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First published online February 1, 2008
Journal of Experimental Biology 211, 491-501 (2008)
Published by The Company of Biologists 2008
doi: 10.1242/jeb.013102
RGD-dependent mechanisms in the endoneurial phagocyte response and axonal regeneration in the nervous system of the snail Lymnaea stagnalis
1 Department of Biological Sciences, Faculty of Science, University of Calgary,
Calgary, Alberta, Canada, T2N 1N4
2 Department of Physiology and Biophysics, Faculty of Medicine, Hotchkiss Brain
Institute, University of Calgary, Calgary, Alberta, Canada, T2N 4N1
* Author for correspondence (e-mail: wilderin{at}ucalgary.ca)
Accepted 4 December 2007
 |
Summary |
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 TOP Summary INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Key words: integrins, phagocytosis, spreading response, oxidative burst, axonal regeneration
|
INTRODUCTION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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; Battisti et al.,
1995; Brown et al.,
1997; Clatworthy and Grose,
1999; Frostick et al.,
1998; Fu and Gordon,
1997; Moffett,
1995; Moffett,
1996; Shen et al.,
2000; Zochodne,
2000). In mammals, peripheral nervous system regeneration is
preceded by a characteristic degenerative process during which distal elements
of the injured neuronal processes are absorbed and extensive remodelling of
the extracellular environment in the injured nerve occurs. Recruitment and
activation of various populations of phagocytes, including Schwann cells
assuming a phagocytic phenotype and resident and haematogenous macrophages,
are essential to this process, which is known as Wallerian degeneration
(Mueller et al., 2001;
Mueller et al., 2003;
Shen et al., 2000;
Stoll et al., 1989). Although
less exhaustively investigated, several studies indicate that repair of the
invertebrate nervous system also critically depends on the recruitment of
active phagocytes to the injury zone (Bale
et al., 2001; Hermann et al.,
2005).
In the absence of injury or inflammatory challenges, phagocytes typically
maintain a dormant state. Although numerous factors have been identified that
contribute to phagocyte activation and recruitment to the injury site, many
unanswered questions remain (Bruck,
1997; Rothshenker, 2003;
Zeev-Brann et al., 1998). In
particular, our understanding of the role of components of the extracellular
matrix (ECM) in the regulation of phagocyte responses to injury is limited.
The ECM is a complex three-dimensional structure containing a variety of
glycoproteins, proteoglycans and other components. Cells, including phagocytic
cell types, interact with many of these ECM components through a variety of
transmembrane cell adhesion receptors. One of the main classes of these
receptors is the integrins, a family of evolutionarily conserved, obligate
heterodimeric transmembrane receptors
(Burke, 1999;
Davids et al., 1999;
Giancotti and Ruoslathi, 1999;
Hughes, 2001;
Hynes, 1992;
Plows et al., 2006;
Wildering et al., 1998).
Integrins typically interact with their ligands, which include ECM
glycoproteins such as fibronectins, laminins and collagens, through short
linear amino acid motifs. One of the most common of these so-called integrin
recognition motifs is the three amino acid sequence Arg-Gly-Asp, also known as
the RGD-motif. The RGD-motif acts as a binding site for a sub-class of the
integrin family, including the most common fibronectin receptors
(Hynes, 1992;
Ruoslahti, 1996;
Ruoslahti and Pierschbacher,
1987). The current study focused on the significance of the
RGD-motif in axonal regeneration in the snail Lymnaea stagnalis, with
particular emphasis on the regulation of the injury response of phagocytes
residing in the animal's nerves (i.e. endoneurial phagocytes). Although
RGD-dependent mechanisms have been implicated in the regulation of the
activity of various circulating vertebrate and invertebrate phagocytic cell
types outside the nervous system (Ballarin
and Burighel, 2006; Ballarin et
al., 2002; Berton and Lowell,
1999; Davids and Yoshino,
1998; Gresham et al.,
1989; Hanayama et al.,
2002; Pech and Strand,
1995; Plows et al.,
2006), comparatively little is known about their role in the
regulation of immune effector cells residing in the nervous system. Yet,
recent studies suggest that they may serve a similar function in the control
of microglial activity in inflammatory conditions of the rodent nervous system
(Milner and Campbell, 2003;
Milner et al., 2007).
The current study aimed to examine the significance of RGD-motifs in the
regenerative response of the nervous system of Lymnaea using a model
system we recently developed (Hermann et
al., 2000; Hermann et al.,
2005; Wildering et al.,
2001). Because of their comparatively superior repair capacity,
invertebrates like Lymnaea have enjoyed wide usage as model systems
in the study of (functional) axonal repair
(Hermann et al., 2000;
Hermann et al., 2005;
Koert et al., 2001;
Moffett, 1995;
Moffett, 1996;
Wildering et al., 2001). Yet,
compared with the regenerative process in mammals, we know very little about
the non-neuronal factors contributing to successful regeneration in these
model systems. Recently, we identified a class of phagocytic cells residing in
Lymnaea's nerves as a key player in the regenerative response of this
model system (Hermann et al.,
2005). Here, we took a pharmacological approach based on the use
of synthetic water-soluble RGD-peptides to investigate the relevance of
RGD-dependent mechanisms in the activation of endoneurial phagocytes and the
injury response of the nervous system of Lymnaea. In a previous
study, we demonstrated this strategy to be effective in selectively
antagonizing adhesive interactions of Lymnaea cells with substrates
known to display the RGD-motif (Wildering
et al., 1998).
