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¹ UK Centre for Tissue Engineering and ² Wellcome Trust Centre for Cell-Matrix Research, Faculty of Life Sciences, The University of Manchester, Manchester M13 9PT, England, UK

Correspondence to C. Adrian Shuttleworth: adrian.shuttleworth{at}manchester.ac.uk; or Cay M. Kielty: cay.kielty{at}manchester.ac.uk

Vascular endothelial growth factor (VEGF-A) is a crucial stimulator of vascular cell migration and proliferation. Using bone marrow–derived human adult mesenchymal stem cells (MSCs) that did not express VEGF receptors, we provide evidence that VEGF-A can stimulate platelet-derived growth factor receptors (PDGFRs), thereby regulating MSC migration and proliferation. VEGF-A binds to both PDGFR and PDGFRß and induces tyrosine phosphorylation that, when inhibited, results in attenuation of VEGF-A–induced MSC migration and proliferation. This mechanism was also shown to mediate human dermal fibroblast (HDF) migration. VEGF-A/PDGFR signaling has the potential to regulate vascular cell recruitment and proliferation during tissue regeneration and disease.

	Introduction

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The vascular endothelial growth factor (VEGF) and PDGF family members are closely related. In Drosophila melanogaster three PDGF/VEGF-like factors (PVFs) have been identified that function through a single receptor to mediate guidance of cell migration (Duchek et al., 2001; Cho et al., 2002). A PVF identified in Caenorhabditis elegans was shown to bind the human VEGF receptors (VEGFRs) VEGFR1 and VEGFR2, which mediated angiogenesis (Tarsitano et al., 2006). Sequence analysis of VEGF, PDGF, and PVF members predicts that VEGF and PDGF evolved from a common ancestor (Holmes and Zachary, 2005). Both VEGF and PDGF belong to the cystine-knot superfamily of signaling molecules, which is characterized by having a cystine-knot structure formed by eight cysteine residues (Vitt et al., 2001).

The most abundant and active member of the VEGF family is VEGF-A (Holmes and Zachary, 2005; Yamazaki and Morita, 2006), which undergoes alternative splicing to produce several different isoforms. The predominant human isoforms are VEGF-A₁₆₅ and -A₁₂₁, which lacks a heparin-binding domain (Neufeld et al., 1999). Three VEGFR tyrosine kinases (RTKs; VEGFR1-3) that form homodimers on ligand binding have been identified (Holmes and Zachary, 2005; Yamazaki and Morita, 2006). VEGF-A binds to VEGFR1 and VEGFR2, but not VEGFR3, but most signal transduction is mediated by VEGFR2 (Zachary and Gliki, 2001; Cross et al., 2003). All three VEGFRs are structurally related to the PDGF class III RTK subfamily, which are all characterized by seven extracellular immunoglobulin-like domains with an intracellular tyrosine kinase domain interrupted by a noncatalytic region (Petrova et al., 1999). These and other structural similarities between VEGFRs and PDGF receptors (PDGFRs) suggest a close evolutionary relationship (Kondo et al., 1998).

The PDGF family consists of four different PDGF chains (A–D), which assemble into functional homodimers or a PDGF-AB heterodimer, and two PDGFR tyrosine kinases ( and ß), which form a homodimer or heterodimer on ligand binding (Betsholtz, 2004; Fredriksson et al., 2004). PDGF-AA binds only PDGFR, whereas PDGF-BB binds both homodimer and heterodimer PDGFRs. The less abundant PDGF-CC and -DD bind to PDGFR and PDGFRß homodimers, respectively, with both binding to the PDGFRß heterodimer. PDGF-C and -D have a novel N-terminal CUB domain and are structurally more similar to the VEGF family than the PDGFs (Fredriksson et al., 2004; Reigstad et al., 2005).

VEGF-A and PDGF-BB are both critical factors in promoting the recruitment and proliferation of vascular cells (Benjamin et al., 1998; Yancopoulos et al., 2000). Adult bone marrow–derived mesenchymal stem cells (MSCs), which can differentiate to vascular cells (Galmiche et al., 1993; Kashiwakura et al., 2003; Ball et al., 2004), may be recruited during angiogenesis and to sites of vascular injury (Shimizu et al., 2001; Abedin et al., 2004). Although PDGF isoforms induce human MSC migration (Fiedler et al., 2004), less is known of VEGF-A–mediated effects, with several studies reporting no VEGFR expression in MSCs (Furumatsu et al., 2003; Kim et al., 2005). In this investigation, we examined the role of VEGF-A in regulating MSC migration and proliferation.

We report that VEGF-A can directly signal through PDGFR, which represents a novel VEGF-A/PDGFR signaling mechanism. This study provides important new insights into how VEGF signaling regulates MSC recruitment and proliferation during tissue regeneration and disease.

	Results

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MSC recruitment and proliferation by vascular growth factors are critical events during blood vessel growth, repair, and disease. In this study, we examined the chemotactic and mitogenic effects of VEGF-A on MSCs.

VEGF-A–induced MSC migration and proliferation
Boyden chamber migration assays were used to analyze the chemotactic effects of 10 ng/ml VEGF-A on MSC migration. 10 ng/ml PDGF was used as a positive control. Both VEGF-A₁₆₅ and -A₁₂₁ isoforms significantly increased MSC migration by 2.2-fold above basal levels (Fig. 1 A). In comparison, both PDGF-AA and -BB isoforms resulted in an 3.3-fold increase in MSC migration (Fig. 1 A). VEGF-A–induced MSC migration was dose dependent, with both isoforms producing maximal stimulation at 10 ng/ml VEGF-A (unpublished data).

