(Received for publication, September 27, 1996, and in revised form, March 26, 1997)
From the Joint Program in Neonatology, Harvard Medical School, Boston, Massachusetts 02115
The syndecan family of transmembrane heparan sulfate proteoglycans is abundant on the surface of all adherent mammalian cells. Syndecans bind and modify the action of various growth factors/cytokines, proteases/antiproteases, cell adhesion molecules, and extracellular matrix components. Syndecan expression is highly regulated during wound repair, a process orchestrated by many of these effectors. Each syndecan ectodomain is shed constitutively by cultured cells, but the mechanism and significance of this shedding are not understood. Therefore, we examined (i) whether physiological agents active during wound repair influence syndecan shedding, and (ii) whether wound fluids contain shed syndecan ectodomains.
Using SVEC4-10 endothelial cells we find that certain proteases and
growth factors accelerate shedding of the syndecan-1 and -4 ectodomains. Protease-accelerated shedding is completely inhibited by
serum-containing media. Thrombin activity is duplicated by the 14-amino
acid thrombin receptor agonist peptide that directly activates the
thrombin receptor and is not inhibited by serum. Epidermal growth
factor family members accelerate shedding but FGF-2, platelet-derived
growth factor-AB, transforming growth factor-, tumor necrosis
factor-
, and vascular endothelial cell growth factor 165 do not.
Shed ectodomains are soluble, stable in the conditioned medium, have
the same size core proteins regardless whether shed at a basal rate, or
accelerated by thrombin or epidermal growth factor-family members and
are found in acute human dermal wound fluids. Thus, shedding is
accelerated by activation of at least two distinct receptor classes, G
protein-coupled (thrombin) and protein tyrosine kinase (epidermal
growth factor). Proteases and growth factors active during wound repair
can accelerate syndecan shedding from cell surfaces. Regulated shedding
of syndecans suggests physiological roles for the soluble proteoglycan
ectodomains.
The response to tissue injury is orchestrated by multiple soluble effectors. These are derived from the blood plasma, immigrant cells from the circulation and resident cells at the wound site, and include proteases, antiproteases, growth factors, cytokines, and chemokines (1). Heparin modifies the action of several of these effector molecules such as thrombin, antithrombin III, heparin-binding epidermal growth factor-like growth factor (HB-EGF),1 vascular endothelial cell growth factor, basic fibroblast growth factor, and interleukin-8 (2-4). These interactions focus attention on the potential regulatory role of the heparan sulfate that is at the surface of all adherent cells.
Much of the heparan sulfate at the cell surface is derived from the syndecan family of transmembrane proteoglycans. These four gene products consist of single polypeptides which comprise at their COOH termini a short cytoplasmic domain (28-34 amino acids) containing three invariant tyrosines, and at their NH2 termini an extracellular domain (ectodomain) that places heparan sulfate chains distal from the plasma membrane. The syndecans bind a variety of growth factors, cytokines, proteases, antiproteases, and cell adhesion molecules (5, 6), are individually expressed in distinct cell-, tissue-, and development-specific patterns (7), and show cell-specific variations in the structure of their heparan sulfate chains (8, 9).
Syndecan expression is highly regulated during development, neoplasia, and wound repair (2, 4, 6, 10). Following skin wounds in mice, the keratinocytes at the leading edge migrating into the wound show a loss of cell surface syndecan-1. Concomitantly, syndecan-1 expression increases on the endothelial cells and syndecan-4 expression increases on the dermal fibroblasts that comprise the forming granulation tissue (11, 12). Cell surface syndecan-1 and -4 and their transcripts are induced in cultured endothelia and fibroblasts by PR-39, a pig neutrophil-derived antimicrobial peptide, and analogous inductive activity is found in human wound fluid (13). While syndecan expression can be regulated at or following transcription, depending on the cell type or pathophysiological situation, the precise mechanism(s) underlying these changes is unknown (11, 14-17).
A diverse group of transmembrane proteins is regulated by proteolytic cleavage of their ectodomains which are then released into the surrounding milieu (18-20). These cell surface proteins often have soluble counterparts in vivo, and can be detected in various body fluids (18, 21). This shedding can result in solubilization of the functional domains of the cell surface proteins. Recently, this shedding has been shown to be a highly regulated process and a common system has been proposed for regulating the shedding of several transmembrane proteins released by the action of calcium ionophores or protein kinase C activators such as phorbol 12-myristate 13-acetate (PMA) (22-24).
It has been known for many years that syndecan-1 is shed constitutively by cultured cells (25) and that this shedding involves release of the soluble ectodomain (26). Indeed, each of the syndecan family members is shed (7) and the site of cleavage has been suggested to be a dibasic sequence (syndecan-1, -2, -3) or a basic residue (syndecan-4) adjacent to the plasma membrane (6, 25).
