice (Neurons wild-type)
or C57BL/6 TNFRI- plus TNFRII-deficient mice (Neurons
TNFR /). The cultures were treated for 16 hr with control
IgG (gray columns) or with TNF receptor IgG
fusion protein (TNFR-IgG, black columns).
Blockade of TNF with TNFR-IgG antagonized the reduced total neurite
length, axonal length, and number of branch points of neurons derived
from wild-type, but not TNFR / mice. Data are presented as
mean ± SEM of three independent experiments.
|
|
The effects of both membrane-bound as well as soluble TNF can be
blocked by a TNF receptor IgG fusion protein. Therefore, we treated the
cultures with TNF receptor IgG fusion protein and control IgG. Reduced
total neurite length, axonal length, and number of branch points were
completely antagonized by blockade of TNF activity with TNF receptor
IgG fusion protein (Fig. 6). Neurons of cultures treated with TNF
receptor IgG fusion protein for 16 hr showed total neurite outgrowth
per cell of 502 µm (±18.9 µm SEM) and axonal length of 180 µm
(±28.7 µm SEM), whereas neurons of cultures treated with control IgG
showed total neurite length per cell of 176 µm (±9.8 µm SEM) and
axonal length of 55.6 µm (±4.7 µm SEM) (Fig. 6). No change in
neuronal survival was detected after treatment with the TNF receptor
IgG fusion protein (Table 2). Hippocampal
neurons derived from TNFRI- plus TNFRII-deficient mice did not show
substantial reduction in total neurite length, axonal length, and
number of branch points after culture on TNF-producing astrocytes (Fig.
6).
In the next step we added the TNF receptor IgG fusion protein to
hippocampal neurons cultured on unstimulated glial cells not secreting
detectable amounts of TNF (Fig. 7). No
change in neurite outgrowth and branching was detected after treatment
of unstimulated cultures with the TNF receptor IgG fusion protein, indicating that unstimulated glia and the low-density neurons do not
secrete sufficient amounts of TNF to modulate neurite outgrowth and
branching.
View larger version (52K):
[in this window]
[in a new window]
|
Figure 7.
Morphometric analyses of primary hippocampal
neurons cultured for 16 hr on unstimulated glia. Neurons were derived
from E16 C57BL/6 mice (Neurons wild-type) or C57BL/6
TNFRI- plus TNFRII-deficient mice (Neurons TNFR /).
The cultures were treated for 16 hr with control IgG
(gray columns) or with TNF receptor IgG fusion
protein (TNFR-IgG, black columns).
Blockade of TNF with TNFR-IgG did not change the total neurite length,
axonal length, and number of branch points of neurons cultured on
unstimulated glial cells. Data are presented as mean ± SEM of
three independent experiments.
|
|
RhoA activation in hippocampal neurons after TNF treatment
Hippocampal neurons were cultured on
poly-L-ornithine-coated dishes without glial cells and were
treated with recombinant murine TNF (10 ng/ml). The cells were lysed at
different time points after treatment with TNF. The active form of RhoA
was precipitated with Sepharose beads conjugated with a GST-tagged
binding domain of Rhotekin that specifically binds to GTP-RhoA. The
amount of precipitated active RhoA was determined by Western blotting.
RhoA was activated by treatment with TNF within 1 hr. The activity of
the GTPase gradually increased after treatment with TNF up to 16 hr
(Fig. 8).
View larger version (14K):
[in this window]
[in a new window]
|
Figure 8.
RhoA activation in primary hippocampal neurons
after TNF treatment. Neurons were treated with 10 ng/ml TNF for
different time periods (15 min, and 1, 4, and 16 hr), and GTP-RhoA was
detected by Western blotting after precipitation with Rhotekin. TNF
activated RhoA within 1 hr, showing increasing levels up to 16 hr.
Activation of RhoA with 10% serum (10 min) served as a positive
control.
|
|
Reduced neurite outgrowth and branching in response to TNF is
mediated by Rho
Next, we analyzed whether the GTPase Rho was involved in the
effect of TNF on neurite length and branching of hippocampal neurons
cultured on glia. Rho can be inhibited efficiently by trituration of
the cells in the presence of C3 transferase, a procedure allowing cell
membrane passage of C3 transferase under special buffer conditions
(Borasio et al., 1989; Jin and Strittmatter, 1997). The C3 transferase
from C. botulinum specifically ADP ribosylates Rho and thus
inactivates the protein. Inhibition of neuronal Rho activity by
trituration of neurons together with C3 transferase inhibited the
effect of TNF on total neurite length, axonal length, and number of
branch points (Fig. 9). Specifically,
TNF-treated neurons triturated together with the C3 transferase showed
total neurite length of 426 µm (±75.2 µm SEM) and axonal length of
172 µm (±47.6 µm SEM) compared with TNF-treated neurons triturated with buffer alone showing total neurite length of 175 µm (±6.1 µm
SEM) and axonal length of 59 µm (±12.3 µm SEM) (Fig. 9).