View larger version (49K): [in this window] [in a new window] [Download PPT slide]   Figure 1. Exposure to VEGF-A increased MSC migration and proliferation. (A) MSC migration was examined in serum-free conditions after a 5-h exposure to a growth factor; 10 ng/ml VEGF-A165, VEGF-A121, PDGF-AA, or PDGF-BB in the lower half of a Boyden chamber. Basal represents growth factor–independent migration. Images below each bar graph are representative of migratory cells/field (using a 10x objective lens) on the membrane underside. Data shown are the mean number of migratory cells ± the SD determined from 10 random fields from each of four independent experiments. *, P < 0.001, compared with basal migration. (B) MSC proliferation was determined over a 5-d period after incubation with growth medium supplemented with fresh growth factor; 10 ng/ml VEGF-A165, VEGF-A121, PDGF-AA, or PDGF-BB every 24 h. Basal represents proliferation independent of supplemented growth factors. Data shown are the mean cell number ± the SD determined from triplicate assays from each of two independent experiments. *, P < 0.001; #, P < 0.005 compared with the respective basal cell proliferation.

MSCs do not express VEGFRs
To identify which VEGFRs were expressed on MSCs, RT-PCR analysis was performed using total RNA isolated from MSCs, with human umbilical vein endothelial cells (HUVECs) and human dermal fibroblast (HDF) cells used as VEGFR-positive and -negative control cells, respectively. Using two different sets of primer pairs for each VEGFR, no VEGFR1, VEGFR2, or VEGFR3 transcripts were identified in MSC- or HDF-derived RNA (Fig. 2 A). In comparison, both VEGFR1 and VEGFR2 transcripts were readily detected in HUVECs. Although all three cell types expressed VEGF-A, MSCs had the highest abundance, but only a low level was determined in HUVECs. In addition, all three cell types also expressed neuropilin (NP)-1 and -2 coreceptor transcripts, but HDFs expressed only a trace amount of NP-2 (Fig. 2 A). Single-color flow-cytometry, using either phycoerythrin (PE)-conjugated antibodies (Fig. 2 B) or FITC-labeled antibodies (unpublished data), both demonstrated that MSCs and HDFs expressed no detectable cell surface VEGFR1, VEGFR2, or VEGFR3 protein. In comparison, HUVECs were shown to express abundant cell surface VEGFR1 and VEGFR2 (Fig. 2 B). After the end of migration assays, when MSCs had been exposed to either 10 ng/ml VEGF-A₁₆₅ or -A₁₂₁ for 5 h, both RT-PCR and flow cytometry analysis again demonstrated no detectable VEGFR1-3 expression (unpublished data). Human MSCs from five different individuals were all VEGFR-negative, reflecting the lack of VEGFRs in these cells.

View larger version (44K): [in this window] [in a new window] [Download PPT slide]   Figure 2. MSCs expressed no VEGFRs. The expression of VEGFR mRNA transcripts was examined by semiquantitative RT-PCR analysis and cell surface protein expression by single-color flow cytometry, using human MSCs, HUVECs as a VEGFR-positive control cell, and HDF as a VEGFR-negative control cell. (A) RNA isolated from MSCs, HUVECs, and HDFs were used to amplify VEGFR1-3, VEGF-A, NP-1, and NP-2 transcripts, with GAPDH as a control, and then resolved by agarose gel. Lane 1, VEGFR1 (99 bp); lane 2, VEGFR2 (81 bp); lane 3, VEGFR3 (87 bp); lane 4, VEGF-A (98 bp); lane 5, GAPDH (71 bp); lane 6, NP-1 (77 bp); lane 7, NP-2 (83 bp). Data are representative of six independent experiments, with two different pairs of primers for VEGFR1-3 used. (B) Flow cytometry using PE-conjugated antibodies. Analysis of VEGFR1-3 is represented by VEGFR1-, VEGFR2-, and VEGFR3-PE expression, respectively, with IgG1-PE expression as a control. A representative example of three independent experiments is shown.

PDGFR and PDGFRß are essential for VEGF-A–induced MSC migration and proliferation

View larger version (45K): [in this window] [in a new window] [Download PPT slide]   Figure 3. Inhibiting PDGFR or PDGFRß attenuated VEGF-A–induced MSC migration. (A) MSCs, or HUVECs used as a VEGFR- positive cell, were pretreated with either 10 µg/ml anti-VEGFR1 or -VEGFR2 neutralization antibodies, 100 nM VEGFR2 tyrosine kinase inhibitor (VEGFR2-TK), 2 µM PDGFR tyrosine kinase inhibitor (PDGFR-TK), and 10 µg/ml anti-PDGFR or -PDGFRß neutralization antibodies; then, either 10 ng/ml VEGF-A165 or 10 ng/ml VEGF-A121 (not depicted) were added to the lower half of a Boyden chamber for 5 h. No inhibition represents control VEGF-A–induced migration. (B) As a control, MSCs were pretreated with either 10 µg/ml anti-PDGFR or -PDGFRß neutralization antibodies, and then 10 ng/ml PDGF-BB was added to the lower half of a Boyden chamber for 5 h. No inhibition represents control PDGF-BB–induced migration. (C) MSCs were transfected with either 3 µg siRNA PDGFR, siRNA PDGFRß, or scrambled siRNA used as a control. Transfected MSCs in serum-free conditions were either unstimulated as a control, or exposed to 10 ng/ml VEGF-A165 in the lower half of a Boyden chamber for 5 h. Images below each bar graph are representative of migratory cells/field (using a 10x objective lens) on the membrane underside. Data shown are the mean number of migratory cells ± the SD, which were determined from 10 random fields from each of four (A) or two (B and C) independent experiments. *, P < 0.001, compared with the respective uninhibited VEGF-A165–stimulated cells.