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MATERIALS AND METHODS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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;
Hermann et al., 2005;
Wildering et al., 2001). All
nerves were cut as far distally as possible without inflicting damage to the
proximal nerves and the rest of the nervous system. The lengths of the
peripheral nerves that remained attached to the ganglia varied depending on
the location of their target. The lengths of the visceral, right internal and
external parietal nerves that were used for the various experiments described
below were between 8 and 12 mm. After dissection, CNS were washed two times
for 5 min in antibiotic Hepes-buffered saline (ABS) composed of (mmol
l–1): 51.3 NaCl, 1.7 KCl, 4.1 CaCl2, 1.5
MgCl2 and 5 Hepes (pH 7.9), with 150 µg ml–1
gentamycin (Sigma Chemical Co., St Louis, MO, USA). Both right internal
parietal (RIP) and right external parietal nerves were crushed as described
previously (Hermann et al.,
2000; Hermann et al.,
2005; Wildering et al.,
2001). This technique severs the axon fibres in the nerve, but
preserves the nerve's perineurium and gross anatomy. Isolated CNS were pinned
on small silicone rubber pads (
36 mm2; RTV no. 616, General
Electric, Waterford, NY, USA) with 0.1 mm insect pins and cultured at room
temperature in a darkened chamber in ABS (2 CNS ml–1) with or
without the addition of the synthetic RGD-peptides Gly-Arg-Gly-Asp-Ser
(GRGDS) or cyclic Gly-Arg-Gly-Asp-Ser-Pro-Ala (cGRGDSPA) or the
`control' peptide Ser-Asp-Gly-Arg-Gly (SDGRG). Note that the control peptide
SDGRG contains the same amino acids as GRGDS but in reversed sequence.
After 48 h, an incubation period shown previously to yield optimal results
(Wildering et al., 2001),
axonal regeneration was examined by retrograde nickel-lysine staining of the
RIP nerve as described before (Hermann et
al., 2000; Hermann et al.,
2005; Wildering et al.,
2001). The nickel-lysine was applied at the cut end of the nerve
trunk, i.e. distal to the crush site (see
Hermann et al., 2000). The
extent of regeneration (i.e. re-growth of axons across the crush site) was
determined by counting the number of retrograde-labelled cell bodies of right
parietal A (RPA) group of motor neurons, known to project into the RIP nerve
(see also Wildering et al.,
2001). Analysis of the back-filled preparations was done in
duplicate, in a blinded fashion by two individuals who were unaware of the
treatment status of the samples.
Endoneurial phagocyte isolation
Endoneurial phagocytes were isolated from Lymnaea's visceral,
right internal and external parietal nerves using a procedure described
previously (Hermann et al.,
2005). Nerves were obtained from at least 15 CNS per experiment.
Care was taken not to isolate haemocytes present in the blood vessel. Four
samples of 100 µl each of the resulting cell suspension were added to 125
µl each of ABS only, ABS + SDGRG, ABS + GRGDS or ABS +
cGRGDSPA. These suspensions were subsequently plated on
poly-L-lysine (Sigma)-coated coverslips placed in 35 mm dishes
containing 3 ml of ABS with compositions identical to the media in which the
cells were suspended (i.e. ABS only, SDGRG, GRGDS or cGRGDSPA).
The cells were cultured in the dark at room temperature for 48 h in the
presence of a 1:7500 diluted suspension of monodispersed uncoated- or human
plasma fibronectin coated-polystyrene carboxylated Fluoresbrite YG
microspheres (0.75 µm; Polysciences, Warrington, PA, USA; see `Covalent
coupling of protein' below).
Morphology and phagocytosis assays
The morphology of the cells and phagocytic activity were examined 48 h
after cell isolation. In order to examine their morphology, the cells were
washed in 70% and 95% ethanol for 5 min each, stained for 1 min with fast
green FCF (0.03% in 95% ethanol; Sigma), washed in 95% ethanol for 10 s and
kept in absolute ethanol. Morphology and phagocytic activity were assessed by
taking 10–14 differential interference contrast (DIC) and fluorescence
images (excitation 480 nm/30 nm, emission 535 nm/40 nm) of 10–14
randomly selected areas in each culture dish at x100 magnification. At
x100, individual microspheres were readily recognizable and microsphere
uptake was quantified at this magnification. Images were acquired with an
intensified CCD camera (Stanford Photonics XR-GENIII+ Ultra-blue; Solamere
Technology Group, Salt Lake City, UT, USA) coupled to an inverted microscope
(Axiovert 100 TV; Zeiss, Oberkochen, Germany) and interfaced with a computer
through an 8-bit frame grabber board (DT3155; Data Translation, Marlboro, MA,
USA). Overlay pictures were used to confirm whether a cell had engulfed
microspheres or if a particle aggregation lay outside a cell.