View larger version (51K):
[in this window]
[in a new window]
|
Figure 9.
Morphometric analyses of primary hippocampal
neurons cultured for 16 hr on astrocytes. Neurons were derived from E16
C57BL/6 mice and either triturated together with C3 transferase
(Neurons C3 treated) or with buffer alone
(Neurons buffer). The cultures were untreated
(gray columns) or treated for 16 hr with 10 ng/ml
TNF (black columns). TNF-mediated reduction in total
neurite length, axonal length, and number of branch points was
antagonized in C3-treated but not control buffer-treated neurons. Data
are presented as mean ± SEM of three independent
experiments.
|
|
Subsequently, the effects of C3
transferase were analyzed on neurons cultured on astrocyte-enriched
glial cells and pretreated with IFN- and IL-1 (Fig. 10, Table
3). Again, inhibition of neuronal Rho activity by trituration of
neurons together with C3 transferase prevented the effect of
TNF-producing astrocytes on neurite length and morphology (Fig.
10).
View larger version (49K):
[in this window]
[in a new window]
|
Figure 10.
Morphometric analyses of primary hippocampal
neurons cultured for 16 hr on glia that has been pretreated for 24 hr
with IFN- and IL-1 to induce TNF production. Neurons were derived
from E16 C57BL/6 mice and either triturated together with C3
transferase (Neurons C3 treated) or with buffer alone
(Neurons buffer). The cultures were treated for 16 hr
with control IgG (gray columns) or with TNF
receptor IgG fusion protein (TNFR-IgG, black
columns). Trituration of neurons together with C3 transferase
antagonized the reduced total neurite length, axonal length, and number
of branch points. Data are presented as mean ± SEM of three
independent experiments.
|
|
| |
DISCUSSION |
This study demonstrates that TNF profoundly modulates neurite
branching and extension in hippocampal neurons in vitro via a mechanism that requires the small GTPase Rho. Recently, it has become
clear that the modulation of the activity of Rho GTPases is an
important link between signal transduction by membrane proteins and the
actin cytoskeleton (Hall, 1998). Activated Rho family GTPases stimulate
specific kinases (p65PAK or ROCK)
to phosphorylate one of the two isoforms of LIM kinase (LIMk1,
LIMk2; Sumi et al., 1999), and the actin polymerization is then
regulated through phosphorylation of cofilin and actin depolymerizing
factor by the LIM kinases (Arber et al., 1998). In neurons, Rho GTPases
act as important check points in the regulation of neuronal
morphogenesis, axonal growth and guidance, dendrite elaboration and
synapse formation (Luo et al., 1997; Luo, 2000). For instance,
inactivation of Rho with C3 transferase stimulates neurite growth of
PC12 cells (Lehmann et al., 1999), and Toxin B blocks axonal outgrowth
of primary hippocampal neurons (Bradke and Dotti, 1999). These in
vitro findings are of relevance in an in vivo context,
because crushed optic nerves treated with C3 transferase send numerous
axons through the lesion site and even elongate in the distal white
matter (Lehmann et al., 1999).
Recently, RhoA has been identified in neurons as a signaling node
linking the neurotrophin receptor p75NTR,
a member of the TNF receptor superfamily, to the cytoskeleton (Yamashita et al., 1999). The experiments established that
p75NTR acts as a constitutive RhoA
activator, whereas ligand binding causes rapid loss of RhoA activity
(Yamashita et al., 1999). We now show that other members of the TNF
receptor superfamily, the classical TNF receptors, stimulate RhoA in
primary hippocampal neurons. Interestingly, the direction and kinetics
of the effect are opposite between NGF and TNF. Transfection
experiments revealed that unligated p75NTR
constitutively activated RhoA, whereas NGF binding to the receptor inactivated RhoA activity within 3 min (Yamashita et al., 1999). This
effect was stable for several hours of sustained NGF stimulation. In
contrast, TNF leads to a delayed activation of RhoA reaching higher
levels of RhoA-GTP within 4-16 hr. No further increase was observed
after longer treatment periods with TNF (our unpublished observation). The p75NTR seems to act by
directly binding the GTPase RhoA (Yamashita et al., 1999), which might
explain the rapid effect of NGF on RhoA activity. In contrast, RhoA
activation in neurons by TNF might be indirect, as in a fibroblast cell
line, where TNF activated the GTPases in a highly ordered manner: first
Rac, followed by Cdc42, and finally Rho (Puls et al., 1999).