To further demonstrate that both PDGFR and PDGFRß are crucial receptors in directing VEGF-A–induced MSC migration, we used specific validated siRNA PDGFR and PDGFRß nucleotides to knockdown the respective transcripts. VEGF-A₁₆₅ stimulation of MSCs transfected with scrambled siRNA as a control resulted in an 2.5-fold increase in migration above unstimulated scrambled siRNA control levels (Fig. 3 C). However, VEGF-A₁₆₅ stimulation of MSCs transfected with either siRNA PDGFR or PDGFRß both resulted in a significant inhibition of migration (Fig. 3 C). Thus, PDGFR or PDGFRß inhibition by siRNA knockdown or cell surface neutralization (Fig. 3 A) both effectively inhibited VEGF-A₁₆₅–induced migration.

Having demonstrated that 5-d exposure to VEGF-A₁₆₅ significantly enhanced MSC proliferation (Fig. 1 B), we stimulated MSCs with VEGF-A₁₆₅ in the presence of either PDGFR or PDGFRß neutralization antibodies, and then examined the effects on proliferation at day 5. Blocking cell surface PDGFR or PDGFRß significantly inhibited VEGF-A₁₆₅–induced MSC proliferation (Fig. S1, available at http://www.jcb.org/cgi/content/full/jcb.200608093/DC1). In comparison, neither VEGFR1 nor VEGFR2 neutralization antibodies had any substantial impact on VEGF-A₁₆₅–induced MSC proliferation (Fig. S1). Thus, functional cell surface PDGFR and PDGFRß are both essential in mediating VEGF-A–induced MSC migration and proliferation.

VEGF-A–induced HDF migration was also mediated by PDGFR and PDGFRß
Having confirmed that HDFs did not express VEGFR transcripts or cell surface receptors (Fig. 2), we wished to establish whether VEGF-A could also induce HDF migration by a PDGFR-dependent mechanism. Flow cytometry demonstrated that HDFs expressed abundant cell surface PDGFR and PDGFRß (Fig. 4 A). Boyden chamber migration analysis demonstrated that both VEGF-A₁₆₅ and -A₁₂₁ isoforms significantly induced a similar level of HDF migration as either PDGF-AA or -BB; the level of migration was 2.0-fold above basal levels (Fig. 4 B). Selectively inhibiting either PDGFR or PDGFRß using specific cell surface neutralization antibodies before growth factor exposure significantly inhibited VEGF-A₁₆₅– and -A₁₂₁–induced HDF migration (Fig. 4 C and not depicted). The involvement of both PDGFR and PDGFRß in mediating VEGF-A₁₆₅–induced HDF migration was further demonstrated by siRNA PDGFR knockdown. VEGF-A₁₆₅ stimulation of HDFs transfected with scrambled siRNA as a control produced a 2.2-fold increase in migration above unstimulated control level, whereas siRNA knockdown of either PDGFR or PDGFRß resulted in a significant inhibition of VEGF-A₁₆₅–induced HDF migration (Fig. 4 D). Thus, both VEGF-A₁₆₅–induced MSC and HDF migration were dependent on a PDGFR-mediated mechanism.

View larger version (37K): [in this window] [in a new window] [Download PPT slide]   Figure 4. VEGF-A–induced HDF migration was PDGFR and PDGFRß dependent. (A) The expression of cell surface PDGFRs on HDFs were determined by single-color flow cytometry. Analysis of PDGFR and PDGFRß was performed using anti–human PE-conjugated antibodies, using an IgG1-PE antibody as a control. (B) The effects of VEGF-A on HDF migration and the involvement of PDGFRs were examined using Boyden chamber migration assays. HDF migration was evaluated in serum-free conditions after 5-h exposure to growth factor; 20 ng/ml VEGF-A165, VEGF-A121, PDGF-AA, or PDGF-BB in the lower half of a Boyden chamber. Basal represents growth factor–independent migration. (C) HDFs were pretreated with either 10 µg/ml anti-PDGFR or -PDGFRß neutralization antibodies, before adding 20 ng/ml VEGF-A165 to the lower half of a Boyden chamber for 5 h. No inhibition represents control VEGF-A165–induced migration. (D) HDFs were transfected with either 3 µg siRNA PDGFR, siRNA PDGFRß, or scrambled siRNA used as a control. Transfected HDFs in serum-free conditions were either unstimulated as a control, or exposed to 20 ng/ml VEGF-A165 in the lower half of a Boyden chamber for 5 h. Images below each bar graph are representative of migratory cells/field (using a 10x objective lens) on the underside of the membrane. Data shown are the mean number of migratory cells ± the SD determined from 10 random fields from each of three independent experiments. *, P < 0.001, compared with the respective uninhibited VEGF-A165 or PDGF-stimulated cells.

VEGF-A₁₆₅–induced PDGFR and PDGFRß tyrosine phosphorylation

RTK array analysis demonstrated that unstimulated MSC lysate resulted in all 42 different RTKs having a very low basal level of tyrosine phosphorylation (Fig. 5 A).