We have recently found that features of syndecan shedding are similar to those of the common system proposed to be responsible for shedding of several membrane-anchored growth factors, growth factor receptors, cell adhesion, and other membrane proteins. As with the common system, syndecan-1 and -4 are shed at basal levels, but this shedding is accelerated within minutes of treating cells with PMA (27). Drosophila syndecan lacks basic residues adjacent to the plasma membrane, yet is readily shed from cultured cells (28). Thus, as with cleavage by the common system, the amino acid sequence may not be of primary importance to the cleavage process. Finally, the apparent loss of cell surface syndecan-1 during wound repair, a process involving various proteases and growth factors, recalled the findings that receptor stimulation can activate the common shedding system (29-31).
Therefore, we examined whether (i) agents that are active during acute wound repair influence syndecan shedding and (ii) dermal wound fluids contain shed syndecans. We find that plasmin, thrombin, and epidermal growth factor (EGF) family members accelerate the shedding of the syndecan-1 and -4 ectodomains from cultured endothelial cell surfaces, that activation of at least two distinct receptor classes (G protein-coupled and protein tyrosine kinase) accelerates shedding, and that the syndecan -1 and -4 ectodomains are in acute human dermal wound fluids. Regulated shedding of the syndecans suggests a physiological role for the soluble proteoglycan ectodomains.
Recombinant human (rHu) HB-EGF was obtained from
Dr. J. Abraham (Scios-Nova, Mountain View, CA); rHu EGF, TGF-, and
FGF-2 from Intergen (Purchase, NY); rHu platelet derived growth factor AB from Upstate Biotechnology (Lake Placid, NY); rHu vascular endothelial cell growth factor 165 from Dr. G. Neufeld (Israel Institute of Technology, Haifa, Israel); rHu TNF-
and porcine platelet TGF-
1 from R & D Systems (Minneapolis, MN). Plasmin (human
plasma), thrombin (human plasma), thrombin receptor agonist peptide
(TRAP), soybean trypsin inhibitor, and genistein were from Calbiochem
(La Jolla, CA). Tyrphostin 25 and methyl 2,5-dihydroxycinnamate were
from Toronto Research Chemicals (Ontario, Canada). Urokinase-type plasminogen activator, PMA, and TPCK-treated trypsin were from Sigma.
Heparan sulfate lyase (heparatinase, EC 4.2.2.8) and chondroitin
sulfate ABC lyase (chondroitinase ABC, EC 4.2.2.4) were from Seikagaku
America Inc. (Rockville, MD).
Horseradish peroxidase-conjugated goat anti-rat IgG and horseradish peroxidase goat anti-rabbit IgG were purchased from Jackson ImmunoResearch Laboratories, Inc. (West Grove, PA) or Amersham Life Sciences. Antibodies specific to syndecan ectodomains included monoclonal antibodies 281-2 against the mouse syndecan-1 ectodomain (32), 5G9 and 8C7 against the syndecan-4 ectodomain (12), polyclonal antisera MSE-2, MSE-3, and MSE-4, against their respective recombinant mouse syndecan ectodomains (7) and polyclonal antisera HSE-1, against the recombinant human syndecan-1 ectodomain (12).
Serum antibodies prepared against the syndecan-1 and -4 cytoplasmic domains, which are identical in sequence across species, detect both mouse and human syndecan-1 and -4, respectively. Polyclonal antisera S7C, against a 7-amino acid synthetic peptide (KQEEFYA) corresponding to the COOH terminus of syndecan-1, has been described (26). Antibodies specific for the syndecan-4 cytoplasmic domain were prepared against a 13-amino acid peptide (LGKKPIYKKAPTN) unique to the syndecan-4 cytoplasmic domain. The immunogen was synthesized using the multiple antigen peptide system and used for immunization and boosts of rabbits at Quality Controlled Biochemicals Inc. (Hopkinton, MA). The antisera was called SCD-4 for syndecan cytoplasmic domain followed by the number corresponding to the specific syndecan family member.
Specificity of SCD-4 was determined by immunoprecipitation of [35S]S04-labeled SVEC4-10 cell lysates prepared in RIPA buffer (RIPA: 50 mM Tris-HCl, pH 7.4, 150 mM NaCl, 1% Nonidet P-40, 1% deoxycholate, 0.1% SDS, 5 mM EDTA, 1 mM phenylmethylsulfonyl fluoride) with antisera specific for each of the four syndecan ectodomains (281-2, MSE-2, MSE-3, and MSE-4). Each antigen-antibody complex contained radioactivity, indicating that these cells express all four syndecans. The complexes were eluted from protein A beads by boiling in 1:1 (v/v) of 2% SDS in 100 mM Tris-HCl, pH 7.4, the eluate was diluted to 0.1% SDS with RIPA buffer without SDS and equal portions were re-immunoprecipitated with SCD-4 sera and preimmune sera as a control. [35S]S04 counts in the resulting immune complexes were found only in the complex obtained with MSE-4. Thus, SCD-4 is selective for the cytoplasmic domain of syndecan-4.