TNF reduced the neurite outgrowth and branching of the hippocampal
neurons. This effect was mediated by Rho and abolished after blocking
Rho with C3 transferase. Furthermore, two lines of evidence suggest
that TNF acts directly on neuronal TNF receptors to modulate neurite
morphology and not indirectly via glial cells. First, neurons derived
from TNFRI- plus TNFRII-deficient mice and cultured on normal
astrocytes showed almost no change in neurite morphogenesis. Second,
the inhibitory effect of TNF on neurite outgrowth and branching was
still detected in cultures of hippocampal neurons on glia derived from
TNFRI- plus TNFRII-deficient mice.
Glia stimulated to secrete TNF reduced neurite outgrowth and branching
of cocultured neurons. Although blockade of TNF activity with the
receptor fusion protein increased outgrowth and branching of neurons
cultured on stimulated glial cells, we did not observe a significant
change in neurite morphogenesis by this treatment in nonstimulated
glial cells. Thus, nonreactive gial cells and neurons do not produce
sufficient amounts of TNF to inhibit neurite outgrowth and branching of
neurons. However, we cannot exclude the possibility that our neuronal
density was too low to detect such possible effects of neurons.
Gene transcripts and protein expression of both TNF receptors (TNFRI
and TNFRII) were detected in cultured hippocampal neurons by
single-cell RT-PCR and immunohistochemistry, respectively. In
situ, neurons of the hippocampus of adult rats showed no or very
low gene transcription of TNFRII under basal conditions, whereas TNFRI
was induced and TNFRII upregulated by treatment with inflammatory
stimuli or after ischemia (Botchkina et al., 1997; Nadeau and Rivest,
1999). Furthermore, gene transcription and protein expression of TNF
and TACE (ADAM-17) have been observed in the CNS during
embryonic and different postnatal developmental stages (Munoz-Fernandez
and Fresno, 1998; Dziegielewska et al., 2000; Karkkainen et al., 2000).
In particular, TNF was localized by immunohistochemistry in cells with
neuronal morphology during early embryonic development of the neocortex
(Dziegielewska et al., 2000). However, it has not been shown that TNF
detected in the CNS during development is biologically active and
whether the level is comparable to inflammatory processes or injury of the CNS.
No gross anatomical CNS abnormalities of TNFRI- and TNFRII-deficient
mice under normal conditions were observed (our unpublished observation). However, a recent report suggested that TNF might be
involved in hippocampal synaptic plasticity. The induction of long-term
potentiation in region CA1 after stimulation of Schaffer collateral
axons was impaired in mice deficient for both TNF receptors (Albensi
and Mattson, 2000).
TNF and its receptors show polymorphism in humans, and recent reports
indicate that this polymorphism might be associated with a
noninflammatory brain disorder. In particular, a TNF gene polymorphism
[TNF2(A) allele] has been associated with schizophrenia (Wassink et
al., 2000), and patients homozygous for a TNFRII polymorphism (allele
1) showed significantly enlarged ventricles and smaller frontal lobes
(Boin et al., 2001).
In our experiments, ligation of TNF receptors by TNF stimulated RhoA
activity, whereas no effect on survival was observed. In theory, TNF
could induce cell death of pyramidal neurons, as shown with cultured
cerebellar neurons by antagonizing insulin-like growth factor I
(Venters et al., 1999). In another study, blockade of TNF by soluble
TNFR-I significantly reduced focal cerebral ischemic injury in
hypertensive rats, indicating a destructive potential of TNF in this
model (Dawson et al., 1996).
TNF can also be "neuroprotective" in pathological situations,
because transgenic mice lacking both TNF receptors have increased tissue lesions in response to ischemia (Bruce et al., 1996). Likewise, pretreatment of cultured hippocampal neurons with TNF reduced death of
neurons mediated by ischemia (Cheng et al., 1994).