Covalent coupling of protein
Human plasma fibronectin was covalently coupled to the carboxylated
polystyrene Fluoresbrite YG microspheres using the carbodiimide method as
described by the supplier (Polysciences Inc., technical data sheet 238C). That
is, after washing 0.5 ml of 2.5% microspheres twice in 0.1 mol
l–1 carbonate buffer (pH 9.6) and three times in 0.2 mol
l–1 phosphate buffer (pH 4.5), the microspheres were
resuspended in a 50/50 phosphate buffer (pH 4.5)/2% carbodiimide solution (in
phosphate buffer) and gently mixed for 4 h at room temperature. Subsequently,
the microspheres were rinsed three times with the phosphate buffer. The
microspheres were then resuspended in 0.2 mol l–1 borate
buffer (pH 8.5), and human plasma fibronectin (Boehringer Mannheim,
Indianapolis, IN, USA) was added to the microspheres to a final concentration
of 0.4 mg ml–1. The microsphere suspension was then
gently agitated overnight at room temperature. After centrifugation and
removal of the supernatant, the microspheres were resuspended in 1.2 ml 0.2
mol l–1 borate buffer (pH 8.5) with the addition of 50 µl
of 0.25 mol l–1 ethanolamine (2-aminoethanol; Sigma) and
mixed gently for 30 min. Subsequently, non-specific binding sites were blocked
by suspending the microspheres twice in 10 mg ml–1 BSA in
borate buffer for 30 min at room temperature. The microspheres were
resuspended and stored at 4°C in 0.5 ml storage buffer (1xPBS pH
7.4, 10 mg ml–1 BSA, 5% glycerol and 0.1% NaN3).
Spectrophotometric analysis of the supernatant remaining after termination of
the coupling reaction revealed no detectable traces of protein, indicating
that most fibronectin had bound to the microspheres.
Reactive oxygen species measurements
The production of reactive oxygen species (ROS) in the injured nerve was
assessed by means of labelling with the redox-sensitive fluorescent probe
5-(and-6)-chloromethyl-2',7'-dichlorodihydro-fluorescein
diacetate, acetyl ester (CM-H2DCFDA; Molecular Probes, Burlington,
ON, Canada). This chloromethyl derivative allows for covalent binding to
intracellular components to enhance intracellular retention of the probe (see
Molecular Probes manual `Reactive oxygen species (ROS) detection reagents';
www.probes.invitrogen.com/media/pis/mp36103.pdf).
To this end, CNS were isolated and RPA nerves were crushed as described above
and cultured for 1 h (acute) or 48 h in ABS alone or ABS + cGRGDSPA.
Subsequently, the CNS were incubated for 45 min in a solution of
CM-H2DCFDA (2 µmol l–1) plus Pluronic F127
(0.008%; Molecular Probes) and washed with ABS only for 15 min. The CNS were
placed on glass slides and the presence of ROS was immediately assessed by
taking phase contrast and fluorescence images (excitation 480 nm/30 nm,
emission 535 nm/40 nm) of the injured nerves using a Retiga Exi Fast cooled
CCD camera attached to a Zeiss Axiovert 200M inverted microscope (Oberkochen,
Germany). Illumination control, data acquisition and data analysis were done
with Northern Eclipse version 7.0 (Mississauga, ON, Canada) and were identical
for all preparations. The preparations were protected from prolonged exposure
to light at all times. CM-H2DCFDA is colourless and non-fluorescent
until the acetate groups are hydrolysed by intracellular esterases and
oxidation occurs within the cell, resulting in the green fluorescent
chloromethyl-2',7'-dichlorofluorescein (CM-H2DCF).
CM-H2DCF fluorescence intensity was measured in and immediately
distal and proximal to the crush zone.
Reagents, peptide reconstitution and application
The circularized RGD-peptide cGRGDSPA (Bachem, Torrance, CA, USA)
was dissolved in H2O to a stock concentration of 5 mmol
l–1 and stored at –20°C. The linear RGD-peptide
GRGDS (Bachem) and control peptide SDGRG (Bachem) were dissolved in
H2O to a stock concentration of 1 mmol l–1,
aliquoted, lyophilized and stored at –20°C. On the day of use, the
peptides were further diluted to the appropriate concentration with ABS.
CM-H2DCFDA was dissolved in DMSO (anhydrous, 99.9+%; Sigma) to a
stock concentration of 1 mmol l–1, aliquoted and stored at
–20°C. Aliquots were used within 7 days of preparation. The working
concentration of DMSO was 0.0005% in the in vitro assays and 0.002%
in the organ-culture studies.