Purification of SVEC4-10 Cell Lysates and Conditioned MediaThe shed form of syndecan-1 and -4 was partially purified from the conditioned media (CM) of confluent cells cultured for 3 days by QAE-Sephadex A-25 (Pharmacia) and cesium chloride density gradient separation similar to the method of Rapraeger and Bernfield (33). One µl of this partially purified CM represents the amount of heparan sulfate proteoglycan purified from 1 ml of SVEC4-10 CM. The native transmembrane form of syndecan-1 and -4 was prepared from a RIPA lysate of confluent cells in a 75-cm2 flask (Falcon). The lysate was partially purified on a DEAE-Sephacel column, precipitated with 95% ethanol containing 1.3% potassium acetate, and dissolved in deionized water. Five hundred µl of this partially purified lysate represents the amount of heparin sulfate proteoglycan in the lysate collected from 2.5 × 107 cells.
Wound Fluid and Plasma SamplesAcute human dermal wound
fluids were obtained and treated essentially as described by Grinnell
et al. (34) and Wysocki et al. (35). Briefly,
wound fluid was collected at 1-day intervals for three consecutive days
from sterile closed-suction drains routinely placed in the subcutaneous
space following mammoplasty. Fluids were centrifuged at 200 × g for 15 min to pellet cells and debri, and further
clarified at 3300 × g and stored frozen (70 °C).
Wound fluids were kindly provided by Dr. E. Eriksson, Brigham and
Women's Hospital, Boston, MA. The use of this anonymous discarded
material was approved by the Human Research Committee of the Brigham
and Women's Hospital, protocol number 92-5416-01. Blood plasma was
collected from human blood diluted 1:1 (v/v) with phosphate-buffered
saline, pH 7.4, at 37 °C following separation of cellular components
on a Ficoll (Histopaque 1083, Sigma) gradient by centrifugation at
1000 × g for 30 min at room temperature and stored
frozen (
70 °C).
SVEC4-10 cells were cultured in 96-well and 6-well tissue culture plates (Costar or Falcon) for 16 and 8 h assays, respectively. Cells were grown to confluence in Dulbecco's modified Eagle's medium containing glucose at 4.5 g/liter (Life Technologies, Inc., Grand Island, NY), supplemented with 10% fetal calf serum (FCS, Intergen, Purchase, NY) and L-glutamine. At the time of treatment, culture media was replaced with fresh media containing the indicated amounts of FCS and test agents. Following incubation for the indicated times, cells were examined by phase microscopy for survival and morphology and the conditioned media harvested for dot blot analysis. Cells in 96-well plates were fixed with 2% paraformaldehyde (in Hepes-buffered saline, pH 7.4, with 1 mM CaCl2, 0.5 mM MgCl2), washed with Tris-buffered saline (TBS) and extracted with 0.1 N NaOH or 1% Triton X-100 in 50 mM Tris-HCl, 1 mM EDTA, pH 8.0. Protein was measured using the BCA protein assay (Pierce) with bovine serum albumin as the standard. The 96-well plate (16 h) assays were performed in triplicate with 100 µl of media per well. The 6-well plate (8 h) assays yielded 600 µl of media per well, which was divided into three equal portions for dot blot analysis. All assays were performed at least three times.
Cell Surface TrypsinizationTrypsinization of cell surface syndecans from SVEC4-10 cell monolayers in 6-well plates was performed essentially as described (25). Briefly, following harvesting of the conditioned media (600 µl), cell layers were washed twice with ice-cold 0.5 mM EDTA-TBS and incubated with 600 µl of 10 µg/ml TPCK-treated trypsin in the same buffer for 10 min on ice. After incubation, soybean trypsin inhibitor was added to 50 µg/ml, cells were counted with a hemocytometer and centrifuged (200 × g) for 5 min at 4 °C. Supernatants containing the ectodomains were used immediately or stored at 4 °C for protein determination and dot immunoassay. Total RNA was extracted from pellets as described below.
Dot ImmunoassaySVEC4-10 cell conditioned media, lysates, and trypsinates, and human dermal wound fluids were diluted in Buffer A (0.15 M NaCl buffered to pH 4.5 with 50 mM NaOAc, with 0.1% Triton X-100), and applied to cationic polyvinylidene difluoride-based membranes (Immobilon-N, Millipore, Bedford, MA) under mild vacuum in an immunodot apparatus (V&P Scientific, San Diego, CA). The membranes were washed twice with Buffer A, and then blocked by a 1-h incubation in Blotto (3% Carnation instant nonfat dry milk, 0.5% bovine serum albumin, 0.15 M NaCl in 10 mM Tris, pH 7.4). Membranes were incubated with the indicated concentration of primary antibody specific for a syndecan ectodomain or cytoplasmic domain, washed in TBS containing 0.3% Tween 20, and incubated with a 5000-fold dilution of the appropriate horseradish peroxidase-conjugated secondary. All antibodies were diluted in Blotto with 0.3% Tween 20.