Our finding that TNF affects neurite elongation suggests that TNF might
contribute to inhibit outgrowth of CNS axons during inflammation or
lesion of the CNS. This finding is of particular importance, because
axons do not regenerate after injury of the adult mammalian CNS.
Multiple signals converge to regulate neuronal survival and neurite
growth and determine the success or failure of axonal regrowth
(Goldberg and Barres, 2000). One barrier to regeneration has been shown
to be growth inhibition by myelin components such as Nogo (Chen et al.,
2000). The synthesis of inhibitory proteins at the glial scar has been
revealed as another impediment to axonal growth (Rudge and Silver,
1990; McKeon et al., 1991). Intriguingly, ablation of reactive
astrocytes promoted neurite outgrowth after injury in a transgenic
model (Bush et al., 1999). In this context, it is interesting to note
that TNF is produced by reactive glia after injury (Hopkins and
Rothwell, 1995) and deposited in the extracellular matrix where it
binds avidly to substrates such as fibronectin and laminin while
maintaining full biological activity (Alon et al., 1994; Hershkoviz et
al., 1994).
In conclusion, TNF secreted by reactive glia during injury or
inflammation might act as an anti-regenerative factor via its ability
to activate Rho proteins in neurons.
| |
FOOTNOTES |
Received Aug. 17, 2001; revised Oct. 24, 2001; accepted Nov. 6, 2001.
Work in the group of H.N. was supported by Deutsche
Forschungsgemeinschaft (SFB 391) and the Volkswagen-Stiftung. R.S. was supported by a predoctoral Marie-Curie fellowship from the European Commission. We thank Drs. Werner Lesslauer and Hansruedi Loetscher for
the gift of TNF receptor IgG fusion protein, Dr. Klaus Pfeffer for
TNFRI deficient mice, Dr. Martin-Alexander Schwartz for the RBD
plasmid, and Dr. Christine Bandtlow for the C3 transferase expression
construct. We are grateful to Lydia Penner for technical assistance.
Furthermore, we thank Dr. Isabelle Medana for helpful discussions.
Correspondence should be addressed to Harald Neumann, Neuroimmunology,
European Neuroscience Institute Göttingen, Waldweg 33, 37073 Göttingen, Germany. E-mail: hneuman1{at}gwdg.de.
| |
REFERENCES |
-
Albensi BC,
Mattson MP
(2000)
Evidence for the involvement of TNF and NF-kappaB in hippocampal synaptic plasticity.
Synapse
35:151-159[Web of Science][Medline].
-
Alon R,
Cahalon L,
Hershkoviz R,
Elbaz D,
Reizis B,
Wallach D,
Akiyama SK,
Yamada KM,
Lider O
(1994)
TNF-alpha binds to the N-terminal domain of fibronectin and augments the b1-integrin mediated adhesion of CD4+ T lymphocytes to the glycoprotein.
J Immunol
152:1304-1313[Abstract].
-
Arber S,
Barbayannis FA,
Hanser H,
Schneider C,
Stanyon CA,
Bernard O,
Caroni P
(1998)
Regulation of actin dynamics through phosphorylation of cofilin by LIM- kinase.
Nature
393:805-809[Medline].
-
Bibel M,
Barde YA
(2000)
Neurotrophins: key regulators of cell fate and cell shape in the vertebrate nervous system.
Genes Dev
14:2919-2937[Free Full Text].
-
Blobel CP
(1997)
Metalloproteinase disintegrins: links to cell adhesion and cleavage of TNF-alpha and Notch.
Cell
90:589-592[Web of Science][Medline].
-
Boin F,
Zanardini R,
Pioli R,
Altamura CA,
Maes M,
Gennarelli M
(2001)
Assocation between -G308A tumor necrosis factor alpha gene polymorphism, schizophrenia.
Mol Psychiatry
6:79-82[Medline].
-
Borasio GD,
John J,
Wittinghofer A,
Barde Y-A,
Sendtner M,
Heumann R
(1989)
Ras p21 protein promotes survival and fiber outgrowth of cultured embryonic neurons.
Neuron
2:1087-1096[Web of Science][Medline].
-
Botchkina GI,
Meistrell ME,
Botchkina IL,
Tracey KJ
(1997)
Expression of TNF and TNF receptors (p55 and p75) in the rat brain after focal cerebral ischemia.
Mol Med
3:765-781[Web of Science][Medline].
-
Bradke F,
Dotti CG
(1999)
The role of local actin instability in axon formation.