View larger version (51K): [in this window] [in a new window] [Download PPT slide]   Figure 5. VEGF-A stimulated both PDGFR and PDGFRß tyrosine phosphorylation. Human phospho-RTK arrays were used to examine VEGF-A–induced RTK phosphorylation levels in MSC lysate samples. Arrays contain phosphotyrosine-positive control spots in each corner, having coordinates (A1, A2), (A23, A24), (F1, F2), (F23, F24), which were assigned a pixel density value of 100, which was used to normalize positive RTK spot pixel density values. Relevant RTK duplicate spot coordinates: PDGFR = (C7, C8), PDGFRß = (C9, C10), VEGFR1 = (D9, D10), VEGFR2 = (D11, D12), VEGFR3 = (D13, D14), EGFR = (B1, B2), FGFR3 = (B13, B14), Axl = (B21, B22), EphA7 = (E3, E4). (A) RTK array analysis of control MSC lysate, not stimulated with exogenous growth factor (basal). (B) RTK array analysis of lysates from MSCs transfected with 3 µg scrambled siRNA as a control, siRNA PDGFR or siRNA PDGFRß, stimulated using 20 ng/ml VEGF-A165 in serum-free conditions for 10 min at 37°C. Each array was identically exposed to detection reagents and film. (C) Bar graph representing data from arrays (A and B). Mean pixel density ± the SD of duplicate spots, normalized against duplicate phosphotyrosine-positive control spots = 100. A representative example of two independent experiments is shown for each array analysis. *, P < 0.001 compared with the respective VEGF-A165–stimulated scrambled siRNA control.

After siRNA PDGFR or PDGFRß knockdown, followed by VEGF-A₁₆₅ stimulation, array analysis demonstrated that the cell lysate contained a significant decrease in the tyrosine phosphorylation state of PDGFR (densitometry value = 7 ± 1) and PDGFRß (densitometry value = 12 ± 1), respectively (Fig. 5, B and C). Thus, VEGF-A₁₆₅ stimulated dimerization and activation of both PDGFR and PDGFRß receptors. Interestingly, VEGF-A₁₆₅ stimulation also induced tyrosine phosphorylation of other RTKs, notably EGFR, EphA7, and Axl (Fig. 5 B).

Stimulation with PDGF-BB, which is the normal ligand for both PDGFR and PDGFRß, was also examined. This allowed a comparison with the level of VEGF-A₁₆₅–stimulated PDGFR and PDGFRß tyrosine phosphorylation, and also further validated the siRNA PDGFR knockdown efficiency and specificity. After siRNA PDGFR or PDGFRß knockdown, followed by PDGF-BB stimulation, the results demonstrated that the respective siRNA PDGFR and PDGFRß knockdowns were both effective and specific (Fig. 6 A), validating their corresponding effects in inhibiting VEGF-A₁₆₅–induced MSC and HDF migration (Fig. 3 C and Fig. 4 D). Using MSCs transfected with scrambled siRNA, followed by PDGF-BB stimulation, array analysis of the cell lysate demonstrated both PDGFR and PDGFRß tyrosine phosphorylation (densitometry values = 81 ± 6 and 294 ± 12, respectively; Fig. 6 A). Thus, whereas 20 ng/ml VEGF-A₁₆₅ induced similar levels of PDGFR and PDGFRß tyrosine phosphorylation (Fig. 5 B), in comparison, 20 ng/ml PDGF-BB induced 2.2- ± 0.1-fold and 6.0- ± 0.2-fold higher levels of PDGFR and PDGFRß tyrosine phosphorylation, respectively (Fig. 6 B).

View larger version (51K): [in this window] [in a new window] [Download PPT slide]   Figure 6. VEGF-A–induced PDGFR tyrosine phosphorylation was comparable to PDGF-BB–induced PDGFR level. (A) RTK array analysis of lysates from MSCs transfected with 3 µg scrambled siRNA as a control, siRNA PDGFR or siRNA PDGFRß, stimulated using 20 ng/ml PDGF-BB in serum-free conditions for 10 min at 37°C. Each array was identically exposed to detection reagents and film. A representative example of two independent experiments is shown. (B) Bar graph comparing VEGF-A165– and PDGF-BB–induced PDGFR tyrosine phosphorylation levels. Data represent VEGF-A165 and PDGF-BB–stimulated controls from RTK array analysis shown in Fig. 5 B and Fig. 6 A, respectively. Mean pixel density ± the SD of duplicate spots, normalized against duplicate phosphotyrosine-positive control spots = 100. (C) Immunoprecipitation (IP) analysis of PDGFR tyrosine phosphorylation levels. MSCs in serum-free conditions were unstimulated with growth factor (basal), or stimulated with either 20 ng/ml VEGF-A165 or PDGF-BB as a control, for 10 min at 37°C. PDGFRs were isolated from MSC lysates by IP analysis using anti-PDGFR or anti-PDGFRß, and then tyrosine phosphorylation detected by immunoblot (IB) analysis using anti-phosphotyrosine (Tyr-P). Membranes were reprobed with corresponding anti-PDGFR or anti-PDGFRß as loading controls. A representative of two independent experiments is shown.

VEGF-A induced a dose-dependent increase in PDGFR tyrosine phosphorylation
To further examine the effects of VEGF-A on PDGFR tyrosine phosphorylation levels, MSCs were exposed to increasing concentrations of VEGF-A₁₆₅ or PDGF-BB as a positive control. Both VEGF-A₁₆₅ and PDGF-BB produced a dose-dependent increase in PDGFR and PDGFRß tyrosine phosphorylation levels (Fig. 7). In the case of VEGF-A₁₆₅, the minimum concentration required to induce a detectable increase in PDGFR or PDGFRß tyrosine phosphorylation was 10 ng/ml (Fig. S2, available at http://www.jcb.org/cgi/content/full/jcb.200608093/DC1). In comparison, PDGFR and PDGFRß were initially stimulated using 5 and 2 ng/ml PDGF-BB, respectively (Fig. S2). Thus, the data further highlight the comparable tyrosine phosphorylation levels induced by PDGF-BB stimulating PDGFR and by VEGF-A₁₆₅ stimulating either PDGFR or PDGFRß.