Data analysis and statistics
All experiments were performed concurrently on matched experimental and
control groups. All animals were randomly sampled from one and the same tank.
The experiments were performed in triplicate. The numbers (N values)
given in the text and figure legends reflect the total number of brains or
total number of cells included under a particular condition. The effect of
RGD-peptides on axonal regeneration of RPA neurons was tested by means of a
one-way analysis of variance (ANOVA) or Student's unpaired t-test.
When required (i.e. as indicated by Kolmogorov–Smirnov one-sample tests
for normality), the data were logarithmically transformed prior to ANOVA. The
effects of RGD-peptides on phagocytic activity were tested by means of
Chi-squared tests. Associations between the spreading response and
CM-H2DCF fluorescence and the effect of different treatment
conditions on this association were evaluated using a stratified analysis of
2x2 RxC tables with the Breslow–Day test for the interaction
of risk ratio over the three strata
(Breslow and Day, 1980).
CM-H2DCF fluorescence intensity distributions in RIP nerves were
constructed with Northern Eclipse version 7.0. Averages and dispersion are
given as arithmetic means and standard error of the mean (s.e.m.) throughout
the text. Percentages of activated phagocytes are presented with their 95%
confidence intervals (CI95%) of ratios as calculated from the
F distribution according to a modified Wald method
(Agresti and Coull, 1998). A
two-sided critical value of statistical significance of P<0.05 was
adopted throughout the paper. Image acquisition conditions were exactly the
same for all preparations within an experiment.
|
RESULTS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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;
Wildering et al., 2001), which
allowed for examination of concentration-dependent effects of RGD-peptides on
axonal regeneration and phagocyte activation. To control for non-specific
effects of these peptides we used Ser-Asp-Gly-Arg-Gly (SDGRG), a reverse
sequence equivalent of GRGDS. The effectiveness of SDGRG as a negative
control was previously confirmed in adhesion studies
(Wildering et al., 1998).
RGD-dependent processes in axonal regeneration
To assess the general hypothesis that RGD-dependent processes are a key
factor in axonal regeneration in Lymnaea, we tested the effect of
GRGDS, SDGRG and cGRGDSPA on the regeneration of RPA motoneuron
axons in the organ-cultured Lymnaea CNS. In the first set of
experiments, a total of 82 isolated brains with crush-injured RIP nerves were
cultured under one of the following three conditions: (1) ABS only
(N=25); (2) ABS + SDGRG (100 µmol l–1;
N=27); and (3) ABS + GRGDS (100 µmol l–1;
N=30). As per our previous studies
(Hermann et al., 2000;
Hermann et al., 2005;
Wildering et al., 2001), the
extent of axonal regeneration of RPA group neurons was determined in each
preparation by means of backfilling regenerated axons with the retrograde
tracer nickel-lysine (Fig.
1Ai,Aii).
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The affinity and activity of synthetic RGD-analogues can be modified
substantially by substituting and/or adding amino acid residues surrounding
the RGD core, or by altering the secondary structure of the peptides. One such
modification, circularization, has been shown to be particularly effective in
boosting the activity of RGD-analogues
(Aumailley et al., 1991;
Tung et al., 1993;
Pfaff et al., 1993;
Schense and Hubbell, 2000;
Kato and Mrksich, 2004).
Circularized RGD-analogues typically have an approximately 100-fold higher
potency than the linear equivalents
(Aumailley et al., 1991;
Pfaff et al., 1993;
Wildering et al., 1998;
Wildering et al., 2002;
Schense and Hubbell, 2000;
Kato and Mrksich, 2004). In a
previous study, we showed that circularized RGD-analogues are about 100-fold
more potent than their linear equivalents in antagonizing adhesive
interactions of Lymnaea cells with a fibronectin matrix
(Wildering et al., 1998).
Prompted by this observation, we tested the dose dependency of cGRGDSPA
on axonal regeneration. A total of 180 preparations that had received a crush
injury to their RIP nerves were divided into six groups and cultured in ABS
only (N=30) or in ABS plus cGRGDSPA at five different
concentrations ranging from 10 nmol l–1 (N=33) to
100 µmol l–1 (N=30 for each group;
Fig. 1C). Treatment with
cGRGDSPA affected axonal regeneration of RPA neurons in a non-linear,
concentration-dependent manner (F5,177=2.839;
P<0.05; Fig. 1C).
That is, over the range from 10 nmol l–1 to 1 µmol
l–1, the number of back-labelled RPA axons declined
progressively. Above 1 µmol l–1, however, the inhibitory
effect of cGRGDSPA treatment reversed and at 100 µmol
l–1 it culminated in a slight increase in the number of
regenerated RPA axons. Note that the same concentration of the linear
RGD-peptide GRGDS strongly suppressed axonal regeneration of RPA neurons
(Fig. 1B).