Science
283:1931-1934[Abstract/Free Full Text].
-
Bruce AJ,
Boling W,
Kindy MS,
Peschon J,
Kraemer PJ,
Carpenter MK,
Holtsberg FW,
Mattson MP
(1996)
Altered neuronal and microglial responses to excitotoxic and ischemic brain injury in mice lacking TNF receptors.
Nat Med
2:788-794[Web of Science][Medline].
-
Bush TG,
Puvanachandra N,
Horner CH,
Polito A,
Ostenfeld T,
Svendsen CN,
Mucke L,
Johnson MH,
Sofroniew MV
(1999)
Leukocyte infiltration, neuronal degeneration, and neurite outgrowth after ablation of scar-forming, reactive astrocytes in adult transgenic mice.
Neuron
23:297-308[Web of Science][Medline].
-
Chen MS,
Huber AB,
Van der Haar ME,
Frank M,
Schnell L,
Spillmann AA,
Christ F,
Schwab ME
(2000)
Nogo-A is a myelin-associated neurite outgrowth inhibitor and an antigen for monoclonal antibody IN-1.
Nature
403:434-439[Medline].
-
Cheng B,
Christakos S,
Mattson MP
(1994)
Tumor necrosis factors protect neurons against metabolic-excitotoxic insults and promote maintenance of calcium homeostasis.
Neuron
12:139-153[Web of Science][Medline].
-
Chisholm A,
Tessier-Lavigne M
(1999)
Conservation and divergence of axon guidance mechanisms.
Curr Opin Neurobiol
9:603-615[Web of Science][Medline].
-
Chung IY,
Benveniste EN
(1990)
Tumor necrosis factor-alpha production by astrocytes: induction by lipopolysaccharide, interferon-gamma and interleukin-1.
J Immunol
144:2999-3007[Abstract].
-
Dawson DA,
Martin D,
Hallenbeck JM
(1996)
Inhibition of tumor necrosis factor-alpha reduces focal cerebral ischemic injury in the spontaneously hypertensive rat.
Neurosci Lett
218:41-44[Web of Science][Medline].
-
Dziegielewska KM,
Moller JE,
Potter AM,
Ek J,
Lane MA,
Saunders NR
(2000)
Acute-phase cytokines IL-1beta and TNF-alpha in brain development.
Cell Tissue Res
299:335-345[Web of Science][Medline].
-
Goldberg JL,
Barres BA
(2000)
The relationship between neuronal survival and regeneration.
Annu Rev Neurosci
23:579-612[Web of Science][Medline].
-
Hall A
(1998)
Rho GTPases and the actin cytoskeleton.
Science
279:509-514[Abstract/Free Full Text].
-
Hershkoviz R,
Cahalon L,
Miron S,
Alon R,
Sapir T,
Akiyama SK,
Yamada KM,
Lider O
(1994)
TNF-alpha associated with fibronectin enhances phorbol myristate acetate- or antigen-mediated integrin-dependent adhesion of CD4+ T cells via protein tyrosine phosphorylation.
J Immunol
153:554-565[Abstract].
-
Hopkins SJ,
Rothwell NJ
(1995)
Cytokines and the nervous system. I. Expression and recognition.
Trends Neurosci
18:83-88[Web of Science][Medline].
-
Hsu H,
Shu HB,
Pan MG,
Goeddel DV
(1996)
TRADD-TRAF2 and TRADD-FADD interactions define two distinct TNF receptor 1 signal transduction pathways.
Cell
84:299-308[Web of Science][Medline].
-
Hu S,
Reichardt LF
(1999)
From membrane to cytoskeleton: enabling a connection.
Neuron
22:419-422[Web of Science][Medline].
-
Jin Z,
Strittmatter SM
(1997)
Rac1 mediates collapsin-1-induced growth cone collapse.
J Neurosci
17:6256-6263[Abstract/Free Full Text].
-
Karkkainen I,
Rybnikova E,
Pelto-Huikko M,
Huovila AP
(2000)
Metalloprotease-disintegrin (ADAM) genes are widely, differentially expressed in the adult CNS.
Mol Cell Neurosci
15:547-560[Web of Science][Medline].
-
Koukouritaki SB,
Vardaki EA,
Papakonstanti EA,
Lianos E,
Stournaras C,
Emmanouel DS
(1999)
TNF-alpha induces actin cytoskeleton reorganization in glomerular epithelial cells involving tyrosine phosphorylation of paxillin and focal adhesion kinase.