View larger version (14K): [in this window] [in a new window] [Download PPT slide]   Figure 7. VEGF-A induced a dose-dependent increase in PDGFR tyrosine phosphorylation. The effects of varying VEGF-A165 concentration on induced PDGFR tyrosine phosphorylation levels was determined by specific ELISAs. MSCs in serum-free conditions were exposed to 0.5, 1, 2, 5, 10, 25, 50, 100, or 200 ng/ml VEGF-A165 for 10 min at 37°C. As a control, cells were also exposed to identical concentrations of PDGF-BB. MSC lysates were assayed for either PDGFR or PDGFRß tyrosine phosphorylation using a corresponding ELISA. Increased tyrosine phosphorylation is represented by an increase in optical density (OD450nm). Data shown are mean OD450nm ± the SD determined from two independent experiments performed in triplicate.

VEGF-A₁₆₅ bound to both PDGFR and PDGFRß
Having established by several methods that VEGF-A₁₆₅–stimulated tyrosine phosphorylation of both PDGFRs, we went on to confirm VEGF-A₁₆₅ binding to cell surface PDGFR and PDGFRß using a cross-linking approach. After VEGF-A₁₆₅ stimulation, PDGFR immunoprecipitation, and immunoblot analysis, a distinct association between VEGF-A and PDGFR or PDGFRß was demonstrated (Fig. 8 A). Cell surface inhibition of either PDGFR or PDGFRß using specific neutralization antibodies before growth factor stimulation resulted in decreased VEGF-A association with the corresponding PDGFR (Fig. 8 A), demonstrating the specificity of the interaction. Reprobing the membranes using anti–PDGF-B produced no immunoreactivity (unpublished data). Using the same approach, PDGF-BB (which binds both PDGFRs) stimulation as a positive control demonstrated that both PDGFRs associated with PDGF-BB (Fig. 8 B). In addition, TGF-ß₁ stimulation used as a negative control, immunoprecipitated with anti-PDGFRß, and immunoblotted using anti–TGF-ß₁ showed no detectable TGF-ß₁ association with PDGFRß (unpublished data), further demonstrating the specificity of the analysis.

View larger version (32K): [in this window] [in a new window] [Download PPT slide]   Figure 8. VEGF-A associated with both PDGFR and PDGFRß. Binding of VEGF-A to either PDGFR or PDGFRß was examined using a cross-linking approach. MSCs were unstimulated (basal) or stimulated with either 10 ng/ml VEGF-A165 (165) or PDGF-BB (BB) as a positive control, or 10 ng/ml TGF-ß1 as a negative control (not depicted), for 10 min at 37°C. To inhibit growth factor binding to the respective PDGFR, MSCs were also pretreated with either 10 µg/ml anti-PDGFR (R) or -PDGFRß (Rß) cell surface neutralization antibodies for 30 min at 37°C, before growth factor stimulation. Growth factor binding to PDGFR was captured by adding 1 mM of a cell membrane–impermeable cross-linking agent (DTSSP), followed by immunoprecipitation (IP) analysis using anti-PDGFR or anti-PDGFRß, then growth factor association detected by immunoblot (IB) analysis using corresponding (A) anti–VEGF-A or (B) –PDGF-B. Membranes were reprobed with anti-PDGFR or -PDGFRß as loading controls. A representative of three independent experiments is shown for each analysis.

View larger version (32K): [in this window] [in a new window] [Download PPT slide]   Figure 9. PDGF-induced MSC migration was inhibited by VEGF-A. The effects of VEGF-A on PDGF-induced MSC migration was examined using Boyden chamber migration assays. MSCs were preincubated with 10 ng/ml VEGF-A165 for 10 min, before adding the cell suspension onto the upper chamber membrane surface and exposure to 10 ng/ml PDGF-AA or -BB in the lower half of a Boyden chamber for 5 h. MSCs not exposed to either growth factor represents a growth factor–independent migration control. Images below each bar graph are representative of migratory cells/field (using a 10x objective lens) on the membrane underside. Data shown are the mean number migratory cells ± the SD determined from 10 random fields from each of two independent experiments. *, P < 0.001 compared with the respective migration induced by PDGF alone.

	Discussion

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Using complementary approaches, we provide evidence of a novel VEGF-A/PDGFR signaling mechanism, showing that VEGF-A can signal using both PDGFRs. Heparin-binding domains are important modulators of VEGF subtype binding and biological activity, VEGF-A₁₆₅ binds heparin, but VEGF-A₁₂₁ does not (Wijelath et al., 2006; Yamazaki and Morita, 2006). Because we demonstrated that both VEGF-A isoforms stimulated MSC and HDF migration, heparin binding is unlikely to be an important determinant. Pretreatment of MSCs with a PDGF RTK inhibitor significantly reduced VEGF-A–stimulated MSC migration. Neutralizing either cell surface PDGFR or PDGFRß using a specific blocking antibody also resulted in significant inhibition of VEGF-A–induced migration. Furthermore, blocking either PDGFR or PDGFRß expression using siRNA oligonucleotides significantly attenuated VEGF-A–induced migration, with RTK array analysis confirming decreased tyrosine phosphorylation of the respective PDGFRs. Thus, both PDGFRs are essential for VEGF-A–induced migration, suggesting that both PDGFR homodimers (- and -ßß) and/or a heterodimer (-ß) mediate VEGF-A/PDGFR signaling.