Detection was by the ECL system (Amersham) as described by the manufacturer, and quantitation was by laser densitometry using the LKB UltroScan XL densitometer (Pharmacia Biotech Inc.) running the GelScan XL software package (Pharmacia). Assay specificity was confirmed by eluting the membranes containing conditioned media by boiling in 2% SDS-PAGE sample buffer. The only immunoreactive materials detected on Western blots were the respective proteoglycans.
Assay quantitation was provided by including known standard amounts of the purified soluble syndecan-1 ectodomain (25) on each dot blot as an internal control. These showed a linear increase of absorbance units (AU) between 0.2 and 3.2 ng of syndecan-1. Standard amounts of SVEC4-10 cell conditioned media (day 3) were used as an internal control for the shed syndecan-4 ectodomain, and these also showed a linear increase of AU. In each case experimental values for dot blot quantitation were within these linear ranges. AU varied between experiments, in part, because of differences in exposure times and, in part, because of differences in treatment parameters. Thus, absorbance units were not compared between experiments. Results are expressed as the amount of syndecan shed in AU; for 16 h assays the values are normalized for micrograms of cellular protein. Each point represents the mean ± S.D. of triplicate determinations. Statistical significance was calculated using the Student's t test with the Instat biostatistic program.
Western Blot Analyis of Syndecans From Conditioned Media and Wound FluidsSVEC4-10 cells at confluence in 150-mm plates (Falcon, Lincoln Park, NJ) were incubated in 12 ml of serum-free medium for 16 h. Proteoglycans in the conditioned medium were precipitated twice with 95% ethanol containing 3% potassium acetate and resuspended in 100 mM Tris-HCl, pH 8.0, containing 0.1% Triton X-100, 5 mM EDTA, and 1 mM phenylmethylsulfonyl fluoride. Half of each sample was incubated with 10 milliunits/ml heparan sulfate lyase and 25 milliunits/ml chondroitin sulfate lyase ABC (Seikagaku America Inc., Rockville, MD) for 2 h at 37 °C. Enzyme-treated samples (0.5 and 2.5 ml of conditioned media equivalent for syndecan-1 and -4, respectively) were subjected to SDS-PAGE (3.5-20% gradient gel) with a discontinuous buffer system (69), and electrotransferred to Immobilon-N. The membrane was processed as for the dot immunoassay; syndecan-1 and -4 core proteins were detected using mAb 281-2 and antisera MSE-4, respectively, followed by ECL detection. Wound fluid (day 1 and 3) was immunoprecipitated using antiserum against the human syndecan-1 ectodomain (HSE-1), or a mixture of mAbs against the human syndecan-4 ectodomain (5G9 and 8C7). The protein A immune complexes were subjected to SDS-PAGE (3.5-20% gradient gel) and electrotransferred to Immobilon-N. A431 human squamous cell carcinoma cell conditioned media (day 3), partially purified by QAE-Sephadex A-25 (Pharmacia) and cesium chloride density gradient separation (33), was run as a control. Syndecan-1 and -4 were detected by ECL using HSE-1 or mAbs 5G9 and 8C7, respectively.
Northern Blot AnalysisTotal RNA was extracted from
approximately 1 × 106 cells by resuspension in
guanidinium denaturation solution, phenol/chloroform extraction, and
isopropyl alcohol precipitation as described in the Ambion Totally RNA
isolation kit (Austin, TX). RNA was separated in a 1% agarose, 0.6%
formaldehyde gel, transferred to Nytran membranes using the
Turboblotter (Schleicher & Schuell Inc.), and UV cross-linked.
Membranes were prehybridized and hybridized in QuikHyb (Stratagene, La
Jolla, CA) at 68 °C for 2 h with 1-2 × 106
cpm/ml of a BamHI-EcoRI fragment of the mouse
syndecan-1 cDNA (26). Blots were washed twice at room temperature
with 2 × SSPE, 0.1% SDS followed by two washes at 65 °C in
0.2 × SSPE with 0.5% SDS and exposed to film (X-Omat AR; Eastman
Kodak) with an intensifying screen at 80 °C. The membranes were
rehybridized with a 32P-labeled 800-base pair
PstI fragment of the mouse
-actin probe provided by Dr.
Stella Kourembanas (Childrens Hospital, Boston, MA) to quantitate the
relative amount of RNA per lane. Results were quantified by
densitometric scanning (Hewlett Packard Scan Jet IIC) using area
measurements from NIH Image, version 1.57.