Mol Med
5:382-392[Web of Science][Medline].
-
Lehmann M,
Fournier A,
Selles-Navarro I,
Dergham P,
Sebok A,
Leclerc N,
Tigyi G,
McKerracher L
(1999)
Inactivation of Rho signaling pathway promotes CNS axon regeneration.
J Neurosci
19:7537-7547[Abstract/Free Full Text].
-
Luo L
(2000)
Rho GTPases in neuronal morphogenesis.
Nat Rev Neurosci
1:173-180[Web of Science][Medline].
-
Luo L,
Jan LY,
Jan YN
(1997)
Rho family GTP-binding proteins in growth cone signalling.
Curr Opin Neurobiol
7:81-86[Web of Science][Medline].
-
McKeon RJ,
Schreiber RC,
Rudge JS,
Silver J
(1991)
Reduction of neurite outgrowth in a model of glial scarring after CNS injury is correlated with the expression of inhibitory molecules on reactive astrocytes.
J Neurosci
11:3398-3411[Abstract].
-
Munoz-Fernandez MA,
Fresno M
(1998)
The role of tumour necrosis factor, interleukin 6, interferon-gamma and inducible nitric oxide synthase in the development and pathology of the nervous system.
Prog Neurobiol
56:307-340[Web of Science][Medline].
-
Nadeau S,
Rivest S
(1999)
Effects of circulating tumor necrosis factor on the neuronal activity and expression of the genes encoding the tumor necrosis factor receptors (p55 and p75) in the rat brain: a view from the blood-brain barrier.
Neuroscience
93:1449-1464[Web of Science][Medline].
-
Neumann H,
Cavalié A,
Jenne DE,
Wekerle H
(1995)
Induction of MHC class I genes in neurons.
Science
269:549-552[Abstract/Free Full Text].
-
Nobes CD,
Hall A
(1995)
Rho, rac, and cdc42 GTPases regulate the assembly of multimolecular focal complexes associated with actin stress fibers, lamellipodia, and filopodia.
Cell
81:53-62[Web of Science][Medline].
-
Puls A,
Eliopoulos AG,
Nobes CD,
Bridges T,
Young LS,
Hall A
(1999)
Activation of the small GTPase Cdc42 by the inflammatory cytokines TNF(alpha) and IL-1, and by the Epstein-Barr virus transforming protein LMP1.
J Cell Sci
112:2983-2992[Abstract].
-
Ren XD,
Kiosses WB,
Schwartz MA
(1999)
Regulation of the small GTP-binding protein Rho by cell adhesion and the cytoskeleton.
EMBO J
18:578-585[Web of Science][Medline].
-
Renno T,
Krakowski M,
Piccirillo C,
Lin J-Y,
Owens T
(1995)
TNF-a expression by resident microglia and infiltrating leukocytes in the central nervous system of mice with experimental allergic encephalomyelitis.
J Immunol
154:944-953[Abstract].
-
Rothe M,
Wong SC,
Henzel WJ,
Goeddel DV
(1994)
A novel family of putative signal transducers associated with the cytoplasmic domain of the 75 kDa tumor necrosis factor receptor.
Cell
78:681-692[Web of Science][Medline].
-
Rudge JS,
Silver J
(1990)
Inhibition of neurite outgrowth on astroglial scars in vitro.
J Neurosci Res
10:3594-3603.
-
Sumi T,
Matsumoto K,
Takai Y,
Nakamura T
(1999)
Cofilin phosphorylation and actin cytoskeletal dynamics regulated by rho- and Cdc42-activated LIM-kinase 2.
J Cell Biol
147:1519-1532[Abstract/Free Full Text].
-
Tchelingerian JL,
Quinonero J,
Booss J,
Jacque C
(1993)
Localization of TNF alpha and IL-1 alpha immunoreactivities in striatal neurons after surgical injury to the hippocampus.
Neuron
10:213-224[Web of Science][Medline].
-
Threadgill R,
Bobb K,
Ghosh A
(1997)
Regulation of dendritic growth and remodeling by Rho, Rac, and Cdc42.
Neuron
19:625-634[Web of Science][Medline].
-
Tucker KL,
Meyer M,
Barde YA
(2001)
Neurotrophins are required for nerve growth during development.
Nat Neurosci
4:29-37[Web of Science][Medline].