PDGFR neutralization by antibody blocking or siRNA knockdown resulted in a greater decrease in VEGF-A–induced migration than corresponding PDGFRß inhibition, which may reflect VEGF-A binding affinity to PDGFR. We have previously shown that the MSCs used in this study express abundant PDGFR, have a high ratio of PDGFR to PDGFRß, and, importantly, virtually every cell coexpressed both receptors (Ball et al., 2007). The two PDGFRs have different PDGF binding affinities; PDGFRß has a higher affinity for PDGF-B or -D, whereas PDGFR has a higher affinity for PDGF-A or -C (Betsholtz et al., 2004). PDGF-C and -D are structurally more similar to VEGF-A than to PDGF-A or -B (Reigstad et al., 2005), and both bind to a PDGFRß heterodimer (Fredriksson et al., 2004). MSCs exposed to PDGF-BB resulted in PDGFR and PDGFRß tyrosine phosphorylation levels being 2.2- and 6.0-fold higher, respectively, than corresponding VEGF-A–stimulated receptors. In comparison, VEGF-A induced similar levels of PDGFR and PDGFRß tyrosine phosphorylation, which may reflect a preference for PDGFRß stimulation. Thus, the data suggest that heterodimeric PDGFRß, at least in part, mediates VEGF-A/PDGFR signaling. The biological functions of PDGF-activated heterodimeric PDGFRß are not defined (Fredriksson et al., 2004).

Interestingly, phospho-RTK array analysis revealed that in addition to VEGF-A₁₆₅–induced PDGFR and PDGFRß tyrosine phosphorylation, VEGF-A₁₆₅ stimulated EGFR, EphA7, and Axl tyrosine phosphorylation. PDGF-BB also stimulated EGFR phosphorylation, as well as FGFR3, but not EphA7 or Axl receptors, indicating that EphA7- and Axl-induced tyrosine phosphorylation were VEGF-A specific. Because siRNA knockdown of either PDGFR or PDGFRß had little impact on EphA7 or Axl tyrosine phosphorylation levels, the mechanism of VEGF-A–induced, ligand-independent dimerization and activation of EphA7 and Axl receptors remains to be determined.

We demonstrated that either VEGF-A₁₆₅ or -A₁₂₁ isoforms were able to induce MSC and HDF migration, and that both cell types expressed NP-1 and -2 transmembrane glycoproteins. Although VEGF-A₁₆₅ binds to NP-1 and -2, VEGF-A₁₂₁ binds to neither (Gluzman-Poltorak et al., 2000). NPs are not known to signal independently after VEGF binding, but are proposed to act as coreceptors and facilitate binding of certain VEGF subtypes to VEGFRs (Neufeld et al., 2002). Thus, although we cannot discount a role for NPs, in the absence of VEGFRs, to facilitate VEGF-A₁₆₅ binding to PDGFRs, NPs are unlikely to be involved in mediating VEGF-A₁₂₁–induced chemotactic or mitogenic effects.

Along with finding that VEGF-A₁₆₅ was able to induce MSC migration, we also demonstrated that a low concentration of VEGF-A₁₆₅ at the cell surface can inhibit both PDGF-AA– and -BB–mediated chemotaxis, indicating that VEGFA₁₆₅ competes with PDGF ligands for PDGFR occupancy. Because both MSCs and HDFs were shown to express abundant VEGF-A transcript, it is tempting to speculate that autocrine expression of VEGF-A may act to regulate PDGF-induced chemotaxis in these cell types.

The demonstration that, in the absence of VEGFRs, VEGF can use PDGFR-mediated signaling in both MSCs and HDFs, suggests the intriguing possibility that under certain circumstances, VEGF may have an impact on a wider range of target cells than previously recognized.

VEGF-A is a crucial factor in promoting the recruitment and proliferation of vascular cells during both physiological and pathological angiogenesis and neovascularization (Pierce et al., 1995; Carmeliet and Jain, 2000). The local oxygen concentration controls the expression of VEGF, which is mediated, at least in part, by the transcription factor, hypoxia-inducible factor 1 (Forsythe et al., 1996). Therefore, in pathological hypoxic microenvironments, such as tumorigenesis (Carmeliet and Jain, 2000), disease progression is often associated with increased VEGF-A and vascular remodeling. MSCs are actively recruited during tumor neovascularization (Annabi et al., 2003; Aghi and Chiocca, 2005) and engraft into established tumor lesions (Hung et al., 2005), forming the basis for novel therapeutic approaches. Thus, VEGF-A/PDGFR signaling, especially during tissue hypoxia, is likely to be an important determinant in the recruitment and proliferation of MSCs and other PDGFR-positive cells.

	Materials and methods

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Cell culture
Human MSCs from normal bone marrow of 20- and 26-yr-old females and 18-, 22-, and 24-yr-old males (Cambrex), HUVECs from 35- and 29-yr-old females, and a pooled batch of HUVECs and HDFs from 23- and 32-yr-old males (Cascade Biologics) were maintained as previously described (Ball et al., 2004). MSCs were analyzed at passage 4, whereas HUVECs and HDFs were analyzed at passage 6. All were grown in serum-free medium for 24 h before analysis. The MSCs used in this study express a wide range of smooth muscle cell markers, including the smooth muscle cell–selective marker smoothelin-B (Ball et al., 2004), and can also differentiate into osteoblast, chondrocyte, and adipocyte lineages (McBeath et al., 2004). They are positive for CD29, CD44, CD105, and CD166, but negative for hematopoietic cell markers CD14, CD34, and CD45. We have also demonstrated that they are negative for the specific pericyte marker 3G5 (Nayak et al., 1988; Ball et al., 2007).