In conclusion, the data presented above confirm that RGD-dependent processes are a crucial factor in axonal regeneration in Lymnaea nerves. In addition, the results show that the conformation in which the RGD-motif is presented has dramatic consequences for both the potency and nature of the effect of RGD-peptides on axonal regeneration in this model system.
RGD-peptides modulate endoneurial phagocyte activity
Axonal regeneration in its native tissue context involves a complex
interplay between many cellular and acellular factors, including the
recruitment of activated phagocytes to the injury zone. Previously, we
identified a class of phagocytes residing in the nerve as a key factor in
in vivo axonal regeneration in Lymnaea
(Hermann et al., 2005). Other
studies in closely related gastropod species (Biomphalaria glabrata)
show that RGD-dependent mechanisms are critical in the activation of
blood-borne phagocytes (i.e. haemocytes)
(Davids and Yoshino, 1998;
Davids et al., 1999).
Therefore, in view of the above results, we first tested whether RGD-peptides
influence the activation and activity of Lymnaea endoneurial
phagocytes in vitro.
To this end, we examined the effect of GRGDS and SDGRG using two
assays of phagocyte activation and activity, i.e. the spreading response and
microsphere engulfment of these cells. These experiments were performed under
one of the following three conditions: (1) ABS only, (2) ABS + SDGRG (100
µmol l–1) and (3) ABS + GRGDS (100 µmol
l–1) in the presence of either uncoated fluorescent latex
microspheres or microspheres coated with human plasma fibronectin. The
percentage of cells displaying a spreading response did not differ
significantly under the two control conditions, independent of whether they
were cultured in the presence of uncoated or fibronectin-coated microspheres
(Fig. 2B,C). Treatment with
GRGDS, however, significantly reduced the percentage of cells
exhibiting a spreading response in the presence of uncoated
(
2(2)=58.29, P<0.001, N=769;
Fig. 2B) as well as
fibronectin-coated microspheres (2(2)=36.67,
P<0.001, N=840; Fig.
2C).
|
), more than 50% of the cells that displayed a spread
phenotype under control conditions had internalized one or more microspheres
(see columns labelled ABS only and +SDGRG in
Fig. 3Bi and Ci). Treatment
with GRGDS had no significant effect on the percentage of spreading
cells that engulfed uncoated microspheres
(2(2)=0.298, P=0.86, N=410;
Fig. 3Bi) or on the
distribution of the number of uncoated microspheres taken up by individual
cells (Fig. 3Bii). In contrast,
the results were very different for fibronectin-coated microspheres. In
comparison with both control conditions, treatment with GRGDS
significantly reduced the percentage of spreading cells that had engulfed one
or more fibronectin-coated microspheres
(2(2)=15.16, P<0.001, N=477;
Fig. 3Ci). In addition, coating
with fibronectin significantly enhanced the number of beads taken up by
individual cells when cultured under control conditions (see ABS only and
+SDGRG in Fig. 3Cii; compare
with Fig. 3Bii). For example,
the percentage of cells that engulfed more than 30 coated microspheres
significantly increased from around 10% to more than 40% in both control
groups (Z=4.79 and 5.83 for ABS only and SDGRG-treated cells,
respectively; P<0.001). However, note that no such shift occurred
in the presence of GRGDS (Z=1.12, P=0.26;
Fig. 3Cii).
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2(3)=51.25; P<0.001, N=1350).
However, increasing cGRGDSPA dosage above 1 µmol
l–1 did not further enhance the peptide's inhibitory actions
on phagocyte spreading. Rather, the percentage of spreading cells increased to
a value slightly below the non-peptide control level. As shown in
Fig. 4B, which shows the
percentage of spread (i.e. activated) phagocytes that internalized
fibronectin-coated microspheres under each of the four aforementioned
conditions, a similar hyperbolic concentration-dependent trend was observed in
the effect of cGRGDSPA on microsphere uptake
(2(3)=31.57; P<0.001). Again, the
strongest inhibitory effect of cGRGDSPA was reached at an intermediate
concentration of 1 µmol l–1
(2(1)=28.19; P<0.001). At the highest
concentration of cGRGDSPA tested, fibronectin-coated microsphere uptake
was not significantly different from the value observed in the ABS-only
controls (2(1)=3.043; P>0.05).
Fig. 4C summarizes the
qualitative effects of cGRGDSPA in that it expresses the data in terms
of the percentage of activated phagocytes that had successfully internalized a
minimal number of fibronectin-coated microspheres. Note that 1 µmol
l–1 cGRGDSPA also reduced the number of microspheres
engulfed per phagocytic active cell (Fig.
4C). Thus, consistent with our observations above
(Fig. 1C), endoneurial
phagocyte activation is modulated by cGRGDSPA in a
concentration-dependent, biphasic manner.
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Taken together, these results lead to the following conclusions: (1) activation of Lymnaea endoneurial phagocytes in vitro is characterized by a spreading response; (2) the spreading response involves RGD-dependent mechanisms; and (3) RGD-peptides antagonize the uptake of fibronectin-coated (i.e. RGD-containing) but not uncoated latex microspheres, suggesting that Lymnaea endoneurial phagocytes utilize both RGD-dependent and RGD-independent internalization mechanisms.