We assessed whether agents known to be involved in wound repair regulate the shedding of syndecan ectodomains from the cell surface. SVEC4-10 cells, a mouse SV40 transformed endothelial cell line, were used as a test cell line (36). These cells were chosen because they remain viable in the presence or absence of serum, express both syndecan-1 and -4, and shed the ectodomains of these syndecans at a low basal rate.
Shedding was assayed by measuring the appearance in the culture media
of immunoreactive syndecan ectodomains. Shed proteoglycans are not
endocytosed by these cells during a 16-h incubation and thus are stable
within the conditioned medium (data not shown). NMuMG mouse mammary
epithelial cells were previously shown to shed the syndecan-1
ectodomain by demonstrating that the material in conditioned media (i)
migrated as a GAG-free core protein at the same
Mr as the trypsin-released ectodomain (25) but
smaller than the transmembrane proteoglycan (37), and (ii) failed to react with an antibody directed against the cytoplasmic domain (26). We
confirmed these results for syndecan-1 and -4 shed into conditioned
media by SVEC4-10 cells in the presence or absence of serum.
Proteoglycans in conditioned media and RIPA cell lysates were partially
purified as described under "Experimental Procedures," treated with
lyases to remove GAG chains, and subjected to SDS-PAGE and transferred
to cationic polyvinylidene difluoride membranes. As expected, the
glycosaminoglycan-free core proteins derived from the conditioned media
were smaller than those from lysates (data not shown). The
proteoglycans were immobilized on cationic membranes and probed with
core protein-specific antibodies directed against the ectodomains and
the cytoplasmic domains (Fig. 1). Antibodies against the
syndecan-1 and -4 ectodomains detected these proteoglycans in cell
lysates and conditioned media, as expected. Antibodies against the
cytoplasmic domains detected proteoglycans in the cell lysates, but
failed to detect proteoglycans in conditioned media, indicating that
these are the ectodomains.
We first examined the effect of various agents on syndecan shedding by
SVEC4-10 cells during a 16-h incubation in the presence and absence of
5% fetal calf serum. Basal shedding of syndecan-1 and -4 was barely
detectable, but shedding was markedly increased by PMA treatment (Fig.
2), as described previously (27). Both EGF and HB-EGF
(10 ng/ml) accelerated shedding, however, vascular endothelial cell
growth factor 165, FGF-2, platelet-derived growth factor AB, TGF,
and TNF
(10 ng/ml) did not (Fig. 2, and data not shown). This growth
factor-accelerated shedding was unaffected by incubation of the cells
in serum-containing medium. Both thrombin and plasmin accelerate
shedding, but urokinase-type plasminogen activator did not (Fig.
3). This protease-accelerated shedding was completely
inhibited by incubation of the cells in serum-containing media.
All members of the EGF family tested accelerated the shedding of
syndecan-1 and -4 from SVEC4-10 cells (Figs. 4,
A and B). EGF was the most potent while
amphiregulin was the least potent. Amphiregulin, FGF-2, and HB-EGF bind
heparin; this binding does not appear to influence whether syndecans
are shed in response to growth factors.
Thus, shedding of syndecan-1 and -4 appears to be a regulated process. PMA and only certain proteases and growth factors accelerate shedding from SVEC4-10 cells and shedding of both proteoglycans is affected similarly. Shedding accelerated by proteases is inhibited by serum, suggesting that serum contains inhibitors which prevent proteolytic scission of the core protein. On the other hand, PMA and growth factor accelerated shedding is not altered by incubation with serum, suggesting a different mechanism.
Accelerated Shedding Yields the Same Size Ectodomain Core ProteinsTo evaluate whether the shed ectodomains differ in size
when released from SVEC4-10 cells by distinct agents, cells were
incubated for 16 h with various accelerating agents in the absence
of serum. The media were harvested, proteoglycans were precipitated
with ethanol, and incubated with heparitinase and chondroitinase ABC, applied to SDS-PAGE, and the ectodomain core proteins analyzed by
Western blots. The GAG-free syndecan-1 and -4 ectodomain core proteins
(Figs. 5, A and B) were the same
size regardless whether shed at a basal rate, or accelerated by PMA,
thrombin, EGF or HB-EGF, or TGF-. These results suggest that the
shedding mechanism yields the same size product whether shed
constitutively or by a phorbol ester, protease, or growth factor.
Accelerated Shedding of Syndecans by Thrombin Is Receptor-mediated
Because the thrombin-released ectodomain was
the same Mr as ectodomains released by other
agents, we assessed whether syndecan shedding accelerated by thrombin
may result from thrombin receptor activation rather than direct
proteolytic cleavage. Increasing thrombin concentrations significantly
enhanced (p < 0.01) syndecan-1 ectodomain but reduced
syndecan-4 ectodomain levels in the culture media (Figs.