Growth factors and inhibitors
All growth factors, PDGF-AA (221-AA), PDGF-BB (220-BB), TGF-ß₁ (240-B), VEGF-A₁₆₅ (293-VE), and VEGF-A₁₂₁ (298-VS), were obtained from R&D Systems. Three different batches of VEGF-A₁₆₅ were used during this study, all containing BSA carrier protein (50 µg BSA/1 µg cytokine). We excluded the possibility that the VEGF-A may contain contaminant PDGF-BB (which binds to both PDGFRs). Immunoblot analysis (using anti–PDGF-B) readily detected 1 ng PDGF-B, but 100 ng VEGF-A₁₆₅ produced no PDGF-B immunoreactivity, indicating that any potential PDGF-BB contamination must be <1 ng (Fig. S2). However, the minimum concentration of PDGF-BB that induced a detectable PDGFR or PDGFRß tyrosine phosphorylation response was 5 ng and 2 ng, respectively (Fig. S2). Thus, any potential contamination of <1 ng PDGF-BB (in 100 ng VEGF-A₁₆₅) would not induce a detectable PDGFR tyrosine phosphorylation response.

In addition, VEGF-A₁₆₅ from two different suppliers (Invitrogen and Autogen Bioclear) was also tested, and both showed similar biological effects to the VEGF-A₁₆₅ obtained from R&D Systems.

Anti–human PDGFR (MAB322) and PDGFRß (AF385) antibodies were used to specifically neutralize PDGFRs, whereas anti–human VEGFR1 (AF321) and VEGFR2 (MAB3572) antibodies were used to specifically neutralize VEGFR1 and VEGFR2 (R&D Systems). PDGFR tyrosine kinase was inhibited using PDGFR tyrosine kinase inhibitor III (50 nM PDGFR IC₅₀; PDGFRß IC₅₀, 80 nM with IC₅₀ 30 µM for EGFR, FGFR, Src, PKA, and PKC; Matsuno et al., 2002; Calbiochem). VEGFR2 tyrosine kinase was inhibited using VEGFR2 inhibitor V (IC₅₀ < 2 nM with IC₅₀ > 50 µM for VEGFR1, EGFR, FGFR1 and PDGFRß; Endo et al., 2003; Calbiochem).

Semiquantitative RT-PCR
Semiquantitative RT-PCR was performed as previously described (Ball et al., 2004). Each primer pair was designed using the same parameters, resulting in similar Tm values (58.8–60.0) and product lengths as shown. VEGFR-1 (99-bp), forward (5'-GCGACGTGTGGTCTTACG-3') and reverse (5'-GGCGACTGCAAAAGTCCT-3'); VEGFR-2 (81-bp), forward (5'-CATCCAGTGGGCTGATGA-3') and reverse (5'-TGCCACTTCCAAAAGCAA-3'); VEGFR-3 (87-bp), forward (5'-GATGCGGGACCGTATCTG-3') and reverse (5'-ATCCTCGGAGCCTTCCAC-3'); VEGF-A (98-bp), forward (5'-CACCCATGGCAGAAGGAG-3') and reverse (5'-CACCAGGGTCTCGATTGG-3'); NP-1 (77-bp), forward (5'-GCAGTGGCTCCTGGAAGA-3') and reverse (5'-AGTCGCCTGCATCCTGTC-3'); NP-2 (83-bp), forward (5'-ATTCGGGATGGGGACAGT-3') and reverse (5'-CCCGAGGAGATGATGGTG-3'); and GAPDH (71-bp), forward (5'-AAGGGCATCCTGGGCTAC-3') and reverse (5'-GTGGAGGAGTGGGTGTCG-3'). An additional pair of primers for all three VEGFRs (VEGFR1-3) that was designed to different sequence regions were also used (primer sequences not shown).

Flow cytometry
For single-color flow cytometry, MSCs, HUVECs, or HDFs (4x10⁶ cells/ml) were incubated with either PE-conjugated anti–human VEGFR1-PE (FAB321P), VEGFR2-PE (FAB357P), or VEGFR3-PE (FAB3492P) antibodies, or control anti–IgG₁-PE antibody (IC002P; R&D Systems). VEGFR1 (MAB4711), VEGFR2 (MAB3572), VEGFR3 (MAB3491) antibodies, or control anti-IgG₁ (MAB002) antibody (R&D Systems) were also used after secondary labeling with a FITC secondary antibody (Dako Cytomation). HDFs were also incubated with either anti–human PDGFR-PE (sc-21789PE) or PDGFRß-PE (sc-19995PE) antibodies (Santa Cruz Biotechnology). For each sample, 100,000 cells were counted using a FACscan cytometer (Becton Dickinson) at a flow rate of <200 events/s.

Migration assay
Cell migration was determined using a modified Boyden chamber assay. Cell culture filter inserts of 8 µm pore size, 6.5 mm diam (Becton Dickinson), were coated on the underside with 10 µg/ml fibronectin in PBS, overnight at 4°C. MSCs (1x10⁵) were added to the upper chamber with 10 or 20 ng/ml growth factors in the lower chamber and cells allowed to migrate to the membrane underside for 5 h at 37°C in a humidified atmosphere of 5% CO₂ in air. In some experiments, cells were preincubated with receptor neutralization antibodies or kinase inhibitors (10 µg/ml anti-VEGFR1 or anti-VEGFR2 neutralization antibodies, 100 nM VEGFR2 tyrosine kinase inhibitor [VEGFR2-TK], 2 µM PDGFR tyrosine kinase inhibitor [PDGFR-TK], and 10 µg/ml anti-PDGFR or -PDGFRß neutralization antibodies) for 30 min at 37°C before growth factor exposure. After migration, cells on the upper membrane surface were removed and migratory cells on the membrane underside were fixed using 5% (wt/vol) glutaraldehyde and stained using 0.1% (wt/vol) crystal violet solution. Filter inserts were inverted and the number of migratory cells on the membrane underside (cells/field using a 10x NA 0.3 Olympus UPlanF1 objective lens) was determined, at room temperature, by visualizing the crystal violet–stained cells directly on insert undersides by phase-contrast microscopy, without use of fluorochromes (BX51; Olympus). Images were captured using a computerized imaging system (MetaMorph imaging v 5.0; Molecular Devices) and CoolSNAP (Photometrics) camera system.