RGD-peptides modulate the phagocytic response to nerve injury
The results described above indicate that RGD-peptides modulate various
aspects of endoneurial phagocyte physiology. To evaluate the relevance of
these in vitro observations in the much more complex context of whole
nerve tissue, we examined whether RGD-peptides affect the injury response of
endoneurial phagocytes in organ-cultured CNS preparations. Since neither
phagocyte spreading nor microsphere uptake can be effectively monitored in the
intact nerve, we approached this question by measuring the production of
reactive oxygen species (ROS). Enhanced ROS production, also known as the
`oxidative burst', is a hallmark of phagocyte activity that can be monitored
through the use of oxidation-sensitive fluorescent probes
(Donko et al., 2005;
Lehmann et al., 2000;
Park, 2003;
Sumimoto et al., 2005). In
these experiments we used
5-(and-6)-chloromethyl-2'7'-dichlorodihydrofluorescein diacetate
acetyl ester (CM-H2DCFDA), a cell-permeant indicator for ROS with
enhanced intracellular retention characteristics.
To validate CM-H2DCFDA for use in our applications, we first
tested this compound on endoneurial phagocytes in vitro. Cells were
isolated and cultured for 48 h as described before under the following three
conditions: ABS only (N=122), ABS + 1 µmol l–1
cGRGDSPA (N=134) and ABS + 100 µmol l–1
cGRGDSPA (N=134). At the end of the incubation period the
cells were loaded with CM-H2DCFDA. After allowing sufficient time
for hydrolysis of the probe to its active form (i.e.
chloromethyl-2'7'-dichlorodihydrofluorescein or
CM-H2DCF), the shape of the cell and the presence of fluorescent
labels were examined qualitatively using a combination of differential
interference contrast (DIC) and epifluorescence microscopy. As shown before
(Fig. 4), cGRGDSPA
suppressed phagocyte spreading at a concentration of 1 µmol
l–1 but had little effect at a concentration of 100 µmol
l–1. While the percentage of spreading cells differed
substantially between the cultures treated with 1 µmol l–1
cGRGDSPA (31.7%) and those maintained in ABS only (67.6%) and ABS + 100
µmol l–1 cGRGDSPA (51.5%), we found a strong
association between cell spreading and fluorescence labelling under all
conditions (Fig. 5). That is,
the percentage of spread phagocytes that were positively labelled was very
similar under all conditions (Fig.
5B). Likewise, the percentage of fluorescently labelled
non-spreading phagocytes was equally low under all three conditions
(Fig. 5Aii,B). Consequently, we
found no significant difference in the association between spreading and
CM-H2DCF fluorescence labelling across the three experimental
conditions (Breslow–Day test for interaction of risk ratio over strata:
2= 0.0673, P=0.967, d.f.=2). Overall, spreading cells
were fluorescently labelled with a more than 25 times higher likelihood than
non-spreading cells (Mantel–Haenszel adjusted risk ratio=25.2,
CI95%=11.19–55.78). Hence, we conclude that
CM-H2DCFDA is a reliable indicator of Lymnaea endoneurial
phagocyte activation and that, once cells are activated, ROS production in
itself is insensitive to treatment with RGD-peptides. Importantly, the data
also indicated that CM-H2DCF fluorescence was contained inside
activated cells (pilot studies with the parent molecule H2DCFDA
showed a substantial extracellular signal distribution, data not shown).
Obviously, this observation is consistent with the purportedly enhanced
intracellular retention of CM-H2DCFDA. The fact that
CM-H2DCF is largely insensitive to the accumulation of
extracellular ROS provides an advantage when monitoring the number of
activated phagocytes in injured nerves. Taken together, these results
demonstrate that CM-H2DCFDA is a reliable and effective indicator
of endoneurial phagocyte activity that is very well suited to quantify the
phagocytic response in injured RIP nerves.
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Both data sets showed that a nerve crush triggers a substantial oxidative burst in the injury zone and adjacent parts of the nerve (Fig. 6). In both data sets, CM-H2DCF fluorescence intensity was distributed in a parabolic fashion centred on the site of the injury (Fig. 6D,E). However, while essentially similar CM-H2DCF fluorescence distributions were found in all experimental groups, absolute values differed across the groups. Fig. 6D,E illustrates that, both immediately and 48 h after injury, CM-H2DCF fluorescence in the injury zone was less intense in the preparations treated with 1 µmol l–1 cGRGDSPA as compared with the other two test groups. While this difference was statistically significant in both the preparations cultured for 1 h (F2,2697=59.97; P<0.001) and those cultured for 48 h (F2,2697=535.7; P<0.001), comparison of the data from the two experiments shows that it was most prominent in the latter group (cf. Fig. 6D,E). We conclude from these data that treatment with 1 µmol l–1 cGRGDSPA significantly reduces acute (i.e. within 2–3 h) as well as long-term (i.e. 48 h post-injury) injury-induced ROS production in Lymnaea nerves, whereas treatment with a higher dose of cGRGDSPA has little or no effect.