6, A and B), suggesting
proteolytic degradation of the syndecan-4 ectodomain. Thrombin receptor
activation requires the serine protease activity of its ligand,
thrombin (38). Therefore, cells were treated with TRAP, a 14-amino acid
peptide which directly activates the thrombin receptor and has no
inherent proteolytic activity (40). TRAP treatment caused a significant
increase (p < 0.01) in the levels of both the shed
syndecan-1 and syndecan-4 ectodomains in the culture media (Figs. 6,
A and B). Thus, direct activation of the thrombin
receptor can accelerate syndecan-1 and -4 shedding.
Accelerated Shedding of Syndecans by TRAP and EGF Involves Receptor Signaling
The kinetics of accelerated shedding were assessed
during the initial 8 h of TRAP- and EGF-accelerated shedding.
Accelerated shedding of syndecan-1 and-4 was detected as early as
1 h following treatment with either agent and the amount of shed
syndecan-1 (Fig. 7A) and syndecan-4 (Fig.
7B) increased with time at a nearly linear rate. Similar
responses were seen when NMuMG mouse mammary epithelial cells were used
in these assays (data not shown).
To determine whether these agents accelerate syndecan shedding by activating receptor signaling, we tested whether tyrosine kinase inhibitors affected shedding. Genistein, a specific tyrosine kinase inhibitor (39) reduced both TRAP- and EGF-accelerated shedding of syndecan-1 (Fig. 7A) and syndecan-4 (Fig. 7B). Similar results were obtained with the tyrosine kinase inhibitors tyrphostin 25 and methyl 2,5-dihydroxycinnamate (data not shown). Thus, tyrosine phosphorylation is involved in accelerating the shedding of syndecan-1 and -4 from the cell surface.
Receptor-mediated acceleration of syndecan shedding could be due to
several possible mechanisms. Thus, we assessed levels of cell surface
syndecan-1 and syndecan-1 mRNA during the initial 8 h of TRAP-
and EGF-accelerated shedding. The conditioned media of EGF-treated and
TRAP-treated cells accumulated 2- and 3-fold more syndecan-1 ectodomain
than untreated cells over an 8-h period, respectively (Fig.
8A). During this time, there was no
detectable change in the levels of cell surface proteoglycan (Fig.
8B). The levels of syndecan-1 mRNA did not increase
(Fig. 8C) during accelerated shedding. These results suggest
that accelerated shedding is accompanied by increased syndecan turnover
at the cell surface. Furthermore, no change in SVEC4-10 or NMuMG cell
morphology occurred during accelerated shedding, an observation which
implies that the cells have retained at least 50% of their cell
surface syndecan-1 during accelerated shedding (46).
Syndecan-1 and -4 Ectodomains Are Detected in Wound Fluid
During cutaneous wound repair in the mouse, keratinocytes
migrating into the wound transiently lose syndecan-1. Concurrently, syndecan-1 is transiently induced on the endothelial cells and syndecan-4 on the dermal fibroblasts that comprise the forming granulation tissue (11, 12). Furthermore, plasmin, thrombin, and EGF
family members, accelerators of syndecan-1 and -4 shedding from
cultured SVEC4-10 cells, are known to operate during acute wound
repair (1). Thus, we examined whether the fluids accumulating in acute
wounds contained syndecan-1 and -4. Human dermal wound fluids were
immunoprecipitated using antiserum HSE-1 or mAbs specific for the human
syndecan-4 ectodomain (5G9 and 8C7) and the precipitates run on
PAGE and analyzed by Western blots. Both precipitates contained materials that migrated as proteoglycans (Fig.
9A). Interestingly, the syndecan-1
immunoprecipitate contained both a proteoglycan smear and a lower
Mr smear. The latter may represent partially degraded syndecan-1.
To determine whether the wound fluid syndecans were the transmembrane proteoglycans or the ectodomains, the wound fluid proteoglycans were partially purified on cationic polyvinylidene difluoride membranes and probed with antibodies against the ectodomains and cytoplasmic domains as in Fig. 1. Antibodies against the syndecan-1 and -4 ectodomains detected proteoglycans in acute wound fluids, but not in plasma (Fig. 9B). In contrast, antibodies against the cytoplasmic domains failed to detect these proteoglycans (Fig. 9B). Thus, the syndecans in wound fluid are the ectodomains, likely shed from cell surfaces.