Proliferation assay
MSCs (2,000 cells/well) in growth medium were seeded in 96-well plates and incubated with 10 ng/ml growth factors at 37°C in a humidified atmosphere of 5% CO₂ in air. Experiments were also conducted using MSCs pretreated with 10 µg/ml receptor neutralization antibodies for 30 min before growth factor addition. At the end of each time point, a CyQuant cell proliferation assay kit (Invitrogen) was used to detect MSC proliferation. Cells were treated in situ according to the manufacturer's protocol. To generate a standard curve, a serial dilution of MSCs (2,000–20,000) were also aliquoted into separate wells and treated the same as sample cells. Plates were read using a scanning multiwell fluorometer at a wavelength of 480 nm, and cell numbers were calculated using the standard curve for each plate.

RTK array analysis
A human Phospho-RTK Array kit (R&D Systems), which has a greater sensitivity than immunoprecipitation analysis, was used to simultaneously detect the relative tyrosine phosphorylation levels of 42 different RTKs in untreated or growth factor–treated MSC lysates. Each array contains duplicate validated control and capture antibodies for specific RTKs. MSCs cultured for 24 h in serum-free medium were stimulated with 20 ng/ml growth factors for 10 min at 37°C in a humidified atmosphere of 5% CO₂ in air, and then immediately placed on ice, washed twice with chilled PBS, and isolated using chilled lysis buffer (20 mM Tris-HCl, pH 8.0, 150 mM NaCl, 1% NP-40, 2.5 mM EDTA, 1 mM sodium orthovanadate, 10% glycerol, 10 µg/ml aprotinin, 10 µg/ml leupeptin, and 1 mM phenylmethylsulfonyl fluoride). Total protein concentration was quantitated using a BCA assay kit (Pierce Chemical Co.). RTK array analysis was performed according to the manufacturer's protocol. In brief, array membranes were blocked, incubated with 500 µg MSC lysate overnight at 4°C, washed, and incubated with anti–phosphotyrosine-HRP for 2 h at room temperature, washed again, and developed with ECL Western blotting detection reagent (GE Healthcare), and RTK spots were visualized using Kodak XAR film. Average pixel density of duplicate spots were determined by Gene Tools v3 software (Syngene), with values normalized against corner duplicate phosphotyrosine-positive control spots, which were assigned a value of 100.

siRNA transfection
MSCs (5x10⁵ cells), together with 3-µg siRNAs, were transfected by electroporation using a human Nucleofector kit (Amaxa) and cultured overnight in growth medium. Validated siRNAs, which were functionally tested to provide 70% target gene knockdown, were used for PDGFR and PDGFRß knockdown and a scrambled siRNA control (QIAGEN).

Phosphorylated PDGFR immunoprecipitation and sandwich ELISAs
Cells were isolated using ice-cold lysis buffer and 100 µg lysates precleared using 10% (wt/vol) protein A–Sepharose (GE Healthcare), and then incubated with monoclonal anti–human PDGFR (MAB1264) or PDGFRß (MAB1263; R&D Systems) overnight at 4°C. Immune complexes were isolated by incubation with 10% (wt/vol) protein A–Sepharose for 2 h. Immunoblot analysis was performed as previously described (Ball et al., 2004), using a monoclonal anti–human antibody for phosphorylated tyrosine (PY99; sc-7020; Santa Cruz Biotechnology). Human phospho-PDGFR, phospho-PDGFRß and soluble PDGF-BB levels were all detected by ELISA kits, performed according to the manufacturer's protocol (R&D Systems).

Cross-linking analysis of growth factor association with PDGFRs
After stimulation of MSCs in serum-free conditions with growth factor, 1 mM 3, 3'-Dithiobis[sulfosuccinimidyl propionate] (DTSSP; Pierce Chemical Co.) was directly added to the medium and incubated for 30 min at room temperature, and the cross-linking reaction was quenched using 20 mM Tris, pH 7.5, for 15 min at room temperature. DTSSP is a membrane-impermeable thiol-cleavable reagent that is used for cross-linking molecules at the cell surface. PDGFRs were immunoprecipitated from cell lysates using anti–human PDGFR (MAB1264) or PDGFRß (MAB1263; R&D Systems). Proteins conjugated to PDGFR–DTSSP complexes were dissociated by adding 5% ß-mercaptoethanol and boiling for 5 min. Growth factors associated with PDGFRs were resolved by SDS-PAGE and detected by immunoblot analysis, as previously described (Ball et al., 2004), using the following corresponding monoclonal anti–human antibodies: VEGF-A (MAB293), PDGF-B (MAB220), or TGF-ß₁ (MAB240; R&D Systems).

Statistical analysis
In all quantitation experiments, results are expressed as the mean ± the SD. Statistical differences between sets of data were determined by using a paired t test on SigmaPlot 8.0 software, with P < 0.05 considered significant.

Online supplemental material
Fig. S1 shows that inhibition of PDGFR or PDGFRß attenuated VEGF-A–induced MSC proliferation. Fig. S2 shows that VEGF-A contained no detectable PDGF-BB contamination. Fig. S3 shows that VEGF-A did not change soluble PDGF-BB levels.

	Acknowledgments

 
This work was funded by the UK Centre for Tissue Engineering (Medical Research Council, Biotechnology and Biological Sciences Research Council, and Engineering and Physical Sciences Research Council). C.M. Kielty is a Royal Society-Wolfson Research Merit Award holder.

Submitted: 16 August 2006

Accepted: 4 April 2007

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