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DISCUSSION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Our results identify RGD-dependent processes as a key regulator of the
Lymnaea endoneurial phagocyte response to nerve injury and make a
case for the involvement of one or more RGD-binding integrins and
RGD-presenting ligands. Our findings share intriguing parallels with those
recently reported by Milner et al. (Milner
et al., 2007), who implicated RGD-binding integrins
5β1 and vβ5 and their RGD-containing ligands
fibronectin and vitronectin in the regulation of microglial activation in a
mouse model of experimental autoimmune encephalomyelitis (EAE). Although we
are not yet in the position to identify the integrin homologues involved in
the effects presented here, recent data emerging from a collective effort to
sequence a Lymnaea brain-derived expression sequence tag (EST)
library indicates that Lymnaea, like other invertebrates, expresses
at least one integrin β-subunit with the hallmarks of an RGD-binding
integrin homologue (information from `Lymnaea stagnalis Sequence
Consortium',
www.Lymnaea.org,
personal communication W.C.W.). Thus, while more work is needed to settle this
issue, Lymnaea seems to be no exception to other invertebrates in
that it expresses at least one integrin receptor of the RGD-binding subfamily
[see Burke (Burke, 1999) or
Hughes (Hughes, 2001) for
discussion of the evolution of integrins).
Previously we demonstrated that, in vitro, the pharmacological
actions of RGD-peptides in Lymnaea are consistent with the existing
literature in that they only interfere with cell adhesion to fibronectin
substrates but not with adhesion to unmodified laminin, collagen or artificial
poly-anionic substrates (Wildering et al.,
1998). Thus, it is reasonable to postulate that, reminiscent of
the role of fibronectin and vitronectin in the activation of microglia in a
mouse EAE model (Milner and Campbell,
2003; Milner et al.,
2007), treatment with RGD-peptides interferes with the ability of
Lymnaea endoneurial phagocytes to bind fibronectin in vivo.
However, it should be noted that while the fibronectin/integrin
ligand/receptor pair constitutes the archetype of RGD-mediated cell adhesion,
fibronectin is not the only ECM protein containing RGD epitopes. In fact,
while fibronectin has only one RGD epitope, other ECM proteins like for
example collagen type IV may have as many as 11 RGD-containing epitopes.
However, in most cases these epitopes are unavailable for receptor binding and
therefore biologically inactive, i.e. they are referred to as matricryptic
RGD-sites (Davis et al.,
2000). A growing body of literature suggests that reconfiguration
of the parent molecule through proteolysis or other means may uncover these
matricryptic RGD-sites and thereby dramatically alter the biological activity
of the molecule (Davis et al.,
2000; Platt et al.,
2003; Schenk and Quaranta,
2003). In the case of the injury response of the mammalian PNS
such a scenario is quite probable. First of all several of the collagens,
including collagen type IV, are abundantly present in the basal membrane and
therefore quite common in the PNS. Moreover, PNS injury has been shown to
trigger the proteolytic activity of several members of the family of matrix
metalloproteinases including those capable of digesting collagens
(La Fleur et al., 1996;
Platt et al., 2003;
Shubayev and Myers, 2000).
Thus it is conceivable that matricryptic RGD-epitopes that normally do not
interact with RGD-selective integrins are involved in the activation of
phagocytic cell types during inflammatory- or injury-induced events in the
mammalian PNS. Although we have no detailed information about the variety and
distribution of ECM proteins expressed in the Lymnaea nervous system
the major ECM glycoproteins, including collagens, appeared early in the
evolution of metazoans and appear broadly represented in all modern metazoan
phyla including gastropod molluscs
(Exposito et al., 2002;
Garrone, 1998;
Miller and Hadley, 1991;
Moroz et al., 2006;
Müller and Müller,
2003; Serpentini et al.,
2000). Hence, future efforts to reveal the identity of the
endogenous integrin ligand(s) involved in RGD-dependent injury-induced
regulation of endoneurial phagocyte activity should, in addition to
fibronectin, also consider proteins containing matricryptic RGD-containing
epitopes as possible ligands of interest.
Alternative targets for RGD-peptides
Although our data identify endoneurial phagocytes as one of the targets of
RGD-peptides in axonal regeneration in Lymnaea nerves they are
probably not the only targets. Many studies have implicated integrins and/or
several of their ligands in axonal growth cone extension and navigation
(Condic, 2001;
Condic and Letourneau, 1997;
Gardiner et al., 2005;
Guan et al., 2003;
Ivins et al., 2000;
Kiryushko et al., 2004;
Tucker et al., 2005;
Vogelezang et al., 2001)
(reviewed by McKerracher et al.,
1996; Nakamoto et al.,
2004). In vitro studies demonstrated that
Lymnaea RPA neurons (i.e. the same neurons involved in the current
study) utilize RGD-dependent adhesion mechanisms to adhere to a fibronectin
substrate (Wildering et al.,
1998). Although we demonstrated in that study that RGD-peptides do
not interfere with brain conditioned medium-induced neurite outgrowth of these
neurons in vitro, we currently do not know whether this evidence can
be extrapolated to the organ-cultured brain. It is therefore conceivable that
part of the effects shown here involve direct actions of RGD-peptides on RPA
neurons themselves.