In this study we show that thrombin, plasmin, and members of the EGF family accelerate shedding of the syndecan-1 and -4 ectodomains from cultured endothelial cell surfaces, and that activation of at least two distinct receptor classes (thrombin (G-protein linked) and EGF (tyrosine kinase)) regulate syndecan shedding. Regulation of syndecan shedding appears to be physiologically relevant because EGF and thrombin receptors are both activated during wound repair, and we find the shed syndecan-1 and -4 ectodomains in the fluid that accumulates within acute dermal wounds. Because syndecan shedding is accelerated by multiple effectors that act directly or via receptors, these cell surface proteoglycans likely have additional physiological roles as soluble paracrine effectors.
Syndecan Ectodomains Are ShedSyndecan-1 and -4 are transmembrane proteoglycans but are released both into conditioned media and wound fluid as soluble proteoglycans. Their electrophoretic migration, presence of extracellular epitopes and absence of cytoplasmic domains demonstrate that the syndecans recovered from the conditioned media and wound fluid correspond to the intact ectodomains. Thus, shedding appears to result from a proteolytic process but the precise location of the cleavage site will require analysis of the amino- or carboxyl-terminal sequences of the cleavage products. Several different cleavage sites have been shown for shedding of other transmembrane proteins (18). Interestingly, the structure of syndecan-1 and -4 differ in several aspects that are potentially important for shedding, including the number and types of basic residues adjacent to the extracellular leaflet of the plasma membrane. Yet these proteoglycans responded similarly in this study to agents that accelerate shedding.
Shedding of Syndecan Ectodomains Is Regulated by Physiological EffectorsSyndecan-1 and -4 belong to the class of transmembrane proteins which undergo proteolytic cleavage and release of their ectodomains into the extracellular milieu when cells are treated with protein kinase C activators. The syndecan-1 ectodomain is shed from cultured adherent cells at a basal rate, but this shedding is markedly enhanced by suspension of the cells (25) or phorbol ester activators of protein kinase C (27). Trypsin treatment also releases the intact syndecan-1 ectodomain from cell surfaces (33). We now find that thrombin or plasmin releases the syndecan-1 and -4 ectodomain from cell surfaces, and this shedding is inhibited by serum. Thrombin-accelerated shedding was less evident with syndecan-4, presumably because the syndecan-4 ectodomain is more susceptible to proteolytic degradation than the syndecan-1 ectodomain. Thrombin receptor activation requires the serine protease activity of its ligand, thrombin (38). Thus, we tested whether the thrombin receptor agonist peptide, TRAP, which directly activates the receptor (40), also accelerates shedding. TRAP accelerated the shedding of both syndecan-1 and -4 ectodomains. Serum prevented thrombin-accelerated shedding, suggesting that serum inhibits the protease activity required for receptor activation. However, TRAP activation of the receptor does not involve protease activity and TRAP-accelerated shedding is not inhibited by serum. Thrombin may accelerate shedding both via direct proteolytic cleavage of the syndecan core protein and receptor activation.
Each member of the EGF family of growth factors tested accelerated the
shedding of syndecan-1 and -4 ectodomains from SVEC4-10 cells. Each of
these growth factors interacts with EGFR-1. Activity was independent of
the growth factor's ability to bind heparin. A variety of other growth
factors, including vascular endothelial cell growth factor 165, FGF-2,
platelet-derived growth factor AB, TGF, and TNF
failed to
accelerate syndecan shedding from these cells, implying that growth
factor-induced shedding from these cells is selective.
Shedding of the syndecan ectodomains is accelerated by cell suspension, proteases, direct PKC activation by phorbol esters, and specific ligand interactions with the thrombin and EGF receptors. The specific ligand interactions likely involve receptor activation because three tyrosine kinase inhibitors, genistein, tyrphostin 25, and methyl 2,5-dihydroxycinnamate, inhibit both EGF and TRAP accelerated shedding of syndecan-1 and -4 ectodomains. Because the inhibition is partial, multiple intracellular processes, some involving tyrosine kinases and others not, are likely involved in this regulated shedding process. Although we cannot rule out the possibility of indirect effects of the tyrosine kinase inhibitors, our results support a role for tyrosine phosphorylation in accelerated syndecan shedding.
The EGF receptor is a single-pass transmembrane protein which undergoes
dimerization and autophosphorylation at tyrosine residues, and can
transphosphorylate (41, 42). The thrombin receptor is a seven-pass
transmembrane protein that is coupled to GTP-binding (G) proteins (43).
Activation of either receptor can induce a
phosphorylation/dephosphorylation cascade, activate phospholipase C,
alter intracellular calcium concentrations, enhance diacylglycerol production and thus stimulate PKC, which is known to accelerate syndecan shedding (27). The common theme of these signaling cascades is
change in the levels of serine and/or tyrosine phosphorylation. However, the site(s) of phosphorylation that may augment this shedding
is unknown. Thus, syndecan shedding involves several effectors and at
least two distinct classes of cell surface receptors. The
susceptibility of syndecan shedding to multiple effectors that act
directly or via receptors implies that the ectodomains of these cell
surface molecules have physiological roles as soluble proteoglycans.