-
Venters HD,
Tang Q,
Liu Q,
VanHoy RW,
Dantzer R,
Kelley KW
(1999)
A new mechanism of neurodegeneration: a proinflammatory cytokine inhibits receptor signaling by a survival peptide.
Proc Natl Acad Sci USA
96:9879-9884[Abstract/Free Full Text].
-
Wassink TH,
Crowe RR,
Andreasen NC
(2000)
Tumor necrosis factor receptor-II: heritability and effect on brain morphology in schizophrenia.
Mol Psychiatry
5:678-682[Medline].
-
Wojciak-Stothard B,
Entwistle A,
Garg R,
Ridley AJ
(1998)
Regulation of TNF-alpha-induced reorganization of the actin cytoskeleton and cell-cell junctions by Rho, Rac, and Cdc42 in human endothelial cells.
J Cell Physiol
176:150-165[Web of Science][Medline].
-
Yamashita T,
Tucker KL,
Barde YA
(1999)
Neurotrophin binding to the p75 receptor modulates Rho activity and axonal outgrowth.
Neuron
24:585-593[Web of Science][Medline].
-
Zhao B,
Schwartz JP
(1998)
Involvement of cytokines in normal CNS development and neurological diseases: recent progress and perspectives.
J Neurosci Res
52:7-16[Web of Science][Medline].
Copyright © 2002 Society for Neuroscience 0270-6474/02/223854-09$05.00/0
This article has been cited by other articles:
|
|
|
|
 
S. J. Mathew, D. Haubert, M. Kronke, and M. Leptin
Looking beyond death: a morphogenetic role for the TNF signalling pathway
J. Cell Sci.,
June 15, 2009;
122(12):
1939 - 1946.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. Kakiashvili, P. Speight, F. Waheed, R. Seth, M. Lodyga, S. Tanimura, M. Kohno, O. D. Rotstein, A. Kapus, and K. Szaszi
GEF-H1 Mediates Tumor Necrosis Factor-{alpha}-induced Rho Activation and Myosin Phosphorylation: ROLE IN THE REGULATION OF TUBULAR PARACELLULAR PERMEABILITY
J. Biol. Chem.,
April 24, 2009;
284(17):
11454 - 11466.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
N. Gavalda, H. Gutierrez, and A. M. Davies
Developmental Regulation of Sensory Neurite Growth by the Tumor Necrosis Factor Superfamily Member LIGHT
J. Neurosci.,
February 11, 2009;
29(6):
1599 - 1607.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. M. Fontainhas and E. Townes-Anderson
RhoA and Its Role in Synaptic Structural Plasticity of Isolated Salamander Photoreceptors
Invest. Ophthalmol. Vis. Sci.,
September 1, 2008;
49(9):
4177 - 4187.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
B. Zhang, Y. K. Chan, B. Lu, M. S. Diamond, and R. S. Klein
CXCR3 Mediates Region-Specific Antiviral T Cell Trafficking within the Central Nervous System during West Nile Virus Encephalitis
J. Immunol.,
February 15, 2008;
180(4):
2641 - 2649.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. F. Segura, C. Sole, M. Pascual, R. S. Moubarak, M. Jose Perez-Garcia, R. Gozzelino, V. Iglesias, N. Badiola, J. R. Bayascas, N. Llecha, et al.
The Long Form of Fas Apoptotic Inhibitory Molecule Is Expressed Specifically in Neurons and Protects Them against Death Receptor-Triggered Apoptosis
J. Neurosci.,
October 17, 2007;
27(42):
11228 - 11241.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. Cavadini, S. Petrzilka, P. Kohler, C. Jud, I. Tobler, T. Birchler, and A. Fontana
From the Cover: TNF-{alpha} suppresses the expression of clock genes by interfering with E-box-mediated transcription
PNAS,
July 31, 2007;
104(31):
12843 - 12848.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Stagi, P. Gorlovoy, S. Larionov, K. Takahashi, and H. Neumann
Unloading kinesin transported cargoes from the tubulin track via the inflammatory c-Jun N-terminal kinase pathway
FASEB J,
December 1, 2006;
20(14):
2573 - 2575.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Krapf, S. P. Morrissey, O. Zenker, T. Zwingers, R. Gonsette, H. -P. Hartung, and the MIMS Study Group
Effect of mitoxantrone on MRI in progressive MS: Results of the MIMS trial
Neurology,
September 13, 2005;
65(5):
690 - 695.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Bessis, D. Bernard, and A. Triller
Tumor Necrosis Factor-{alpha} and Neuronal Development
Neuroscientist,
August 1, 2005;
11(4):
277 - 281.