RGD-dependent and -independent processes
We have shown here that RGD-peptides interfere with various aspects of
endoneurial phagocyte activation (i.e. the spreading response and the
production of ROS) as well as with the process of phagocytosis itself. Similar
effects of RGD-peptides have been demonstrated in circulating immune effector
cells in a variety of species ranging from insects to mammals, indicating that
RGD-dependent, integrin-mediated processes are an evolutionarily conserved
feature in the regulation of metazoan cellular host defence systems
(Ballarin and Burighel, 2006;
Ballarin et al., 2002;
Davids and Yoshino, 1998;
Gresham et al., 1989;
Hanayama et al., 2002;
Moita et al., 2006;
Pech and Strand, 1995;
Plows et al., 2006).
Our results indicate that particle internalization by activated
Lymnaea endoneurial phagocytes involves at least one RGD-dependent
and one RGD-independent pathway. That is, our data show that RGD-peptides
interfere with the uptake of microspheres coated with RGD-containing proteins
but do not interfere with phagocytosis of uncoated microspheres. In this
context is it intriguing that a novel opsonin, called granularin, consisting
of a single von Willebrand factor (vWF) type C domain has recently been
isolated in Lymnaea (Smit et al.,
2004). This peptide, secreted by cells in the connective tissue
surrounding the CNS, opsonizes zymosan particles for phagocytosis by
haemocytes (i.e. blood-borne phagocytes). Granularin does not contain
RGD-motifs. At present we do not know whether granularin interacts with
endoneurial phagocytes. However, considering our data indicating that
Lymnaea endoneurial phagocytes also utilize RGD-independent
internalization mechanism, such a possibility should not be ignored.
Multiple integrins, multiple phagocyte populations
Although both linear and circular RGD-peptides significantly antagonize
endoneurial phagocyte spreading, a substantial proportion of the cells still
display the characteristic morphology of an activated phagocyte. Yet, our
results also show that RGD-peptides can interfere with internalization of
fibronectin-coated microspheres in the latter group of cells. There are
various scenarios that could explain these observations. For instance, as
suggested in a recent review (Humphries
and Yoshino, 2003), one plausible explanation is that we are
dealing with multiple phagocyte populations differing with respect to their
integrin phenotype. In this scenario, one or more of these populations relies
on RGD-dependent pathways for activation and at least one population uses
RGD-independent pathways for the purpose of activation but utilizes
RGD-dependent mechanisms for internalization of microspheres exposing
RGD-containing epitopes. This idea is consistent with the observation that
several phagocytic cell types can express multiple integrins with different
ligand affinities (Hynes,
1992; Moita et al.,
2006; Milner et al.,
2007). These observations may also provide an explanation for one
of the most puzzling features of our results, i.e. the biphasic,
concentration-dependent effects of the circular RGD-peptide cGRGDSPA on
endoneurial phagocyte activation and activity in vitro, as well as on
RPA neuron axonal regeneration and injury-induced ROS production in the
organ-cultured brain. In theory, these results could arise from the actions of
two integrins that have differential affinities for cGRGDSPA and that
are coupled to pathways with opposing effects on phagocyte function.
Alternatively, although the molecular basis of these effects is often not well
understood, there is evidence suggesting that depending on their
configuration, presentation and/or density, integrin ligands may have variable
effects on their receptor's ligand-binding, adhesive and signalling states and
may trigger a range of biological responses
(Eid et al., 2001;
Gaudet et al., 2003;
Hynes, 1992;
Legler et al., 2001;
Rajagopalan et al., 2004;
Schense and Hubbell, 2000;
Schense et al., 2000). In this
context, it is important to note that this is not the first time we observed
concentration-dependent, non-linear biological effects of cGRGDSPA. In
a previous study, we showed that depending on its concentration this peptide
can either enhance or suppress high voltage-activated Ca2+ currents
in Lymnaea neurons (Wildering et
al., 2002).
In summary, our results provide pharmacological support for the significance of RGD-mediated mechanisms in axonal regeneration of gastropod molluscs, a phylum known for the superior regenerative capacity of their nervous systems. Our data implicate RGD-dependent mechanisms in the regulation and execution of the Lymnaea cellular immune response triggered by nerve injury, an area that has thus far received little consideration in the study of nerve repair. In more general terms, our results suggest that further investigation into the interactions between RGD-binding proteins and their receptors is worthwhile for advancing our understanding of the management of inflammatory responses in tissue injury and repair.
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Acknowledgments |
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References |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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