EGF or TRAP enhances the shedding of syndecan-1 and -4 ectodomains
within 1-2 h of treatment. However, at least for TRAP-accelerated shedding, the amount of shed proteoglycan cannot be accounted for by a
change in the level of cell surface proteoglycan. Thus, as shedding
proceeds, the turnover of syndecan-1 at the cell surface may also
increase. The syndecan-1 mRNA level is also unchanged, suggesting
that the translation rate increases and/or an intracellular pool is
depleted. Our results suggest that these cells maintain a steady state
level of cell surface syndecan-1 during accelerated shedding. This
could account for the lack of apparent change in cell morphology during
accelerated shedding, since a marked reduction in cell surface
syndecan-1 is accompanied by change in cell shape, rearranged 1
integrins, and disorganization of the actin cytoskeleton (44-46). Such
regulation of cell surface syndecan may enable cells to retain their
adhesive phenotype while shedding is accelerated.
Our finding that syndecan shedding is accelerated by multiple effectors that act through receptor-mediated events at the cell surface is consistent with the involvement of the common system proposed to regulate shedding of a heterogeneous group of transmembrane proteins (24). This system responds to multiple activators, induces cleavage of ectodomains at diverse sequences, and is inhibited by zinc ion chelators, suggesting the action of membrane-associated metalloproteinases. Whether syndecan shedding follows this same proposed mechanisms remains to be determined.
Receptor-mediated Syndecan Shedding Is Relevant to Wound RepairThe syndecan-1 and -4 ectodomains were readily detected in human dermal wound fluid on day 1 and 2 after wounding. These syndecan ectodomains were not detected in human plasma, indicating that they likely arose in the wound environment as a result of the injury. Syndecans in wound fluids had a relatively high average Mr, similar to that from mesenchymal cells (8, 14), possibly reflecting the cell type(s) from which they are derived. Syndecan-1 from keratinocytes has a lower Mr than from mesenchymal cells or other epithelial cells (14), implying that the endothelial and/or fibroblastic cells at the wound site may be the source of the shed syndecan ectodomains. The shed ectodomains may also undergo partial degradation by proteases and/or heparanases in wound fluid (1).
The effectors that accelerate syndecan shedding are known to act during
acute wound repair. Tissue injury is accompanied by cell disruption,
activation of proteases, and release of growth factors, each of which
accelerates syndecan shedding. The accelerated shedding that
accompanies cell suspension (25) could involve member(s) of the ADAMS
family, widely expressed transmembrane proteins that contain both
metalloproteinase and potential integrin binding domains (47). Both
thrombin and plasmin, formed during the blood coagulation process, the
initial event in tissue injury, can accelerate shedding. However, the
formation and activity of these proteases is tightly regulated, and
their ability to accelerate shedding may be limited in the presence of
fluid phase protease inhibitors such as 2-macroglobulin,
antithrombin III, and
2-antiplasmin. Indeed, in the
presence of serum, shedding by plasmin and thrombin from SVEC4-10
cells was inhibited. However, the platelet activation and aggregation
which occurs with hemostasis rapidly releases many mediators into
the wound, including EGF, HB-EGF, and TGF-
(1). The shedding
activity of these growth factors is not inhibited by serum components.
Interestingly, several other transmembrane proteins released by the
common shedding system are also involved in the response to tissue
injury. These proteins include the receptors for TNF-
(48, 49),
CSF-1 (50), interleukin-6 (24, 51, 52), and the growth
factors/cytokines TNF-
(53-56), CSF-1 (57, 58), TGF-
(23, 24,
59, 60), and HB-EGF (61), and the cell adhesion molecules V-CAM (62),
E- and L-selectin (24, 63-65). Hence, activation of this common
shedding system may be a component of wound repair.
The conversion of cell surface syndecans into soluble proteoglycans
during wound repair introduces anionic, multivalent molecules into the
wound environment. The significance of the regulated conversion of
membrane-anchored factors into soluble effectors has been emphasized
for cell adhesion molecules, growth factors, and growth factor
receptors (18-20, 66, 67). Especially important are findings, as with
CSF-1, TNF-, TGF-
, and HB-EGF, which show that the function of
the transmembrane protein may differ from that of its soluble
counterpart. The function of the syndecans as co-receptors for a large
number of physiological effectors is instantly changed when the
syndecan is released from the cell surface. Indeed, this change in
physical location can cause the soluble syndecan to compete for the
same ligands for which it was a co-receptor at the cell surface
(68).
We thank Shuyuan Zhao, Dmitry Leyfer, and Elena Shneider for technical assistance and Drs. Huiming Wang and John Lincecum for help with preparation of the figures. We also thank Dr. Elof Eriksson for providing wound fluid samples.