[Abstract]
[PDF]
|
|
|
|
|
|
|
D. Stellwagen, E. C. Beattie, J. Y. Seo, and R. C. Malenka
Differential Regulation of AMPA Receptor and GABA Receptor Trafficking by Tumor Necrosis Factor-{alpha}
J. Neurosci.,
March 23, 2005;
25(12):
3219 - 3228.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
F. Pujol, P. Kitabgi, and H. Boudin
The chemokine SDF-1 differentially regulates axonal elongation and branching in hippocampal neurons
J. Cell Sci.,
March 1, 2005;
118(5):
1071 - 1080.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
K. Takahashi, C. D.P. Rochford, and H. Neumann
Clearance of apoptotic neurons without inflammation by microglial triggering receptor expressed on myeloid cells-2
J. Exp. Med.,
February 22, 2005;
201(4):
647 - 657.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Stagi, P. S. Dittrich, N. Frank, A. I. Iliev, P. Schwille, and H. Neumann
Breakdown of Axonal Synaptic Vesicle Precursor Transport by Microglial Nitric Oxide
J. Neurosci.,
January 12, 2005;
25(2):
352 - 362.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. R. John, L. Chen, M. A. Rivieccio, C. V. Melendez-Vasquez, A. Hartley, and C. F. Brosnan
Interleukin-1{beta} Induces a Reactive Astroglial Phenotype via Deactivation of the Rho GTPase-Rock Axis
J. Neurosci.,
March 17, 2004;
24(11):
2837 - 2845.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Nakajima, K. Yamada, T. Nagai, T. Uchiyama, Y. Miyamoto, T. Mamiya, J. He, A. Nitta, M. Mizuno, M. H. Tran, et al.
Role of Tumor Necrosis Factor-{alpha} in Methamphetamine-Induced Drug Dependence and Neurotoxicity
J. Neurosci.,
March 3, 2004;
24(9):
2212 - 2225.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Leemhuis, S. Boutillier, H. Barth, T. J. Feuerstein, C. Brock, B. Nurnberg, K. Aktories, and D. K. Meyer
Rho GTPases and Phosphoinositide 3-Kinase Organize Formation of Branched Dendrites
J. Biol. Chem.,
January 2, 2004;
279(1):
585 - 596.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Golan, T. Levav, A. Mendelsohn, and M. Huleihel
Involvement of Tumor Necrosis Factor Alpha in Hippocampal Development and Function
Cereb Cortex,
January 1, 2004;
14(1):
97 - 105.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. Brabeck, M. Mittelbronn, K. Bekure, R. Meyermann, H. J. Schluesener, and J. M. Schwab
Effect of Focal Cerebral Infarctions on Lesional RhoA and RhoB Expression
Arch Neurol,
September 1, 2003;
60(9):
1245 - 1249.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. I. Dubreuil, M. J. Winton, and L. McKerracher
Rho activation patterns after spinal cord injury and the role of activated Rho in apoptosis in the central nervous system
J. Cell Biol.,
July 21, 2003;
162(2):
233 - 243.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. C. Martinez, T. Ochiishi, M. Majewski, and K. S. Kosik
Dual regulation of neuronal morphogenesis by a {delta}-catenin-cortactin complex and Rho
J. Cell Biol.,
July 7, 2003;
162(1):
99 - 111.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. L. Hynds, M. L. Spencer, D. A. Andres, and D. M. Snow
Rit promotes MEK-independent neurite branching in human neuroblastoma cells
J. Cell Sci.,
May 15, 2003;
116(10):
1925 - 1935.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Kubo, T. Yamashita, A. Yamaguchi, H. Sumimoto, K. Hosokawa, and M. Tohyama
A Novel FERM Domain Including Guanine Nucleotide Exchange Factor Is Involved in Rac Signaling and Regulates Neurite Remodeling
J. Neurosci.,
October 1, 2002;
22(19):
8504 - 8513.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Tanaka, T. Yamashita, M. Asada, S. Mizutani, H. Yoshikawa, and M. Tohyama
Cytoplasmic p21Cip1/WAF1 regulates neurite remodeling by inhibiting Rho-kinase activity
J. Cell Biol.,
July 22, 2002;
158(2):
321 - 329.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
TOP
ABSTRACT
INTRODUCTION
